01932nas a2200217 4500008004100000245010600041210006900147260000800216300001600224490000700240520127100247653000701518653000701525100002101532700001901553700002101572700002001593700002001613700002101633856006001654 2024 eng d00aSimulation of optomechanical interaction of levitated nanoparticle with photonic crystal micro cavity0 aSimulation of optomechanical interaction of levitated nanopartic cFeb a7185–71960 v323 a
We propose and analyze theoretically a promising design of an optical trap for vacuum levitation of nanoparticles based on a one-dimensional (1D) silicon photonic crystal cavity (PhC). The considered cavity has a quadratically modulated width of the silicon wave guiding structure, leading to a calculated cavity quality factor of 8 × 105. An effective mode volume of approximately 0.16 μm3 having the optical field strongly confined outside the silicon structure enables optical confinement on nanoparticle in all three dimensions. The optical forces and particle-cavity optomechanical coupling are comprehensively analyzed for two sizes of silica nanoparticles (100 nm and 150 nm in diameter) and various mode detunings. The value of trapping stiffnesses in the microcavity is predicted to be 5 order of magnitudes higher than that reached for optimized optical tweezers, moreover the linear single photon coupling rate can reach MHz level which is 6 order magnitude larger than previously reported values for common bulk cavities. The theoretical results support optimistic prospects towards a compact chip for optical levitation in vacuum and cooling of translational mechanical degrees of motion for the silica nanoparticle of a diameter of 100 nm.
10aLF10aMF1 aMaňka, Tadeáš1 aŠiler, Martin1 aLiška, Vojtěch1 aZemánek, Pavel1 aŠerý, Mojmír1 aBrzobohatý, Oto uhttps://opg.optica.org/oe/abstract.cfm?URI=oe-32-5-718500926nas a2200277 4500008004100000245012900041210006900170260001000239300000900249490000700258653000700265653000700272100002400279700002500303700002000328700002000348700001900368700002200387700001600409700001700425700001700442700002200459700001900481700001800500856013000518 2023 eng d00a110 mu m thin endo-microscope for deep-brain in vivo observations of neuronal connectivity, activity and blood flow dynamics0 a110 mu m thin endomicroscope for deepbrain in vivo observations cAPR 5 a18970 v1410aKF10aMF1 aStibůrek, Miroslav1 aOndráčková, Petra1 aTuckova, Tereza1 aTurtaev, Sergey1 aŠiler, Martin1 aPikálek, Tomáš1 aJákl, Petr1 aGomes, Andre1 aKrejci, Jana1 aKolbabkova, Petra1 aUhlirova, Hana1 aCizmar, Tomas uhttps://www.isibrno.cz/cs/110-mu-m-thin-endo-microscope-deep-brain-vivo-observations-neuronal-connectivity-activity-and-blood01782nas a2200193 4500008004100000022001400041245011200055210006900167520117100236653000801407653000701415100002401422700001701446700001801463700002301481700001601504700002101520856004701541 2023 eng d a1433-301500aAnalysis of the machinability of different types of sintered carbides with WEDM in both water and oil baths0 aAnalysis of the machinability of different types of sintered car3 aThe unconventional wire electric discharge machining (WEDM) technology represents a vital manufacturing technology in different industrial branches. This technology is essential because of the possibility to machine difficult-to-machine materials such as sintered carbides. For this reason, this study analyses the machinability of sintered carbides WKP23S, WSM33S and WK1 with WEDM in both water and oil baths. We investigated the influence of the machining parameters, namely, pulse off time, gap voltage, discharge current, pulse on time and wire feed, on the cutting speed, surface roughness and defect occurrence. We investigated 9 different roughness parameters, analysed surface morphology with an electron microscope and also analysed cross-sectioned samples. We found out that machining sintered carbides in oil bath yields better results than machining in deionized water. The oil tank prevents the removal of the cobalt binder, but it does not reduce fissure occurrence in any significant way. The lowest Ra value, that is 0.7 µm, was recorded for the WKP23S sample when machined in oil and Ra 0.9 µm when the same material was machined in water.
10aAIF10aMF1 aMouralova, Katerina1 aBenes, Libor1 aProkes, Tomas1 aZahradnicek, Radim1 aFries, Jiri1 aPlichta, Tomáš uhttps://doi.org/10.1007/s00170-023-10913-400680nas a2200229 4500008004100000020002200041245004700063210004700110260004400157300001600201653000700217653000700224100002000231700002000251700001700271700001500288700002500303700002300328700002100351700002900372856004900401 2023 eng d a978-3-030-27322-400aApplication of Aerogels in Optical Devices0 aApplication of Aerogels in Optical Devices aChambSpringer International Publishing a1431–145410aLF10aMF1 aOzbakir, Yaprak1 aJonas, Alexandr1 aKiraz, Alper1 aErkey, Can1 aAegerter, Michel, A.1 aLeventis, Nicholas1 aKoebel, Matthias1 aIII, Stephen, A. Steiner uhttps://doi.org/10.1007/978-3-030-27322-4_5600822nas a2200253 4500008004100000022001400041245012400055210006900179490000700248653000700255653000700262100002400269700002700293700002000320700002000340700001700360700002600377700001700403700002700420700001900447700001800466700001600484856006800500 2023 eng d a1664-302X00aAspergillus niger as a cell factory for the production of pyomelanin, a molecule with UV-C radiation shielding activity0 aAspergillus niger as a cell factory for the production of pyomel0 v1410aBF10aMF1 aKoch, Stella, Marie1 aFreidank-Pohl, Carsten1 aSiontas, Oliver1 aCortesao, Marta1 aMota, Afonso1 aRunzheimer, Katharina1 aJung, Sascha1 aRebrošová, Katarína1 aŠiler, Martin1 aMoeller, Ralf1 aMeyer, Vera uhttps://www.frontiersin.org/articles/10.3389/fmicb.2023.123374000670nas a2200205 4500008004100000245015300041210006900194260000800263300001100271490000700282653000700289653000700296100001500303700001300318700001600331700001800347700002000365700001700385856006200402 2023 eng d00aBayesian Estimation of Experimental Parameters in Stochastic Inertial Systems: Theory, Simulations, and Experiments with Objects Levitated in Vacuum0 aBayesian Estimation of Experimental Parameters in Stochastic Ine cJun a0640590 v1910aLF10aMF1 aŠiler, M.1 aSvak, V.1 aJonáš, A.1 aSimpson, S.H.1 aBrzobohatý, O.1 aZemánek, P. uhttps://link.aps.org/doi/10.1103/PhysRevApplied.19.06405900684nas a2200229 4500008004100000245006200041210006200103300001600165490000700181653000700188653000700195100002100202700002400223700001800247700001600265700001600281700002300297700002500320700002000345700002100365856006800386 2023 eng d00aCold damping of levitated optically coupled nanoparticles0 aCold damping of levitated optically coupled nanoparticles a1203–12090 v1010aLF10aMF1 aLiška, Vojtěch1 aZemánková, Tereza1 aSvak, Vojtech1 aJákl, Petr1 aJežek, Jan1 aBránecký, Martin1 aSimpson, Stephen, H.1 aZemánek, Pavel1 aBrzobohatý, Oto uhttps://opg.optica.org/optica/abstract.cfm?URI=optica-10-9-120300671nas a2200205 4500008004100000245008600041210006900127260000800196300000800204490000600212653000700218653000700225100002100232700002500253700002200278700002100300700002000321700002100341856010300362 2023 eng d00aCooling the optical-spin driven limit cycle oscillations of a levitated gyroscope0 aCooling the opticalspin driven limit cycle oscillations of a lev cNov a2380 v610aLF10aMF1 aArita, Yoshihiko1 aSimpson, Stephen, H.1 aBruce, Graham, D.1 aWright, Ewan, M.1 aZemánek, Pavel1 aDholakia, Kishan uhttps://www.isibrno.cz/cs/cooling-optical-spin-driven-limit-cycle-oscillations-levitated-gyroscope02401nas a2200229 4500008004100000022001400041245008200055210006900137260001100206300001600217490000700233520167900240653000701919653000701926100001801933700002001951700002501971700002101996700002502017700002602042856010302068 2023 eng d a1944-824400aDownsizing the Channel Length of Vertical Organic Electrochemical Transistors0 aDownsizing the Channel Length of Vertical Organic Electrochemica cMAY 22 a27002-270090 v153 aOrganic electrochemical transistors (OECTs) are promisingbuildingblocks for bioelectronic devices such as sensors and neural interfaces.While the majority of OECTs use simple planar geometry, there is interestin exploring how these devices operate with much shorter channelson the submicron scale. Here, we show a practical route toward theminimization of the channel length of the transistor using traditionalphotolithography, enabling large-scale utilization. We describe thefabrication of such transistors using two types of conducting polymers.First, commercial solution-processed poly-(dioxyethylenethiophene):poly-(styrenesulfonate), PEDOT:PSS. Next, we also exploit the short channel lengthto support easy in situ electropolymerization of poly-(dioxyethylenethiophene):tetrabutylammonium hexafluorophosphate, PEDOT:PF6. Both variantsshow different promising features, leading the way in terms of transconductance(g (m)), with the measured peak g (m) up to 68 mS for relatively thin (280 nm) channel layerson devices with the channel length of 350 nm and with widths of 50,100, and 200 mu m. This result suggests that the use of electropolymerizedsemiconductors, which can be easily customized, is viable with verticalgeometry, as uniform and thin layers can be created. Spin-coated PEDOT:PSSlags behind with the lower values of g (m); however, it excels in terms of the speed of the device and alsohas a comparably lower off current (300 nA), leading to unusuallyhigh on/off ratio, with values up to 8.6 x 10(4). Ourapproach to vertical gap devices is simple, scalable, and can be extendedto other applications where small electrochemical channels are desired.
10aKF10aMF1 aBrodský, Jan1 aGablech, Imrich1 aMigliaccio, Ludovico1 aHavli'cek, Marek1 aDonahue, Mary, J. J.1 aGlowacki, Eric, D. D. uhttps://www.isibrno.cz/cs/downsizing-channel-length-vertical-organic-electrochemical-transistors-000777nas a2200241 4500008004100000245011000041210006900151490000700220653000700227653000700234100002100241700002600262700002700288700001800315700002200333700001500355700002300370700001900393700001500412700002200427700001800449856006800467 2023 eng d00aIdentification of staphyloxanthin and derivates in yellow-pigmented Staphylococcus capitis subsp. capitis0 aIdentification of staphyloxanthin and derivates in yellowpigment0 v1410aBF10aMF1 aSiems, Katharina1 aRunzheimer, Katharina1 aRebrošová, Katarína1 aEtzbach, Lara1 aAuerhammer, Alina1 aRehm, Anna1 aSchwengers, Oliver1 aŠiler, Martin1 aSamek, Ota1 aRůžička, Filip1 aMoeller, Ralf uhttps://www.frontiersin.org/articles/10.3389/fmicb.2023.127273402490nas a2200289 4500008004100000022001400041245012900055210006900184300001100253490000800264520159600272653000701868653000701875100002101882700002201903700002201925700001601947700001901963700001801982700002202000700002502022700001502047700002102062700001802083700002702101856007202128 2023 eng d a0045-653500aLaser-based techniques: Novel tools for the identification and characterization of aged microplastics with developed biofilm0 aLaserbased techniques Novel tools for the identification and cha a1373730 v3133 aMicroplastics found in the environment are often covered with a biofilm, which makes their analysis difficult. Therefore, the biofilm is usually removed before analysis, which may affect the microplastic particles or lead to their loss during the procedure. In this work, we used laser-based analytical techniques and evaluated their performance in detecting, characterizing, and classifying pristine and aged microplastics with a developed biofilm. Five types of microplastics from different polymers were selected (polyamide, polyethylene, polyethylene terephthalate, polypropylene, and polyvinyl chloride) and aged under controlled conditions in freshwater and wastewater. The development of biofilm and the changes in the properties of the microplastic were evaluated. The pristine and aged microplastics were characterized by standard methods (e.g., optical and scanning electron microscopy, and Raman spectroscopy), and then laser-induced breakdown spectroscopy (LIBS) and laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) were used. The results show that LIBS could identify different types of plastics regardless of the ageing and major biotic elements of the biofilm layer. LA-ICP-MS showed a high sensitivity to metals, which can be used as markers for various plastics. In addition, LA-ICP-MS can be employed in studies to monitor the adsorption and desorption (leaching) of metals during the ageing of microplastics. The use of these laser-based analytical techniques was found to be beneficial in the study of environmentally relevant microplastics.
10aBF10aMF1 aPořízka, Pavel1 aBrunnbauer, Lukas1 aPorkert, Michaela1 aRozman, Ula1 aMarolt, Gregor1 aHolub, Daniel1 aKizovský, Martin1 aBenešová, Markéta1 aSamek, Ota1 aLimbeck, Andreas1 aKaiser, Jozef1 aKalčíková, Gabriela uhttps://www.sciencedirect.com/science/article/pii/S004565352203866802487nas a2200325 4500008004100000022001400041245011700055210006900172300001100241490000800252520149500260653000701755653000701762100002501769700002301794700002201817700002201839700001601861700001801877700001501895700002001910700001601930700003201946700002601978700002002004700002802024700001802052700001902070856007202089 2023 eng d a0304-389400aPhysiological and transcriptome profiling of Chlorella sorokiniana: A study on azo dye wastewater decolorization0 aPhysiological and transcriptome profiling of Chlorella sorokinia a1324500 v4603 aOver decades, synthetic dyes have become increasingly dominated by azo dyes posing a significant environmental risk due to their toxicity. Microalgae-based systems may offer an alternative for treatment of azo dye effluents to conventional physical-chemical methods. Here, microalgae were tested to decolorize industrial azo dye wastewater (ADW). Chlorella sorokiniana showed the highest decolorization efficiency in a preliminary screening test. Subsequently, the optimization of the experimental design resulted in 70% decolorization in a photobioreactor. Tolerance of this strain was evidenced using multiple approaches (growth and chlorophyll content assays, scanning electron microscopy (SEM), and antioxidant level measurements). Raman microspectroscopy was employed for the quantification of ADW-specific compounds accumulated by the microalgal biomass. Finally, RNA-seq revealed the transcriptome profile of C. sorokiniana exposed to ADW for 72 h. Activated DNA repair and primary metabolism provided sufficient energy for microalgal growth to overcome the adverse toxic conditions. Furthermore, several transporter genes, oxidoreductases-, and glycosyltransferases-encoding genes were upregulated to effectively sequestrate and detoxify the ADW. This work demonstrates the potential utilization of C. sorokiniana as a tolerant strain for industrial wastewater treatment, emphasizing the regulation of its molecular mechanisms to cope with unfavorable growth conditions.
10aBF10aMF1 aTarbajova, Vladimira1 aKolackova, Martina1 aChaloupsky, Pavel1 aDobesova, Marketa1 aCapal, Petr1 aPilat, Zdenek1 aSamek, Ota1 aZemánek, Pavel1 aSvec, Pavel1 aSterbova, Dagmar, Skopalova1 aVaculovicova, Marketa1 aRichtera, Lukas1 aPérez-de-Mora, Alfredo1 aAdam, Vojtech1 aHuska, Dalibor uhttps://www.sciencedirect.com/science/article/pii/S030438942301733800760nas a2200241 4500008004100000245011000041210006900151300001400220490000700234653000700241653000700248100002700255700002300282700001900305700001600324700001500340700001600355700002200371700002000393700002000413700002200433856006300455 2023 eng d00aRapid Identification of Pathogens Causing Bloodstream Infections by Raman Spectroscopy and Raman Tweezers0 aRapid Identification of Pathogens Causing Bloodstream Infections ae00028-230 v1110aBF10aMF1 aRebrošová, Katarína1 aBernatová, Silvie1 aŠiler, Martin1 aMašek, Jan1 aSamek, Ota1 aJežek, Jan1 aKizovský, Martin1 aHolá, Veronika1 aZemánek, Pavel1 aRůžička, Filip uhttps://journals.asm.org/doi/abs/10.1128/spectrum.00028-2300840nas a2200277 4500008004100000245012000041210006900161260000800230300001600238490000700254653000800261653000700269653000700276653000700283100002200290700002300312700002700335700001500362700002100377700002400398700002000422700001900442700001800461700002000479856006300499 2023 eng d00aRapid identification of pathogens in blood serum via Raman tweezers in combination with advanced processing methods0 aRapid identification of pathogens in blood serum via Raman tweez cDec a6410–64210 v1410aAIF10aBF10aLF10aMF1 aVaculík, Ondřej1 aBernatová, Silvie1 aRebrošová, Katarína1 aSamek, Ota1 aŠilhan, Lukáš1 ažička, Filip, Rů1 aŠerý, Mojmír1 aŠiler, Martin1 aek, Jan, Jež1 aZemánek, Pavel uhttps://opg.optica.org/boe/abstract.cfm?URI=boe-14-12-641003137nas a2201129 4500008004100000245003300041210003300074260000800107300001100115490000600126653000700132653000700139100002000146700002400166700003100190700002000221700002600241700001900267700002300286700002400309700002500333700002700358700001800385700001800403700002200421700002400443700002400467700002300491700002000514700002100534700001900555700001600574700001500590700002200605700001800627700002700645700002200672700002200694700002100716700001900737700001700756700003100773700002500804700002700829700002500856700002800881700001700909700002100926700001700947700001500964700002200979700002001001700002001021700001401041700001901055700002401074700002001098700002201118700001901140700001701159700001901176700001801195700002901213700002101242700002101263700001701284700002101301700002401322700002001346700001801366700001901384700002201403700002401425700001901449700002201468700001901490700002601509700002501535700001901560700002001579700002601599700002101625700001901646700002101665700002901686700002301715700002401738700002101762700001801783700002701801700002601828700002501854700002601879700002601905700002801931856004801959 2023 eng d00aRoadmap for optical tweezers0 aRoadmap for optical tweezers capr a0225010 v510aLF10aMF1 aVolpe, Giovanni1 aMaragò, Onofrio, M1 aRubinsztein-Dunlop, Halina1 aPesce, Giuseppe1 aStilgoe, Alexander, B1 aVolpe, Giorgio1 aTkachenko, Georgiy1 aTruong, Viet, Giang1 aChormaic, Síle, Nic1 aKalantarifard, Fatemeh1 aElahi, Parviz1 aKäll, Mikael1 aCallegari, Agnese1 aMarqués, Manuel, I1 aNeves, Antonio, A R1 aMoreira, Wendel, L1 aFontes, Adriana1 aCesar, Carlos, L1 aSaija, Rosalba1 aSaidi, Abir1 aBeck, Paul1 aEismann, Jörg, S1 aBanzer, Peter1 aFernandes, Thales, F D1 aPedaci, Francesco1 aBowen, Warwick, P1 aVaippully, Rahul1 aLokesh, Muruga1 aRoy, Basudev1 aThalhammer-Thurner, Gregor1 aRitsch-Marte, Monika1 aGarcía, Laura, Pérez1 aArzola, Alejandro, V1 aCastillo, Isaac, Pérez1 aArgun, Aykut1 aMuenker, Till, M1 aVos, Bart, E1 aBetz, Timo1 aCristiani, Ilaria1 aMinzioni, Paolo1 aReece, Peter, J1 aWang, Fan1 aMcGloin, David1 aNdukaife, Justus, C1 aQuidant, Romain1 aRoberts, Reece, P1 aLaplane, Cyril1 aVolz, Thomas1 aGordon, Reuven1 aHanstorp, Dag1 aMarmolejo, Javier, Tello1 aBruce, Graham, D1 aDholakia, Kishan1 aLi, Tongcang1 aBrzobohatý, Oto1 aSimpson, Stephen, H1 aZemánek, Pavel1 aRitort, Felix1 aRoichman, Yael1 aBobkova, Valeriia1 aWittkowski, Raphael1 aDenz, Cornelia1 aKumar, G, V Pavan1 aFoti, Antonino1 aDonato, Maria, Grazia1 aGucciardi, Pietro, G1 aGardini, Lucia1 aBianchi, Giulio1 aKashchuk, Anatolii, V1 aCapitanio, Marco1 aPaterson, Lynn1 aJones, Philip, H1 aBerg-Sørensen, Kirstine1 aBarooji, Younes, F1 aOddershede, Lene, B1 aPouladian, Pegah1 aPreece, Daryl1 aAdiels, Caroline, Beck1 aDe Luca, Anna, Chiara1 aMagazzù, Alessandro1 aCiriza, David, Bronte1 aIatì, Maria, Antonia1 aSwartzlander, Grover, A uhttps://dx.doi.org/10.1088/2515-7647/acb57b00821nas a2200265 4500008004100000022001400041245013400055210006900189300000800258490000700266653000700273653000700280100002500287700002300312700001600335700002100351700001600372700001900388700001500407700002200422700002700444700002000471700002000491856004400511 2023 eng d a2079-637400aSERS-Tags: Selective Immobilization and Detection of Bacteria by Strain-Specific Antibodies and Surface-Enhanced Raman Scattering0 aSERSTags Selective Immobilization and Detection of Bacteria by S a1820 v1310aBF10aMF1 aBenešová, Markéta1 aBernatová, Silvie1 aMika, Filip1 aPokorná, Zuzana1 aJežek, Jan1 aŠiler, Martin1 aSamek, Ota1 aRůžička, Filip1 aRebrošová, Katarína1 aZemánek, Pavel1 aPilát, Zdeněk uhttps://www.mdpi.com/2079-6374/13/2/18202580nas a2200193 4500008004100000022001400041245009200055210006900147300001100216490000800227520198700235653000802222653000702230100001902237700001702256700002202273700001902295856007202314 2023 eng d a0257-897200aStable a-CSi:H films with a wide range of modulus of elasticity and low internal stress0 aStable aCSiH films with a wide range of modulus of elasticity an a1291470 v4593 aAmorphous hydrogenated silicon carbide (a-CSi:H) thin films were deposited by plasma-enhanced chemical vapor deposition using tetravinylsilane as organosilicon precursor. The mechanical properties of the thin films, namely the modulus of elasticity, hardness, and elastic recovery parameter, were determined by nanoindentation, as well as the internal stresses by scanning electron microscopy and optical profilometry. It was found that the modulus of elasticity increased from 10 to 137 GPa with increasing power (2–150 W) delivered to plasma, while the hardness increased from 1.5 to 14.5 GPa. This improvement in mechanical properties with increasing energy delivered to the plasma is related to greater fragmentation of the precursor which led to an increase in the crosslinking of the material network. The compressive internal stresses in the films reached low values of −0.04 to −0.2 GPa with increasing power (2–75 W) and an acceptable −0.5 GPa for 150 W. The elastic recovery parameter decreased with increasing power from 0.86 to 0.64, i.e., the thin films behaved more plasticity with increasing power. The modulus of elasticity and hardness were investigated in terms of the aging of the films for a period of 6 years when samples were stored under ambient conditions. No significant changes in these properties were observed. However, minor changes were observed in the indentation curves obtained for the 2 W and even less for the 10 W samples. Small changes were then also observed for the elastic recovery parameter, whose value for these samples partially decreased which may be related to postdeposition oxidation. No changes in internal stress values over time were observed. The wide range of mechanical properties of stable a-CSi:H films with low internal stress increases their application potential and their wide use as materials with tailored properties from polymer-like to tough material.
10aAIF10aMF1 aPlichta, Tomas1 aSulc, Vaclav1 aOhlidal, Miloslav1 aCech, Vladimir uhttps://www.sciencedirect.com/science/article/pii/S025789722201068400619nas a2200205 4500008004100000245008900041210006900130300000900199490000700208653000700215653000700222100002100229700002000250700001600270700001600286700001900302700002000321700002500341856004700366 2023 eng d00aSynchronization of spin-driven limit cycle oscillators optically levitated in vacuum0 aSynchronization of spindriven limit cycle oscillators optically a54410 v1410aLF10aMF1 aBrzobohatý, Oto1 aDuchaň, Martin1 aJákl, Petr1 aJežek, Jan1 aŠiler, Martin1 aZemánek, Pavel1 aSimpson, Stephen, H. uhttps://doi.org/10.1038/s41467-023-41129-501763nas a2200241 4500008004100000245014800041210006900189260000800258300001600266490000700282520101500289653000701304653000701311100001701318700001801335700001901353700001801372700001801390700001901408700001701427700001601444856006101460 2022 eng d00aAbsolute frequencies of H13C14N hydrogen cyanide transitions in the 1.5-µm region with the saturated spectroscopy and a sub-kHz scanning laser0 aAbsolute frequencies of H13C14N hydrogen cyanide transitions in cNov a5704–57070 v473 aThe wide span and high density of lines in its rovibrational spectrum render hydrogen cyanide a useful spectroscopic media for referencing absolute frequencies of lasers in optical communication and dimensional metrology. We determined, for the first time to the best of our knowledge, the molecular transitions' center frequencies of the H13C14N isotope in the range from 1526 nm to 1566 nm with 1.3&\#x00A0;×&\#x00A0;10\textminus10 fractional uncertainty. We investigated the molecular transitions with a highly coherent and widely tunable scanning laser that was precisely referenced to a hydrogen maser through an optical frequency comb. We demonstrated an approach to stabilize the operational conditions needed to maintain the constantly low pressure of the hydrogen cyanide to carry out the saturated spectroscopy with the third-harmonic synchronous demodulation. We demonstrated approximately a forty-fold improvement in the line centers' resolution compared to the previous result.
10aBF10aMF1 aHrabina, Jan1 aHosek, Martin1 aRerucha, Simon1 aCizek, Martin1 aPilat, Zdenek1 aZucco, Massimo1 aLazar, Josef1 aCip, Ondrej uhttps://opg.optica.org/ol/abstract.cfm?URI=ol-47-21-570400919nas a2200217 4500008004100000245008400041210006900125260000800194300001600202490000600218520029100224653000700515653000700522100001400529700001800543700001900561700002000580700001700600700001700617856006700634 2022 eng d00aAll-optical sub-Kelvin sympathetic cooling of a levitated microsphere in vacuum0 aAlloptical subKelvin sympathetic cooling of a levitated microsph cSep a1000–10020 v93 aWe demonstrate all-optical sympathetic cooling of a laser-trapped microsphere to sub-Kelvin temperatures, mediated by optical binding to a feedback-cooled adjacent particle. Our study opens prospects for multi-particle quantum entanglement and sensing in levitated optomechanics.
10aLF10aMF1 aArita, Y.1 aBruce, G., D.1 aWright, E., M.1 aSimpson, S., H.1 aZemánek, P.1 aDholakia, K. uhttps://opg.optica.org/optica/abstract.cfm?URI=optica-9-9-100001044nas a2200349 4500008004100000022001400041245006200055210006200117260001100179300001100190490000800201653000700209653000700216100002200223700002600245700002100271700001800292700002000310700002000330700002600350700002300376700002900399700002300428700002200451700002400473700002200497700002200519700002300541700002200564700002600586856008200612 2022 eng d a0021-960600aChallenges on optical printing of colloidal nanoparticles0 aChallenges on optical printing of colloidal nanoparticles cJAN 21 a0342010 v15610aLF10aMF1 aVioli, Ianina, L.1 aMartinez, Luciana, P.1 aBarella, Mariano1 aZaza, Cecilia1 aChvátal, Lukas1 aZemánek, Pavel1 aGutierrez, Marina, V.1 aParedes, Maria, Y.1 aScarpettini, Alberto, F.1 aOlmos-Trigo, Jorge1 aPais, Valeria, R.1 aNoblega, Ivan, Diaz1 aCortès, Emiliano1 aSaenz, Juan, Jose1 aBragas, Andrea, V.1 aGargiulo, Juliàn1 aStefani, Fernando, D. uhttps://www.isibrno.cz/cs/challenges-optical-printing-colloidal-nanoparticles00638nas a2200217 4500008004100000245010000041210006900141300000700210490000600217653000700223653000700230653000700237100001600244700001900260700001600279700002100295700002400316700002000340700001800360856004200378 2022 eng d00aEndoscopic Imaging Using a Multimode Optical Fibre Calibrated with Multiple Internal References0 aEndoscopic Imaging Using a Multimode Optical Fibre Calibrated wi a370 v910aBF10aKF10aMF1 aJákl, Petr1 aŠiler, Martin1 aJežek, Jan1 aCifuentes, Angel1 aTrägårdh, Johanna1 aZemánek, Pavel1 aCizmar, Tomas uhttps://www.mdpi.com/2304-6732/9/1/3701697nas a2200205 4500008004100000245008800041210006900129300001400198490000800212520109100220653000801311653000701319100002401326700001901350700002301369700001801392700001901410700001601429856004601445 2022 eng d00aExperimental analysis of microhardness changes of subsurface areas affected by WEDM0 aExperimental analysis of microhardness changes of subsurface are a1979-19910 v2363 aThe influence of the surface area by the impact of high temperatures after wire electric discharge machining (WEDM) is a known fact. However, the affected parameters also include a change in microhardness. In order to further investigate this statement, 5 different ferrous and non-ferrous materials were selected, from which three samples were always made with different settings of machine parameters (gap voltage, pulse on and off time, wire feed and discharge current). This examined not only the effect of the machining itself on the material but also whether the change in the microhardness of the material is affected by the setting of the machine parameters. In order to measure the microhardness of the subsurface layer, a metallographic preparation was made from each sample, which enabled accurate measurements always in the same area. Subsequent evaluation revealed that the microhardness may not be affected at all and everything depends only on the type of material being machined. The changes in microhardness affected by setting machine parameters are negligible.
10aAIF10aMF1 aMouralova, Katerina1 aMichna, Stefan1 aZahradnicek, Radim1 aBednar, Josef1 aPlichta, Tomas1 aFries, Jiri uhttps://doi.org/10.1177/0954408922107838300961nas a2200301 4500008004100000022001400041245014400055210006900199260000800268300001400276490000700290653000700297653000700304100001600311700001600327700001700343700001600360700001900376700001700395700002200412700001400434700001700448700001900465700001900484700001600503700001300519856012700532 2022 eng d a0921-897100aGlycogen, poly(3-hydroxybutyrate) and pigment accumulation in three Synechocystis strains when exposed to a stepwise increasing salt stress0 aGlycogen poly3hydroxybutyrate and pigment accumulation in three cJUN a1227-12410 v3410aBF10aMF1 aMeixner, K.1 aDaffert, C.1 aDalnodar, D.1 aMrazova, K.1 aHrubanová, K.1 aKrzyzanek, V1 aNebesářová, J.1 aSamek, O.1 aSedrlova, Z.1 aSlaninová, E.1 aSedláček, P.1 aObruča, S.1 aFritz, I uhttps://www.isibrno.cz/cs/glycogen-poly3-hydroxybutyrate-and-pigment-accumulation-three-synechocystis-strains-when-exposed00516nas a2200181 4500008004100000020000900041245006200050210005800112300001200170490000900182653000700191653000700198100002400205700002100229700001800250700002400268856004200292 2022 eng d anull00aHow to Build the ``Optical Inverse'' of a Multimode Fibre0 aHow to Build the Optical Inverse of a Multimode Fibre a98160260 v202210aKF10aMF1 aBūtaitė, Unė, G.1 aKupianskyi, Hlib1 aCizmar, Tomas1 aPhillips, David, B. uhttps://doi.org/10.34133/2022/981602600678nas a2200217 4500008004100000022001400041245009800055210006900153300000600222490000600228653000700234653000700241100001300248700002000261700001800281700001900299700001800318700002300336700002300359856007800382 2022 eng d a2689-962000aHybrid multimode - multicore fibre based holographic endoscope for deep-tissue neurophotonics0 aHybrid multimode multicore fibre based holographic endoscope for a10 v310aKF10aMF1 aDu, Yang1 aTurtaev, Sergey1 aLeite, Ivo, T1 aLorenz, Adrian1 aKobelke, Jens1 aWondraczek, Katrin1 aČižmár, Tomáš uhttps://www.light-am.com//article/id/5e7e4e57-462a-4c48-92ca-1aec395fed5900639nas a2200217 4500008004100000245006700041210006700108260000800175300000900183490000700192653000700199653000700206100001900213700001600232700002300248700001600271700001600287700002000303700001600323856008200339 2022 eng d00aIn Vivo Contrast Imaging of Rat Heart with Carbon Dioxide Foam0 aIn Vivo Contrast Imaging of Rat Heart with Carbon Dioxide Foam cJUL a51240 v2210aBF10aMF1 aKaralko, Anton1 aKesa, Peter1 aJelinek, Frantisek1 aSefc, Ludek1 aJežek, Jan1 aZemánek, Pavel1 aGrus, Tomas uhttps://www.isibrno.cz/cs/vivo-contrast-imaging-rat-heart-carbon-dioxide-foam00486nas a2200157 4500008004100000245006800041210006600109260000800175300001800183490000700201653000700208653000700215100002100222700002400243856006100267 2022 eng d00aA method for single particle tracking through a multimode fiber0 amethod for single particle tracking through a multimode fiber cSep a36055–360640 v3010aKF10aMF1 aCifuentes, Angel1 aTrägårdh, Johanna uhttp://opg.optica.org/oe/abstract.cfm?URI=oe-30-20-3605500510nas a2200181 4500008004100000245005100041210005100092260000800143300001800151490000700169653000700176653000700183100002200190700002000212700001300232700002300245856006000268 2022 eng d00aNear perfect focusing through multimode fibres0 aNear perfect focusing through multimode fibres cMar a10645–106630 v3010aKF10aMF1 aGomes, André, D.1 aTurtaev, Sergey1 aDu, Yang1 aČižmár, Tomáš uhttp://opg.optica.org/oe/abstract.cfm?URI=oe-30-7-1064502729nas a2200961 4500008004100000245008500041210006900126490000600195653000700201653000700208100002300215700001700238700001700255700002500272700002000297700001800317700002200335700002500357700002300382700001900405700002300424700002200447700002500469700001600494700002300510700002200533700002400555700002900579700002300608700003200631700003000663700001700693700001300710700001900723700003000742700002500772700002200797700001100819700002100830700002400851700001200875700001500887700002200902700002600924700002100950700003000971700002201001700001701023700002101040700002501061700002601086700002701112700002301139700002001162700002501182700002101207700002701228700001801255700002001273700001601293700002301309700001801332700001901350700002301369700002601392700002201418700001401440700001401454700002001468700002001488700002101508700002701529700001901556700002101575700002201596700001401618700002001632700001701652700001701669700001701686700001801703856004601721 2022 eng d00aNeurophotonic tools for microscopic measurements and manipulation: status report0 aNeurophotonic tools for microscopic measurements and manipulatio0 v910aKF10aMF1 aAbdelfattah, Ahmed1 aAhuja, Sapna1 aAkkin, Taner1 aAllu, Srinivasa, Rao1 aBoas, David, A.1 aBrake, Joshua1 aBuckley, Erin, M.1 aCampbell, Robert, E.1 aChen, Anderson, I.1 aCheng, Xiaojun1 aČižmár, Tomáš1 aCostantini, Irene1 aDe Vittorio, Massimo1 aDevor, Anna1 aDoran, Patrick, R.1 aKhatib, Mirna, El1 aEmiliani, Valentina1 aFomin-Thunemann, Natalie1 aFainman, Yeshaiahu1 aAlfonso, Tomás, Fernández1 aFerri, Christopher, G. L.1 aGilad, Ariel1 aHan, Xue1 aHarris, Andrew1 aHillman, Elizabeth, M. C.1 aHochgeschwender, Ute1 aHolt, Matthew, G.1 aJi, Na1 aKiliç, Kivilcim1 aLake, Evelyn, M. R.1 aLi, Lei1 aLi, Tianqi1 aMächler, Philipp1 aMesquita, Rickson, C.1 aMiller, Evan, W.1 aNadella, K.M., Naga Srini1 aNägerl, Valentin1 aNasu, Yusuke1 aNimmerjahn, Axel1 aOndráčková, Petra1 aPavone, Francesco, S.1 aCampos, Citlali, Perez1 aPeterka, Darcy, S.1 aPisano, Filippo1 aPisanello, Ferruccio1 aPuppo, Francesca1 aSabatini, Bernardo, L.1 aSadegh, Sanaz1 aSakadžic, Sava1 aShoham, Shy1 aShroff, Sanaya, N.1 aSilver, Angus1 aSims, Ruth, R.1 aSmith, Spencer, L.1 aSrinivasan, Vivek, J.1 aThunemann, Martin1 aTian, Lei1 aTian, Lin1 aTroxler, Thomas1 aValera, Antoine1 aVaziri, Alipasha1 aVinogradov, Sergei, A.1 aVitale, Flavia1 aWang, Lihong, V.1 aUhlířová, Hana1 aXu, Chris1 aYang, Changhuei1 aYang, Mu-Han1 aYellen, Gary1 aYizhar, Ofer1 aZhao, Yongxin uhttps://doi.org/10.1117/1.NPh.9.S1.01300102054nas a2200217 4500008004100000022001400041245012900055210006900184300001100253490000800264520136300272653000701635653000701642100001801649700002101667700002201688700002101710700001501731700001801746856007201764 2022 eng d a0584-854700aThe potential of combining laser-induced breakdown spectroscopy and Raman spectroscopy data for the analysis of wood samples0 apotential of combining laserinduced breakdown spectroscopy and R a1064870 v1953 aWe report on combining the surface analysis technique of Laser-induced Breakdown Spectroscopy (LIBS) with Raman spectroscopy. The combination of both techniques enables to study the chemical composition of the sample in a broader context when combining elemental and molecular information. Obtained elemental and molecular spectra are characteristic for individual biological samples (e.g., organs and cells) and are considered as a fingerprint. In this study, Raman spectroscopy is used for the detection of important molecular complexes in selected wood samples, e.g., accurate lignin and cellulose content on distinct spots of the sample surface. We chose Raman as a standard reference technique that is used for the lignin/cellulose ratio estimation. To complement the molecular information, LIBS technique was employed for the imaging of essential nutrients, e.g., Ca, Na, and K. Consequently, the contribution from both analytical techniques was combined and changes in the molecular content were visually correlated to the abundance of nutrition elements and show a direct dependence between the two signal responses. Thus, we can get specific answers to relation of lignin and cellulose formation with nutrients within the plant tissue. This evidence may then be helpful for the study of the effect of various environmental and stress factors.
10aBF10aMF1 aHolub, Daniel1 aPořízka, Pavel1 aKizovský, Martin1 aProchazka, David1 aSamek, Ota1 aKaiser, Josef uhttps://www.sciencedirect.com/science/article/pii/S058485472200131800644nas a2200217 4500008004100000022001400041245006500055210006500120260001100185300000900196490000700205653000800212653000700220100002400227700001800251700001700269700002100286700001800307700001600325856008500341 2022 eng d a2045-232200aProduction of precision slots in copper foil using micro EDM0 aProduction of precision slots in copper foil using micro EDM cMAR 23 a50230 v1210aAIF10aMF1 aMouralova, Katerina1 aBednar, Josef1 aBenes, Libor1 aPlichta, Tomáš1 aProkes, Tomas1 aFries, Jiri uhttps://www.isibrno.cz/cs/production-precision-slots-copper-foil-using-micro-edm00773nas a2200217 4500008004100000022001400041245013400055210006900189260001100258300001100269490000700280653000700287653000700294100002700301700001500328700002200343700002300365700002000388700002200408856012500430 2022 eng d a2235-298800aRaman Spectroscopy-A Novel Method for Identification and Characterization of Microbes on a Single-Cell Level in Clinical Settings0 aRaman SpectroscopyA Novel Method for Identification and Characte cAPR 22 a8664630 v1210aBF10aMF1 aRebrošová, Katarína1 aSamek, Ota1 aKizovský, Martin1 aBernatová, Silvie1 aHolá, Veronika1 aRůžička, Filip uhttps://www.isibrno.cz/cs/raman-spectroscopy-novel-method-identification-and-characterization-microbes-single-cell-level00785nas a2200253 4500008004100000022001400041245010600055210007100161300001100232490000900243653000700252653000700259653000700266100002700273700002300300700001900323700002400342700001500366700001600381700002000397700002200417700002000439856007200459 2022 eng d a0003-267000aRaman spectroscopy—a tool for rapid differentiation among microbes causing urinary tract infections0 aRaman spectroscopy—a tool for rapid differentiation among microb a3392920 v119110aBF10aKF10aMF1 aRebrošová, Katarína1 aBernatová, Silvie1 aŠiler, Martin1 aUhlirova, Magdalena1 aSamek, Ota1 aJežek, Jan1 aHolá, Veronika1 aRůžička, Filip1 aZemánek, Pavel uhttps://www.sciencedirect.com/science/article/pii/S000326702101118102383nas a2200685 4500008004100000245006700041210006700108260000800175300001100183490000600194520054700200653000700747653000700754100001900761700001400780700002500794700002600819700002100845700002300866700002000889700002000909700001800929700002200947700002000969700001300989700002001002700002001022700001801042700002301060700001401083700002301097700001901120700002001139700002201159700002301181700001101204700002501215700001801240700002201258700002001280700002401300700002001324700002201344700002301366700002101389700001901410700002201429700001901451700001401470700002201484700001801506700001701524700001901541700001601560700001401576700002001590700002001610700001901630856004801649 2022 eng d00aRoadmap on wavefront shaping and deep imaging in complex media0 aRoadmap on wavefront shaping and deep imaging in complex media caug a0425010 v43 aThe last decade has seen the development of a wide set of tools, such as wavefront shaping, computational or fundamental methods, that allow us to understand and control light propagation in a complex medium, such as biological tissues or multimode fibers. A vibrant and diverse community is now working in this field, which has revolutionized the prospect of diffraction-limited imaging at depth in tissues. This roadmap highlights several key aspects of this fast developing field, and some of the challenges and opportunities ahead.
10aKF10aMF1 aGigan, Sylvain1 aKatz, Ori1 ade Aguiar, Hilton, B1 aAndresen, Esben, Ravn1 aAubry, Alexandre1 aBertolotti, Jacopo1 aBossy, Emmanuel1 aBouchet, Dorian1 aBrake, Joshua1 aBrasselet, Sophie1 aBromberg, Yaron1 aCao, Hui1 aChaigne, Thomas1 aCheng, Zhongtao1 aChoi, Wonshik1 aČižmár, Tomáš1 aCui, Meng1 aCurtis, Vincent, R1 aDefienne, Hugo1 aHofer, Matthias1 aHorisaki, Ryoichi1 aHorstmeyer, Roarke1 aJi, Na1 aLaViolette, Aaron, K1 aMertz, Jerome1 aMoser, Christophe1 aMosk, Allard, P1 aPégard, Nicolas, C1 aPiestun, Rafael1 aPopoff, Sebastien1 aPhillips, David, B1 aPsaltis, Demetri1 aRahmani, Babak1 aRigneault, Hervé1 aRotter, Stefan1 aTian, Lei1 aVellekoop, Ivo, M1 aWaller, Laura1 aWang, Lihong1 aWeber, Timothy1 aXiao, Sheng1 aXu, Chris1 aYamilov, Alexey1 aYang, Changhuei1 aYılmaz, Hasan uhttps://dx.doi.org/10.1088/2515-7647/ac76f902109nas a2200277 4500008004100000022001400041245013300055210006900188300001200257490000800269520124000277653000701517653000701524100002101531700002301552700001901575700001901594700001501613700001901628700002501647700002201672700002201694700002101716700002201737856007201759 2022 eng d a0141-813000aThe role of polyhydroxyalkanoates in adaptation of Cupriavidus necator to osmotic pressure and high concentration of copper ions0 arole of polyhydroxyalkanoates in adaptation of Cupriavidus necat a977-9890 v2063 aPolyhydroxyalkanoates (PHA) are abundant microbial polyesters accumulated in the form of intracellular granules by numerous prokaryotes primarily as storage of carbon and energy. Apart from their storage function, the presence of PHA also enhances the robustness of the microbial cells against various stressors. In this work, we investigated the role of PHA in Cupriavidus necator, a model organism concerning PHA metabolism, for adaptation to osmotic pressure and copper ions. In long-term laboratory evolution experiments, the bacterial culture was cultivated in presence of elevated doses of sodium chloride or copper ions (incubations lasted 78 passages for Cu2+ and 68 passages for NaCl) and the evolved strains were compared with the wild-type strain in terms of growth and PHA production capacity, cell morphology (investigated by various electron microscopy techniques), activities of selected enzymes involved in PHA metabolism and other crucial metabolic pathways, the chemical composition of bacterial biomass (determined by infrared and Raman spectroscopy) and also considering robustness against various stressors. The results confirmed the important role of PHA metabolism for adaptation to both tested stressors.
10aBF10aMF1 aNovackova, Ivana1 aHrabalova, Vendula1 aSlaninova, Eva1 aSedlacek, Petr1 aSamek, Ota1 aKoller, Martin1 aKrzyzanek, Vladislav1 aHrubanova, Kamila1 aMrazova, Katerina1 aNebesarova, Jana1 aObruca, Stanislav uhttps://www.sciencedirect.com/science/article/pii/S014181302200571200638nas a2200193 4500008004100000022001400041245008100055210006900136300001400205490000700219653000700226653000700233100002200240700002400262700002100286700001800307700002400325856009500349 2022 eng d a2156-708500aSuppression of the Non-Linear Background in a Multimode Fibre CARS Endoscope0 aSuppression of the NonLinear Background in a Multimode Fibre CAR a862–8640 v1310aKF10aMF1 aPikálek, Tomáš1 aStibůrek, Miroslav1 aSimpson, Stephen1 aCizmar, Tomas1 aTrägårdh, Johanna uhttps://www.isibrno.cz/cs/suppression-non-linear-background-multimode-fibre-cars-endoscope02627nas a2200181 4500008004100000022001400041245005600055210005600111300001100167490000800178520211100186653000802297653000702305100001902312700002302331700001902354856007202373 2022 eng d a0040-609000aSurface topography affects the nanoindentation data0 aSurface topography affects the nanoindentation data a1391050 v7453 aThe near-surface mechanical properties of thin films as well as bulk materials are amongst the key parameters important for their application, and instrumented nanoindentation is a standard technique for determining these mechanical properties. However, it is known that the surface topography of the characterized materials may affect the nanoindentation data when a sharp indenter for small penetration depths (displacements) is used. A thin film of hydrogenated amorphous silicon carbide with a thickness of 1.0 μm was deposited on a silicon wafer by plasma-enhanced chemical vapour deposition. The cyclic nanoindentation was used to construct a depth profile of mechanical properties for the flat surface (0.5 nm roughness) of the thin film, which made it possible to determine its modulus of elasticity of 83 GPa and hardness of 8.6 GPa unaffected by the silicon substrate. Grains with a spherical cap geometry with a typical radius of 0.5 µm and a height of 60 nm are distributed along the flat surface of the film. The grains have the same mechanical properties as the deposited film. Depth profiles of mechanical properties were determined for different types of contact between the Berkovich indenter with a radius of 50 nm and the selected grain (grain top, grain foot, two or three grains); i.e. for these measurements the following applied - the radius of the tip curvature was less than grain radii (RBerkovich < Rgrain). Residual imprints after nanoindentation measurements were carefully observed by atomic force microscopy and scanning electron microscopy. The near-surface mechanical properties were significantly affected by the surface topography, and the determined modulus of elasticity and hardness were crucially under- or overestimated in the range of 50% to 100% compared to the real values. The nature of these deviations was discussed. The solution is to use cyclic nanoindentation performed on the flat surfaces or on the top of grains, followed by extrapolation of the depth profiles to the zero-contact depth (film surface).
10aAIF10aMF1 aPlichta, Tomas1 aZahradnicek, Radim1 aCech, Vladimir uhttps://www.sciencedirect.com/science/article/pii/S004060902200026802406nas a2200205 4500008004100000022001400041245009600055210006900151300000800220490000700228520179900235653000802034653000702042100002102049700002602070700001802096700002102114700002102135856004402156 2021 eng d a2073-436000aThe Adhesion of Plasma Nanocoatings Controls the Shear Properties of GF/Polyester Composite0 aAdhesion of Plasma Nanocoatings Controls the Shear Properties of a5930 v133 aHigh-performance fibre-reinforced polymer composites are important construction materials based not only on the specific properties of the reinforcing fibres and the flexible polymer matrix but also on the compatible properties of the composite interphase. First, oxygen-free (a-CSi:H) and oxygen-binding (a-CSiO:H) plasma nanocoatings of different mechanical and tribological properties were deposited on planar silicon dioxide substrates that closely mimic E-glass. The nanoscratch test was used to characterize the nanocoating adhesion expressed in terms of critical normal load and work of adhesion. Next, the same nanocoatings were deposited on E-glass fibres, which were used as reinforcements in the polyester composite to affect its interphase properties. The shear properties of the polymer composite were characterized by macro- and micromechanical tests, namely a short beam shear test to determine the short-beam strength and a single fibre push-out test to determine the interfacial shear strength. The results of the polymer composites showed a strong correlation between the short-beam strength and the interfacial shear strength, proving that both tests are sensitive to changes in fibre-matrix adhesion due to different surface modifications of glass fibres (GF). Finally, a strong correlation between the shear properties of the GF/polyester composite and the adhesion of the plasma nanocoating expressed through the work of adhesion was demonstrated. Thus, increasing the work of adhesion of plasma nanocoatings from 0.8 to 1.5 mJ·m−2 increased the short-beam strength from 23.1 to 45.2 MPa. The results confirmed that the work of adhesion is a more suitable parameter in characterising the level of nanocoating adhesion in comparison with the critical normal load.
10aAIF10aMF1 aPlichta, Tomáš1 aŠirjovová, Veronika1 aZvonek, Milan1 aKalinka, Gerhard1 aČech, Vladimír uhttps://www.mdpi.com/2073-4360/13/4/59300664nas a2200193 4500008004100000022001400041245010900055210006900164260001000233300001100243490000800254653000700262653000700269100002000276700002000296700001700316700001500333856012200348 2021 eng d a1385-894700aAn aerogel-based photocatalytic microreactor driven by light guiding for degradation of toxic pollutants0 aaerogelbased photocatalytic microreactor driven by light guiding cAPR 1 a1281080 v40910aLF10aMF1 aOzbakir, Yaprak1 aJonas, Alexandr1 aKiraz, Alper1 aErkey, Can uhttps://www.isibrno.cz/cs/aerogel-based-photocatalytic-microreactor-driven-light-guiding-degradation-toxic-pollutants01082nas a2200193 4500008004100000245005100041210005000092260000800142300001800150490000700168520054400175653000700719653000700726100001900733700002700752700002300779700002100802856006500823 2021 eng d00aAll-optical manipulation of photonic membranes0 aAlloptical manipulation of photonic membranes cMay a14260–142680 v293 aWe demonstrate the all-optical manipulation of polymeric membranes in microfluidic environments. The membranes are decorated with handles for their use in holographic optical tweezers systems. Our results show that due to their form factor the membranes present a substantial increase in their mechanical stability, respect to micrometric dielectric particles. This intrinsic superior stability is expected to improve profoundly a wide range of bio-photonic applications that rely on the optical manipulation of micrometric objects.
10aKF10aMF1 aAskari, Meisam1 aKirkpatrick, Blair, C.1 aČižmár, Tomáš1 aDi Falco, Andrea uhttp://www.opticsexpress.org/abstract.cfm?URI=oe-29-10-1426000713nas a2200229 4500008004100000022001400041245008000055210006900135260001100204300000700215490000700222653000700229653000700236100001500243700002200258700002000280700002300300700002100323700001800344700002400362856009700386 2021 eng d a2047-753800aCompressively sampling the optical transmission matrix of a multimode fibre0 aCompressively sampling the optical transmission matrix of a mult cAPR 21 a880 v1010aKF10aMF1 aLi, Shuhui1 aSaunders, Charles1 aLum, Daniel, J.1 aMurray-Bruce, John1 aGoyal, Vivek, K.1 aCizmar, Tomas1 aPhillips, David, B. uhttps://www.isibrno.cz/cs/compressively-sampling-optical-transmission-matrix-multimode-fibre00778nas a2200241 4500008004100000245011700041210006900158260000800227300001800235490000700253653000700260653000700267100002200274700001900296700002500315700001600340700002000356700002400376700002300400700002200423700002300445856006800468 2021 eng d00aComputational image enhancement of multimode fibre-based holographic endo-microscopy: harnessing the muddy modes0 aComputational image enhancement of multimode fibrebased holograp cNov a38206–382200 v2910aKF10aMF1 aTučková, Tereza1 aŠiler, Martin1 aFlaes, DE, Boonzajer1 aJákl, Petr1 aTurtaev, Sergey1 aKrátký, Stanislav1 aHeintzmann, Rainer1 aUhlířová, Hana1 aČižmár, Tomáš uhttp://www.osapublishing.org/oe/abstract.cfm?URI=oe-29-23-3820601569nas a2200205 4500008004100000022001400041245006800055210006800123300000900191490000700200520099500207653000701202653000701209100001501216700002601231700001701257700001801274700002401292856004701316 2021 eng d a2041-172300aMemory effect assisted imaging through multimode optical fibres0 aMemory effect assisted imaging through multimode optical fibres a37510 v123 aWhen light propagates through opaque material, the spatial information it holds becomes scrambled, but not necessarily lost. Two classes of techniques have emerged to recover this information: methods relying on optical memory effects, and transmission matrix (TM) approaches. Here we develop a general framework describing the nature of memory effects in structures of arbitrary geometry. We show how this framework, when combined with wavefront shaping driven by feedback from a guide-star, enables estimation of the TM of any such system. This highlights that guide-star assisted imaging is possible regardless of the type of memory effect a scatterer exhibits. We apply this concept to multimode fibres (MMFs) and identify a `quasi-radial' memory effect. This allows the TM of an MMF to be approximated from only one end - an important step for micro-endoscopy. Our work broadens the applications of memory effects to a range of novel imaging and optical communication scenarios.
10aKF10aMF1 aLi, Shuhui1 aHorsley, Simon, A. R.1 aTyc, Tomáš1 aCizmar, Tomas1 aPhillips, David, B. uhttps://doi.org/10.1038/s41467-021-23729-100520nas a2200169 4500008004100000245008100041210006900122300001100191490000600202653000700208653000700215100001900222700002000241700002800261700002300289856003800312 2021 eng d00aObserving distant objects with a multimode fiber-based holographic endoscope0 aObserving distant objects with a multimode fiberbased holographi a0361120 v610aKF10aMF1 aLeite, Ivo, T.1 aTurtaev, Sergey1 aFlaes, Dirk, E. Boonzaj1 aČižmár, Tomáš uhttps://doi.org/10.1063/5.003836700792nas a2200241 4500008004100000245010900041210006900150260001100219300001800230490000700248653000700255653000700262653000700269100002000276700002000296700001600316700002300332700002000355700001500375700001700390700002000407856012300427 2021 eng d00aOptically transportable optofluidic microlasers with liquid crystal cavities tuned by the electric field0 aOptically transportable optofluidic microlasers with liquid crys cOCT 21 a50657−506670 v1310aBF10aLF10aMF1 aJonas, Alexandr1 aPilát, Zdeněk1 aJežek, Jan1 aBernatová, Silvie1 aJedlička, Petr1 aAas, Mehdi1 aKiraz, Alper1 aZemánek, Pavel uhttps://www.isibrno.cz/cs/optically-transportable-optofluidic-microlasers-liquid-crystal-cavities-tuned-electric-field00722nas a2200205 4500008004100000245008700041210006900128300001600197490000600213653000700219653000700226100002100233700002200254700002500276700002800301700003400329700001800363700002400381856011100405 2021 eng d00aPolarization-resolved second-harmonic generation imaging through a multimode fiber0 aPolarizationresolved secondharmonic generation imaging through a a1065–10740 v810aKF10aMF1 aCifuentes, Angel1 aPikálek, Tomáš1 aOndráčková, Petra1 aAmezcua-Correa, Rodrigo1 aAntonio-Lopez, José, Enrique1 aCizmar, Tomas1 aTrägårdh, Johanna uhttps://www.isibrno.cz/cs/polarization-resolved-second-harmonic-generation-imaging-through-multimode-fiber00548nas a2200181 4500008004100000022001400041245006900055210006500124260000800189300001400197490000700211653000700218653000700225100001500232700002300247700001700270856007900287 2021 eng d a2192-860600aThe potential of SERS as an AST methodology in clinical settings0 apotential of SERS as an AST methodology in clinical settings cAUG a2537-25610 v1010aBF10aMF1 aSamek, Ota1 aBernatová, Silvie1 aDohnal, Fadi uhttps://www.isibrno.cz/cs/potential-sers-ast-methodology-clinical-settings00944nas a2200325 4500008004100000022001400041245009900055210006900154300000800223490000700231653000700238653000700245100002200252700002000274700002000294700001900314700001400333700001900347700002700366700002300393700001900416700001600435700002300451700002400474700002200498700001900520700001500539700002000554856004400574 2021 eng d a2079-637400aRaman Microspectroscopic Analysis of Selenium Bioaccumulation by Green Alga Chlorella vulgaris0 aRaman Microspectroscopic Analysis of Selenium Bioaccumulation by a1150 v1110aBF10aMF1 aKizovský, Martin1 aPilát, Zdeněk1 aMylenko, Mykola1 aHrouzek, Pavel1 aKuta, Jan1 aSkoupý, Radim1 aKrzyžánek, Vladislav1 aHrubanová, Kamila1 aAdamczyk, Olga1 aJežek, Jan1 aBernatová, Silvie1 aKlementová, Tereza1 aGjevik, Alžběta1 aŠiler, Martin1 aSamek, Ota1 aZemánek, Pavel uhttps://www.mdpi.com/2079-6374/11/4/11500794nas a2200289 4500008004100000245008900041210006900130300000800199490000800207653000700215653000700222653000700229100001900236700002000255700001500275700001500290700001500305700001400320700001500334700001500349700001800364700002000382700001400402700001900416700001700435856005200452 2021 eng d00aRapid detection of antibiotic sensitivity of Staphylococcus aureus by Raman tweezers0 aRapid detection of antibiotic sensitivity of Staphylococcus aure a2330 v13610aBF10aKF10aMF1 aBernatová, S.1 aRebrošová, K.1 aPilát, Z.1 aŠerý, M.1 aGjevik, A.1 aSamek, O.1 aJežek, J.1 aŠiler, M.1 aKizovský, M.1 aKlementová, T.1 aHolá, V.1 aRůžička, F.1 aZemánek, P. uhttps://doi.org/10.1140/epjp/s13360-021-01152-102024nas a2200217 4500008004100000245008100041210006900122300001800191490000700209520135300216653000701569653000701576100002601583700002201609700002401631700002501655700001601680700001901696700002301715856006801738 2021 eng d00aSide-view holographic endomicroscopy via a custom-terminated multimode fibre0 aSideview holographic endomicroscopy via a customterminated multi a23083–230950 v293 aMicroendoscopes based on optical fibres have recently come to the fore as promising candidates allowing in-vivo observations of otherwise inaccessible biological structures in animal models. Despite being still in its infancy, imaging can now be performed at the tip of a single multimode fibre, by relying on powerful holographic methods for light control. Fibre based endoscopy is commonly performed en face, resulting in possible damage of the specimen owing to the direct contact between the distal end of the probe and target. On this ground, we designed an all-fibre probe with an engineered termination that reduces compression and damage to the tissue under investigation upon probe insertion. The geometry of the termination brings the field of view to a plane parallel to the fibre&\#x2019;s longitudinal direction, conveying the probe with off-axis imaging capabilities. We show that its focusing ability also benefits from a higher numerical aperture, resulting in imaging with increased spatial resolution. The effect of probe insertion was investigated inside a tissue phantom comprising fluorescent particles suspended in agarose gel, and a comparison was established between the novel side-view probe and the standard en face fibre probe. This new concept paves the way to significantly less invasive deep-tissue imaging.
10aKF10aMF1 aSilveira, Beatriz, M.1 aPikálek, Tomáš1 aStibůrek, Miroslav1 aOndráčková, Petra1 aJákl, Petr1 aLeite, Ivo, T.1 aČižmár, Tomáš uhttp://www.osapublishing.org/oe/abstract.cfm?URI=oe-29-15-2308300741nas a2200241 4500008004100000245007000041210006900111260000800180300001400188490000600202653000700208653000700215100001800222700002400240700002200264700001900286700002200305700001600327700002500343700002000368700002100388856009000409 2021 eng d00aStochastic dynamics of optically bound matter levitated in vacuum0 aStochastic dynamics of optically bound matter levitated in vacuu cFeb a220–2290 v810aLF10aMF1 aSvak, Vojtech1 aFlajšmanová, Jana1 aChvátal, Lukáš1 aŠiler, Martin1 aJonáš, Alexandr1 aJežek, Jan1 aSimpson, Stephen, H.1 aZemánek, Pavel1 aBrzobohatý, Oto uhttps://www.isibrno.cz/cs/stochastic-dynamics-optically-bound-matter-levitated-vacuum00583nas a2200193 4500008004100000022001400041245006000055210006000115260001100175300001100186490000800197653000700205653000700212100002500219700002100244700002100265700002000286856008300306 2021 eng d a2469-992600aStochastic Hopf bifurcations in vacuum optical tweezers0 aStochastic Hopf bifurcations in vacuum optical tweezers cOCT 15 a0435180 v10410aLF10aMF1 aSimpson, Stephen, H.1 aArita, Yoshihiko1 aDholakia, Kishan1 aZemánek, Pavel uhttps://www.isibrno.cz/cs/stochastic-hopf-bifurcations-vacuum-optical-tweezers00599nas a2200193 4500008004100000245008400041210006900125260000800194300001800202490000700220653000700227653000700234100002100241700001300262700002000275700001900295700002300314856006800337 2021 eng d00aThermal stability of wavefront shaping using a DMD as a spatial light modulator0 aThermal stability of wavefront shaping using a DMD as a spatial cDec a41808–418180 v2910aKF10aMF1 aRudolf, Benjamin1 aDu, Yang1 aTurtaev, Sergey1 aLeite, Ivo, T.1 aČižmár, Tomáš uhttp://www.osapublishing.org/oe/abstract.cfm?URI=oe-29-25-4180801932nas a2200169 4500008004100000245006100041210006000102300001800162490000700180520142200187653000701609653000701616100002701623700002101650700002301671856006801694 2021 eng d00aTime-averaged image projection through a multimode fiber0 aTimeaveraged image projection through a multimode fiber a28005–280200 v293 aMany disciplines, ranging from lithography to opto-genetics, require high-fidelity image projection. However, not all optical systems can display all types of images with equal ease. Therefore, the image projection quality is dependent on the type of image. In some circumstances, this can lead to a catastrophic loss of intensity or image quality. For complex optical systems, it may not be known in advance which types of images pose a problem. Here we show a new method called Time-Averaged image Projection (TAP), allowing us to mitigate these limitations by taking the entire image projection system into account despite its complexity and building the desired intensity distribution up from multiple illumination patterns. Using a complex optical setup, consisting of a wavefront shaper and a multimode optical fiber illuminated by coherent light, we succeeded to suppress any speckle-related background. Further, we can display independent images at multiple distances simultaneously, and alter the effective sharpness depth through the algorithm. Our results demonstrate that TAP can significantly enhance the image projection quality in multiple ways. We anticipate that our results will greatly complement any application in which the response to light irradiation is relatively slow (one microsecond with current technology) and where high-fidelity spatial distribution of optical power is required.
10aKF10aMF1 aFlaes, Dirk, Boonzajer1 aŠtolzová, Hana1 aČižmár, Tomáš uhttp://www.osapublishing.org/oe/abstract.cfm?URI=oe-29-18-2800500646nas a2200205 4500008004100000245006300041210006100104300001400165490000800179653000700187653000700194100002000201700002400221700002600245700001700271700002000288700002300308700002300331856008600354 2021 eng d00aTime-of-flight 3D imaging through multimode optical fibers0 aTimeofflight 3D imaging through multimode optical fibers a1395-13990 v37410aKF10aMF1 aStellinga, Daan1 aPhillips, David, B.1 aMekhail, Simon, Peter1 aSelyem, Adam1 aTurtaev, Sergey1 aČižmár, Tomáš1 aPadgett, Miles, J. uhttps://www.isibrno.cz/cs/time-flight-3d-imaging-through-multimode-optical-fibers00782nas a2200253 4500008004100000022001400041245009000055210006900145260001100214300000700225490000800232653000700240653000700247100001700254700001700271700002700288700002000315700001300335700002000348700001700368700001900385700001400404856011000418 2021 eng d a2190-544400aT-matrix calculations of spin-dependent optical forces in optically trapped nanowires0 aTmatrix calculations of spindependent optical forces in opticall cJAN 16 a860 v13610aLF10aMF1 aPolimeno, P.1 aIati, M., A.1 aBoschi, Degli, Esposti1 aSimpson, S., H.1 aSvak, V.1 aBrzobohatý, O.1 aZemánek, P.1 aMarago, O., M.1 aSaija, R. uhttps://www.isibrno.cz/cs/t-matrix-calculations-spin-dependent-optical-forces-optically-trapped-nanowires02317nas a2200217 4500008004100000022001400041245010000055210006900155300000800224490000600232520167900238653000701917653000701924100002201931700002201953700001501975700002301990700002302013700002002036856004302056 2021 eng d a2076-260700aThe Use of Raman Spectroscopy to Monitor Metabolic Changes in Stressed Metschnikowia sp. Yeasts0 aUse of Raman Spectroscopy to Monitor Metabolic Changes in Stress a2770 v93 aRaman spectroscopy is a universal method designed for the analysis of a wide range of physical, chemical and biological systems or various surfaces. This technique is suitable to monitor various components of cells, tissues or microorganisms. The advantages include very fast non-contact and non-destructive analysis and no or minimal need for sample treatment. The yeasts Metschnikowia can be considered as industrially usable producers of pulcherrimin or single-cell lipids, depending on cultivation conditions and external stress. In the present study, Raman spectroscopy was used as an effective tool to identify both pulcherrimin and lipids in single yeast cells. The analysis of pulcherrimin is very demanding; so far, there is no optimal procedure to analyze or identify this pigment. Based on results, the strong dependence of pulcherrimin production on the ferric ion concentration was found with the highest yield in media containing 0.1 g/L iron. Further, production of lipids in Metschnikowia cells was studied at different temperatures and C:N ratios, using Raman spectroscopy to follow fatty acids composition, under different regimes, by monitoring the iodine number. The results of Raman spectroscopy were comparable with the fatty acid analysis obtained by gas chromatography. This study therefore supported use of Raman spectroscopy for biotechnological applications as a simple tool in the identification and analysis both the pulcherrimin and microbial lipids. This method provides a quick and relatively accurate estimation of targeted metabolites with minimal sample modification and allows to monitor metabolic changes over time of cultivation.
10aBF10aMF1 aNěmcová, Andrea1 aGonová, Dominika1 aSamek, Ota1 aSipiczki, Matthias1 aBreierová, Emilia1 aMárová, Ivana uhttps://www.mdpi.com/2076-2607/9/2/27703030nas a2200217 4500008004100000022001400041245010800055210006900163300000900232490000600241520238000247653000702627653000702634100002202641700002302663700001502686700002302701700002302724700002002747856004502767 2021 eng d a2076-260700aUse of Waste Substrates for the Lipid Production by Yeasts of the Genus Metschnikowia—Screening Study0 aUse of Waste Substrates for the Lipid Production by Yeasts of th a22950 v93 aOleogenic yeasts are characterized by the ability to accumulate increased amounts of lipids under certain conditions. These microbial lipids differ in their fatty acid composition, which allows them to be widely used in the biotechnology industry. The interest of biotechnologists is closely linked to the rising prices of fossil fuels in recent years. Their negative environmental impact is caused by significantly increased demand for biodiesel. The composition of microbial lipids is very similar to vegetable oils, which provides great potential for use in the production of biodiesel. In addition, some oleogenic microorganisms are capable of producing lipids with a high proportion of unsaturated fatty acids. The presented paper’s main aim was to study the production of lipids and lipid substances by yeasts of the genus Metschnikowia, to cultivate crude waste animal fat to study its utilization by yeasts, and to apply the idea of circular economy in the biotechnology of Metschnikowia yeasts. The work focuses on the influence of various stress factors in the cultivation process, such as reduced temperature or nutritional stress through the use of various waste substrates, together with manipulating the ratio of carbon and nitrogen sources in the medium. Yeast production properties were monitored by several instrumental techniques, including gas chromatography and Raman spectroscopy. The amount of lipids and in particular the fatty acid composition varied depending on the strains studied and the culture conditions used. The ability of yeast to produce significant amounts of unsaturated fatty acids was also demonstrated in the work. The most suitable substrate for lipid production was a medium containing glycerol, where the amount of accumulated lipids in the yeast M. pulcherrima 1232 was up to 36%. In our work, the crude animal fat was used for the production of high-value lipids, which to the best of our knowledge is a new result. Moreover, quantitative screening of lipase enzyme activity cultivated on animal fat substrate on selected yeasts of the genus Metschnikowia was performed. We found that for the yeast utilizing glycerol, animal fat seems to be an excellent source of carbon. Therefore, the yeast conversion of crude processed animal fat to value-added products is a valuable process for the biotechnology and food industry.
10aBF10aMF1 aNěmcová, Andrea1 aSzotkowski, Martin1 aSamek, Ota1 aCagáňová, Linda1 aSipiczki, Matthias1 aMárová, Ivana uhttps://www.mdpi.com/2076-2607/9/11/229500802nas a2200289 4500008004100000245006500041210006400106300001800170490000700188653000700195653000700202653000700209100001400216700001500230700001800245700001900263700001800282700001400300700001400314700001700328700001800345700001700363700001800380700001300398700001600411856008500427 2020 eng d00aAnalysis of bacteriophage-host interaction by Raman tweezers0 aAnalysis of bacteriophagehost interaction by Raman tweezers a12304–123110 v9210aBF10aKF10aMF1 aPilát, Z1 aJonáš, A1 aPilátová, J1 aKlementová, T1 aBernatová, S1 aŠiler, M1 aMaňka, T1 aKizovský, M1 aRůžička, F1 aPanůček, R1 aNeugebauer, U1 aSamek, O1 aZemánek, P uhttps://www.isibrno.cz/cs/analysis-bacteriophage-host-interaction-raman-tweezers00808nas a2200277 4500008004100000245005500041210005500096300001400151490000800165653000700173653000700180100001900187700002200206700001700228700001800245700002000263700001900283700002100302700002200323700001900345700001900364700002500383700002300408700001800431856008100449 2020 eng d00aCellular locomotion using environmental topography0 aCellular locomotion using environmental topography a582–5850 v58210aKF10aMF1 aReversat, Anne1 aGaertner, Florian1 aMerrin, Jack1 aStopp, Julian1 aTasciyan, Saren1 aAguilera, Juan1 ade Vries, Ingrid1 aHauschild, Robert1 aHons, Miroslav1 aPiel, Matthieu1 aCallan-Jones, Andrew1 aVoituriez, Raphael1 aSixt, Michael uhttps://www.isibrno.cz/cs/cellular-locomotion-using-environmental-topography00607nas a2200157 4500008004100000245013200041210006900173490000600242653000700248653000700255100001300262700001600275700001600291700001600307856012600323 2020 eng d00aCoherent oscillations of a levitated birefringent microsphere in vacuum driven by nonconservative rotation-translation coupling0 aCoherent oscillations of a levitated birefringent microsphere in0 v610aLF10aMF1 aArita, Y1 aSimpson, SH1 aZemánek, P1 aDholakia, K uhttps://www.isibrno.cz/cs/coherent-oscillations-levitated-birefringent-microsphere-vacuum-driven-nonconservative-rotation00604nas a2200169 4500008004100000245009400041210006900135300001800204490000700222653000700229653000700236100002100243700002200264700001900286700002000305856010900325 2020 eng d00aComplex colloidal structures with non-linear optical properties formed in an optical trap0 aComplex colloidal structures with nonlinear optical properties f a37700–377070 v2810aLF10aMF1 aBrzobohatý, Oto1 aChvátal, Lukáš1 aŠiler, Martin1 aZemánek, Pavel uhttps://www.isibrno.cz/cs/complex-colloidal-structures-non-linear-optical-properties-formed-optical-trap01337nas a2200205 4500008004100000022001400041245006800055210006600123300000800189490000600197520075000203653000700953653000700960653000700967100002000974700002300994700002401017700002501041856006501066 2020 eng d a2296-424X00aEntropy Production in an Elementary, Light Driven Micro-Machine0 aEntropy Production in an Elementary Light Driven MicroMachine a5380 v83 aWe consider the basic, thermodynamic properties of an elementary micro-machine operating at colloidal length scales. In particular, we track and analyze the driven stochastic motion of a carefully designed micro-propeller rotating unevenly in an optical tweezers, in water. In this intermediate regime, the second law of macroscopic thermodynamics is satisfied only as an ensemble average, and individual trajectories can be temporarily associated with decreases in entropy. We show that our light driven micro-propeller satisfies an appropriate fluctuation theorem that constrains the probability with which these apparent violations of the second law occur. Implications for the development of more complex micro-machines are discussed.
10aKF10aLF10aMF1 aBox, Stuart, J.1 aAllen, Michael, P.1 aPhillips, David, B.1 aSimpson, Stephen, H. uhttps://www.frontiersin.org/article/10.3389/fphy.2020.59312200723nas a2200217 4500008004100000245011200041210006900153490000600222653000700228653000700235100001500242700001400257700001600271700001600287700001500303700001300318700001400331700001600345700001500361856012900376 2020 eng d00aNanovortex-driven all-dielectric optical diffusion boosting and sorting concept for lab-on-a-chip platforms0 aNanovortexdriven alldielectric optical diffusion boosting and so0 v710aLF10aMF1 aValero, AC1 aKislov, D1 aGurvitz, EA1 aShamkhi, HK1 aPavlov, AA1 aRedka, D1 aYankin, S1 aZemánek, P1 aShalin, AS uhttps://www.isibrno.cz/cs/nanovortex-driven-all-dielectric-optical-diffusion-boosting-and-sorting-concept-lab-chip-platforms00693nas a2200205 4500008004100000245011300041210006900154300001600223490000700239653000700246653000700253100001500260700001500275700001400290700001400304700001500318700001300333700001300346856012800359 2020 eng d00aSize-based sorting of emulsion droplets in microfluidic channels patterned with laser-ablated guiding tracks0 aSizebased sorting of emulsion droplets in microfluidic channels a2597–26040 v9210aLF10aMF1 aRehman, AU1 aCoskun, UC1 aRashid, Z1 aMorova, B1 aJonáš, A1 aErten, A1 aKiraz, A uhttps://www.isibrno.cz/cs/size-based-sorting-emulsion-droplets-microfluidic-channels-patterned-laser-ablated-guiding-tracks00739nas a2200205 4500008004100000245012400041210006900165300001000234490000700244653000700251653000700258100002400265700001900289700002000308700002300328700002100351700001700372700002000389856012400409 2020 eng d00aUsing the transient trajectories of an optically levitated nanoparticle to characterize a stochastic Duffing oscillator0 aUsing the transient trajectories of an optically levitated nanop a144360 v1010aLF10aMF1 aFlajšmanová, Jana1 aŠiler, Martin1 aJedlička, Petr1 aHrubý, František1 aBrzobohatý, Oto1 aFilip, Radim1 aZemánek, Pavel uhttps://www.isibrno.cz/cs/using-transient-trajectories-optically-levitated-nanoparticle-characterize-stochastic-duffing00853nas a2200253 4500008004100000245013600041210006900177300001600246490000700262653000700269653000700276100001700283700001600300700001500316700001900331700001800350700001500368700001500383700001700398700001900415700001900434700001500453856013100468 2019 eng d00aControlled Oil/Water Partitioning of Hydrophobic Substrates Extending the Bioanalytical Applications of Droplet-Based Microfluidics0 aControlled OilWater Partitioning of Hydrophobic Substrates Exten a10008-100150 v9110aBF10aMF1 aBuryška, T.1 aVašina, M.1 aGielen, F.1 aVaňáček, P.1 avan Vliet, L.1 aJežek, J.1 aPilát, Z.1 aZemánek, P.1 aDamborský, J.1 aHollfelder, F.1 aProkop, Z. uhttps://www.isibrno.cz/cs/controlled-oilwater-partitioning-hydrophobic-substrates-extending-bioanalytical-applications-droplet00680nas a2200205 4500008004100000245010400041210006900145300001000214490000800224653000700232653000700239100001900246700001800265700001900283700001900302700001400321700001600335700001400351856010900365 2019 eng d00aThe effects of the treatment conditions on the dissolution profile of ethylcellulose coated pellets0 aeffects of the treatment conditions on the dissolution profile o a86-950 v13210aBF10aMF1 aPavloková, S.1 aMušelík, J.1 aSabadková, D.1 aBernatová, S.1 aSamek, O.1 aNeumann, D.1 aFranc, A. uhttps://www.isibrno.cz/cs/effects-treatment-conditions-dissolution-profile-ethylcellulose-coated-pellets01576nas a2200241 4500008004100000245012300041210006900164300001200233490000700245520085700252653000701109653000701116653000701123100002701130700001901157700001501176700002201191700002301213700001601236700002001252700002001272856004201292 2019 eng d00aIdentification of ability to form biofilm in Candida parapsilosis and Staphylococcus epidermidis by Raman spectroscopy0 aIdentification of ability to form biofilm in Candida parapsilosi a509-5170 v143 aAim: Finding rapid, reliable diagnostic methods is a big challenge in clinical microbiology. Raman spectroscopy is an optical method used for multiple applications in scientific fields including microbiology. This work reports its potential in identifying biofilm positive strains of Candida parapsilosis and Staphylococcus epidermidis. Materials & methods: We tested 54 S. epidermidis strains (23 biofilm positive, 31 negative) and 51 C. parapsilosis strains (27 biofilm positive, 24 negative) from colonies on Mueller-Hinton agar plates, using Raman spectroscopy. Results: The accuracy was 98.9% for C. parapsilosis and 96.1% for S. epidermidis. Conclusion: The method showed great potential for identifying biofilm positive bacterial and yeast strains. We suggest that Raman spectroscopy might become a useful aid in clinical diagnostics.
10aBF10aKF10aMF1 aRebrošová, Katarína1 aŠiler, Martin1 aSamek, Ota1 aRůžička, Filip1 aBernatová, Silvie1 aJežek, Jan1 aZemánek, Pavel1 aHolá, Veronika uhttps://doi.org/10.2217/fmb-2018-029701412nas a2200205 4500008004100000245006700041210006600108300001800174490000700192520080300199653000701002653000701009100002401016700002201040700002001062700001801082700001801100700002301118856006501141 2019 eng d00aLabel-free CARS microscopy through a multimode fiber endoscope0 aLabelfree CARS microscopy through a multimode fiber endoscope a30055–300660 v273 aMultimode fibres have recently been employed as high-resolution ultra-thin endoscopes, capable of imaging biological structures deep inside tissue in vivo. Here, we extend this technique to label-free non-linear microscopy with chemical contrast using coherent anti-Stokes Raman scattering (CARS) through a multimode fibre endoscope, which opens up new avenues for instant and in-situ diagnosis of potentially malignant tissue. We use a commercial 125 &\#x00B5;m diameter, 0.29 NA GRIN fibre, and wavefront shaping on an SLM is used to create foci that are scanned behind the fibre facet across the sample. The chemical selectivity is demonstrated by imaging 2 &\#x00B5;m polystyrene and 2.5 &\#x00B5;m PMMA beads with per pixel integration time as low as 1 ms for epi-detection.
10aKF10aMF1 aTrägårdh, Johanna1 aPikálek, Tomáš1 aŠerý, Mojmír1 aMeyer, Tobias1 aPopp, Jürgen1 aČižmár, Tomáš uhttp://www.opticsexpress.org/abstract.cfm?URI=oe-27-21-3005500711nas a2200205 4500008004100000022001400041245009900055210006900154260001100223300001400234490000700248653000700255653000700262100002000269700002300289700002700312700002100339700002500360856012000385 2019 eng d a0743-746300aMechanical Contact Spectroscopy: Characterizing Nanoscale Adhesive Contacts via Thermal Forces0 aMechanical Contact Spectroscopy Characterizing Nanoscale Adhesiv cAPR 30 a5809-58200 v3510aLF10aMF1 aJonas, Alexandr1 aKochanczyk, Martin1 aRamirez, Alexandro, D.1 aSpeidel, Michael1 aFlorin, Ernst-Ludwig uhttps://www.isibrno.cz/cs/mechanical-contact-spectroscopy-characterizing-nanoscale-adhesive-contacts-thermal-forces00613nas a2200205 4500008004100000245006400041210006400105260000800169300001800177490000700195653000700202653000700209100002100216700002100237700001900258700001800277700002300295700002400318856006500342 2019 eng d00aNanobore fiber focus trap with enhanced tuning capabilities0 aNanobore fiber focus trap with enhanced tuning capabilities cDec a36221–362300 v2710aKF10aMF1 aPlidschun, Malte1 aWeidlich, Stefan1 aŠiler, Martin1 aWeber, Karina1 aČižmár, Tomáš1 aSchmidt, Markus, A. uhttp://www.opticsexpress.org/abstract.cfm?URI=oe-27-25-3622100809nas a2200229 4500008004100000245011300041210006900154300001200223490000700235653000700242653000700249100002200256700002100278700002000299700002000319700002600339700002300365700001800388700002500406700001700431856013100448 2019 eng d00aOptical Trapping, Optical Binding, and Rotational Dynamics of Silicon Nanowires in Counter-Propagating Beams0 aOptical Trapping Optical Binding and Rotational Dynamics of Sili a342-3520 v1910aLF10aMF1 aDonato, Maria, G.1 aBrzobohatý, Oto1 aSimpson, S., H.1 aIrrera, Alessia1 aLeonardi, Antonio, A.1 aFaro, Maria, J. Lo1 aSvak, Vojtech1 aMaragò, Onofrio, M.1 aZemánek, P. uhttps://www.isibrno.cz/cs/optical-trapping-optical-binding-and-rotational-dynamics-silicon-nanowires-counter-propagating-beams00540nas a2200157 4500008004100000245007800041210006900119300001200188490000700200653000700207653000700214100002100221700002200242700001700264856010100281 2019 eng d00aOptomechanical properties of optically self-arranged colloidal waveguides0 aOptomechanical properties of optically selfarranged colloidal wa a707-7100 v4410aLF10aMF1 aBrzobohatý, Oto1 aChvátal, Lukáš1 aZemánek, P. uhttps://www.isibrno.cz/cs/optomechanical-properties-optically-self-arranged-colloidal-waveguides00729nas a2200217 4500008004100000022001400041245011000055210006900165260000800234300000700242490000700249653000700256653000700263100002000270700001700290700001800307700002100325700002000346700001700366856012800383 2019 eng d a1613-498200aPassive sorting of emulsion droplets with different interfacial properties using laser-patterned surfaces0 aPassive sorting of emulsion droplets with different interfacial cMAY a650 v2310aLF10aMF1 aRashid, Zeeshan1 aErten, Ahmet1 aMorova, Berna1 aMuradoglu, Metin1 aJonas, Alexandr1 aKiraz, Alper uhttps://www.isibrno.cz/cs/passive-sorting-emulsion-droplets-different-interfacial-properties-using-laser-patterned-surfaces00566nas a2200181 4500008004100000245009600041210006900137260000800206300001400214490000700228653000700235653000700242100002000249700001900269700002200288700002100310856005300331 2019 eng d00aPerspective on light-induced transport of particles: from optical forces to phoretic motion0 aPerspective on lightinduced transport of particles from optical cSep a577–6780 v1110aLF10aMF1 aZemánek, Pavel1 aVolpe, Giorgio1 aJonáš, Alexandr1 aBrzobohatý, Oto uhttp://aop.osa.org/abstract.cfm?URI=aop-11-3-57700571nas a2200169 4500008004100000245008000041210006900121300001300190490000600203653000700209653000700216100002600223700002200249700001300271700001700284856010000301 2019 eng d00aSpin to orbital light momentum conversion visualized by particle trajectory0 aSpin to orbital light momentum conversion visualized by particle a4127:1-70 v910aLF10aMF1 aArzola, Alejandro, V.1 aChvátal, Lukáš1 aJákl, P1 aZemánek, P. uhttps://www.isibrno.cz/cs/spin-orbital-light-momentum-conversion-visualized-particle-trajectory00618nas a2200205 4500008004100000245006600041210006500107300001200172490000600184653000700190653000700197100002100204700002200225700001600247700001400263700001500277700001400292700001700306856008900323 2019 eng d00aTunable Soft-Matter Optofluidic Waveguides Assembled by Light0 aTunable SoftMatter Optofluidic Waveguides Assembled by Light a403-4100 v610aLF10aMF1 aBrzobohatý, Oto1 aChvátal, Lukáš1 aJonáš, A.1 aŠiler, M1 aKaňka, J.1 aJežek, J1 aZemánek, P. uhttps://www.isibrno.cz/cs/tunable-soft-matter-optofluidic-waveguides-assembled-light00552nas a2200193 4500008004100000245004300041210004300084300001100127490000800138653000700146653000700153100001800160700001900178700002400197700002100221700001600242700003100258856006900289 2019 eng d00aVisualizing gravitational Bessel waves0 aVisualizing gravitational Bessel waves a0440500 v10010aLF10aMF1 aPaták, Aleš1 aZouhar, Martin1 aŘiháček, Tomáš1 aBrzobohatý, Oto1 aGeršl, Jan1 aCampbell, Anna, Charvátov uhttps://www.isibrno.cz/cs/visualizing-gravitational-bessel-waves01270nas a2200181 4500008004100000245007300041210006900114300001800183490000700201520071100208653000700919653000700926100002200933700002400955700002100979700002301000856006501023 2019 eng d00aWavelength dependent characterization of a multimode fibre endoscope0 aWavelength dependent characterization of a multimode fibre endos a28239–282530 v273 aMultimode fibres have recently shown promise as miniature endoscopic probes. When used for non-linear microscopy, the bandwidth of the imaging system limits the ability to focus light from broadband pulsed lasers as well as the possibility of wavelength tuning during the imaging. We demonstrate that the bandwidth is limited by the dispersion of the off-axis hologram displayed on the SLM, which can be corrected for, and by the limited bandwidth of the fibre itself. The selection of the fibre is therefore crucial for these experiments. In addition, we show that a standard prism pulse compressor is sufficient for material dispersion compensation for multi-photon imaging with a fibre endoscope.
10aKF10aMF1 aPikálek, Tomáš1 aTrägårdh, Johanna1 aSimpson, Stephen1 aČižmár, Tomáš uhttp://www.opticsexpress.org/abstract.cfm?URI=oe-27-20-2823900780nas a2200229 4500008004100000245010000041210006900141300001400210490000800224653000700232653000700239100002300246700002600269700001600295700001500311700001500326700002400341700002500365700002000390700002600410856011400436 2019 eng d00aWavelength-Dependent Optical Force Aggregation of Gold Nanorods for SERS in a Microfluidic Chip0 aWavelengthDependent Optical Force Aggregation of Gold Nanorods f a5608-56150 v12310aBF10aMF1 aBernatová, Silvie1 aDonato, Maria, Grazia1 aJežek, Jan1 aPilát, Z.1 aSamek, Ota1 aMagazzu, Alessandro1 aMaragò, Onofrio, M.1 aZemánek, Pavel1 aGucciardi, Pietro, G. uhttps://www.isibrno.cz/cs/wavelength-dependent-optical-force-aggregation-gold-nanorods-sers-microfluidic-chip00803nas a2200241 4500008004100000245011300041210006900154300001400223490000800237653000700245653000700252100001900259700001900278700001300297700001500310700002200325700001700347700001900364700002000383700001400403700001600417856012800433 2019 eng d00aWhat keeps polyhydroxyalkanoates in bacterial cells amorphous? A derivation from stress exposure experiments0 aWhat keeps polyhydroxyalkanoates in bacterial cells amorphous A a1905-19170 v10310aBF10aMF1 aSedláček, P.1 aSlaninová, E.1 aEnev, V.1 aKoller, M.1 aNebesářová, J.1 aMárová, I.1 aHrubanová, K.1 aKrzyžánek, V.1 aSamek, O.1 aObruča, S. uhttps://www.isibrno.cz/cs/what-keeps-polyhydroxyalkanoates-bacterial-cells-amorphous-derivation-stress-exposure-experiments00806nas a2200241 4500008004100000245012300041210006900164300000900233490000800242653000700250653000700257100001900264700001500283700001400298700002000312700001800332700001300350700002200363700001700385700001700402700001500419856013000434 2018 eng d00aCombination of laser-induced breakdown spectroscopy and Raman spectroscopy for multivariate classification of bacteria0 aCombination of laserinduced breakdown spectroscopy and Raman spe a6-120 v13910aBF10aMF1 aProcházka, D.1 aMazura, M.1 aSamek, O.1 aRebrošová, K.1 aPořízka, P.1 aKlus, J.1 aProcházková, P.1 aNovotný, J.1 aNovotný, K.1 aKaiser, J. uhttps://www.isibrno.cz/cs/combination-laser-induced-breakdown-spectroscopy-and-raman-spectroscopy-multivariate-classification00801nas a2200265 4500008004100000245009200041210006900133300000900202490000700211653000700218653000700225100001500232700001800247700001400265700001700279700001500296700001400311700001400325700001700339700001900356700001900375700001500394700001700409856010900426 2018 eng d00aDetection of chloroalkanes by surface-enhanced raman spectroscopy in microfluidic chips0 aDetection of chloroalkanes by surfaceenhanced raman spectroscopy a32120 v1810aBF10aMF1 aPilát, Z.1 aKizovský, M.1 aJežek, J1 aKrátký, S.1 aSobota, J.1 aŠiler, M1 aSamek, O.1 aBuryška, T.1 aVaňáček, P.1 aDamborský, J.1 aProkop, Z.1 aZemánek, P. uhttps://www.isibrno.cz/cs/detection-chloroalkanes-surface-enhanced-raman-spectroscopy-microfluidic-chips00671nas a2200217 4500008004100000245008100041210006900122300001000191490000800201653000700209653000700216100001400223700001800237700002100255700001300276700001800289700001600307700001700323700001700340856009600357 2018 eng d00aDiffusing up the Hill: Dynamics and Equipartition in Highly Unstable Systems0 aDiffusing up the Hill Dynamics and Equipartition in Highly Unsta a236010 v12110aLF10aMF1 aŠiler, M1 aOrnigotti, L.1 aBrzobohatý, Oto1 aJákl, P1 aRyabov, Artem1 aHolubec, V.1 aZemánek, P.1 aFilip, Radim uhttps://www.isibrno.cz/cs/diffusing-hill-dynamics-and-equipartition-highly-unstable-systems00628nas a2200193 4500008004100000245008400041210006900125300001000194490000600204653000700210653000700217100001900224700002200243700001400265700002200279700002100301700001700322856009500339 2018 eng d00aEnhancement of the `tractor-beam' pulling force on an optically bound structure0 aEnhancement of the tractorbeam pulling force on an optically bou a171350 v710aLF10aMF1 aDamková, Jana1 aChvátal, Lukáš1 aJežek, J1 aOulehla, Jindrich1 aBrzobohatý, Oto1 aZemánek, P. uhttps://www.isibrno.cz/cs/enhancement-tractor-beam-pulling-force-optically-bound-structure00629nas a2200193 4500008004100000245008100041210006900122300000700191490000600198653000700204653000700211100001600218700001600234700002400250700001800274700002000292700002300312856010000335 2018 eng d00aHigh-fidelity multimode fibre-based endoscopy for deep brain in vivo imaging0 aHighfidelity multimode fibrebased endoscopy for deep brain in vi a920 v710aKF10aMF1 aTurtaev, S.1 aLeite, I.T.1 aAltwegg-Boussac, T.1 aPakan, J.M.P.1 aRochefort, N.L.1 aČižmár, Tomáš uhttps://www.isibrno.cz/cs/high-fidelity-multimode-fibre-based-endoscopy-deep-brain-vivo-imaging00718nas a2200217 4500008004100000245010100041210006900142300000900211490000700220653000700227653000700234100001500241700002200256700001400278700001800292700001600310700001900326700001400345700001700359856012400376 2018 eng d00aMicrofluidic Cultivation and Laser Tweezers Raman Spectroscopy of E-coli under Antibiotic Stress0 aMicrofluidic Cultivation and Laser Tweezers Raman Spectroscopy o a16230 v1810aBF10aMF1 aPilát, Z.1 aBernatová, Silva1 aJežek, J1 aKirchhoff, J.1 aTannert, A.1 aNeugebauer, U.1 aSamek, O.1 aZemánek, P. uhttps://www.isibrno.cz/cs/microfluidic-cultivation-and-laser-tweezers-raman-spectroscopy-e-coli-under-antibiotic-stress00714nas a2200193 4500008004100000245014800041210006900189300000900258490000700267653000700274653000700281100001900288700002000307700002200327700001900349700001500368700001400383856012300397 2018 eng d00aMonitoring Candida parapsilosis and Staphylococcus epidermidis Biofilms by a Combination of Scanning Electron Microscopy and Raman Spectroscopy0 aMonitoring Candida parapsilosis and Staphylococcus epidermidis B a40890 v1810aBF10aMF1 aHrubanová, K.1 aKrzyžánek, V.1 aNebesářová, J.1 aRůžička, F.1 aPilát, Z.1 aSamek, O. uhttps://www.isibrno.cz/cs/monitoring-candida-parapsilosis-and-staphylococcus-epidermidis-biofilms-combination-scanning00613nas a2200169 4500008004100000245011300041210006900154300001100223490000600234653000700240653000700247100001600254700001600270700001700286700001400303856012600317 2018 eng d00aA new type of microphotoreactor with integrated optofluidic waveguide based on solid-air nanoporous aerogels0 anew type of microphotoreactor with integrated optofluidic wavegu a1808020 v510aBF10aMF1 aOzbakir, Y.1 aJonáš, A.1 aKiraz, Alper1 aErkey, C. uhttps://www.isibrno.cz/cs/new-type-microphotoreactor-integrated-optofluidic-waveguide-based-solid-air-nanoporous-aerogels00581nas a2200169 4500008004100000245008400041210006900125300001400194490000700208653000700215653000700222100002000229700001600249700002300265700001700288856010600305 2018 eng d00aOptofluidic Dye Lasers Based on Holey Fibers: Modeling and Performance Analysis0 aOptofluidic Dye Lasers Based on Holey Fibers Modeling and Perfor a4114-41220 v3610aBF10aMF1 aRashid, Zeeshan1 aJonáš, A.1 aBuczynski, Ryszard1 aKiraz, Alper uhttps://www.isibrno.cz/cs/optofluidic-dye-lasers-based-holey-fibers-modeling-and-performance-analysis00763nas a2200217 4500008004100000245013600041210006900177300001200246490000800258653000700266653000700273100002000280700001500300700001800315700001700333700001600350700001700366700001700383700002100400856012400421 2018 eng d00aReversible switching of wetting properties and erasable patterning of polymer surfaces using plasma oxidation and thermal treatment0 aReversible switching of wetting properties and erasable patterni a841-8520 v44110aBF10aMF1 aRashid, Zeeshan1 aAtay, Ipek1 aSoydan, Seren1 aYagci, Baris1 aJonáš, A.1 aYilgor, Emel1 aKiraz, Alper1 aYilgor, Iskender uhttps://www.isibrno.cz/cs/reversible-switching-wetting-properties-and-erasable-patterning-polymer-surfaces-using-plasma00671nas a2200193 4500008004100000245010500041210006900146300001500215490000800230653000700238653000700245100001800252700001600270700001600286700001800302700001200320700002300332856012200355 2018 eng d00aRobustness of Light-Transport Processes to Bending Deformations in Graded-Index Multimode Waveguides0 aRobustness of LightTransport Processes to Bending Deformations i a233901:1-50 v12010aKF10aMF1 aFlaes, D.E.B.1 aStopka, Jan1 aTurtaev, S.1 ade Boer, J.F.1 aTyc, T.1 aČižmár, Tomáš uhttps://www.isibrno.cz/cs/robustness-light-transport-processes-bending-deformations-graded-index-multimode-waveguides00662nas a2200181 4500008004100000245011800041210006900159300001200228490000800240653000700248653000700255100002400262700001600286700001700302700001700319700001500336856012900351 2018 eng d00aSensitivity of compositional measurement of high-pressure fluid mixtures using microcantilever frequency response0 aSensitivity of compositional measurement of highpressure fluid m a111-1260 v27810aBF10aMF1 aBaloch, Shadi, Khan1 aJonáš, A.1 aKiraz, Alper1 aAlaca, Erdem1 aErkey, Can uhttps://www.isibrno.cz/cs/sensitivity-compositional-measurement-high-pressure-fluid-mixtures-using-microcantilever-frequency00748nas a2200217 4500008004100000245011800041210006900159300000800228490000600236653000700242653000700249100002400256700001700280700001400297700001800311700001700329700001400346700002300360700001800383856012900401 2018 eng d00aSubcellular spatial resolution achieved for deep-brain imaging in vivo using a minimally invasive multimode fiber0 aSubcellular spatial resolution achieved for deepbrain imaging in a1100 v710aKF10aMF1 aVasquez-Lopez, S.A.1 aTurcotte, R.1 aKoren, V.1 aPloschner, M.1 aPadamsey, Z.1 aBooth, M.1 aČižmár, Tomáš1 aEmptage, N.J. uhttps://www.isibrno.cz/cs/subcellular-spatial-resolution-achieved-deep-brain-imaging-vivo-using-minimally-invasive-multimode00723nas a2200205 4500008004100000245011600041210006900157300001200226490000700238653000700245653000700252100001600259700001600275700001500291700001400306700002200320700002800342700002300370856012400393 2018 eng d00aThree-dimensional holographic optical manipulation through a high-numerical-aperture soft-glass multimode fibre0 aThreedimensional holographic optical manipulation through a high a33–390 v1210aKF10aMF1 aLeite, I.T.1 aTurtaev, S.1 aJiang, Xin1 aŠiler, M1 aCuschieri, Alfred1 aRussell, Philip, St. J.1 aČižmár, Tomáš uhttps://www.isibrno.cz/cs/three-dimensional-holographic-optical-manipulation-through-high-numerical-aperture-soft-glass00701nas a2200205 4500008004100000245011100041210006900152300000900221490000600230653000700236653000700243100001800250700002100268700001400289700001300303700001500316700001700331700002000348856012700368 2018 eng d00aTransverse spin forces and non-equilibrium particle dynamics in a circularly polarized vacuum optical trap0 aTransverse spin forces and nonequilibrium particle dynamics in a a54530 v910aLF10aMF1 aSvak, Vojtech1 aBrzobohatý, Oto1 aŠiler, M1 aJákl, P1 aKaňka, J.1 aZemánek, P.1 aSimpson, S., H. uhttps://www.isibrno.cz/cs/transverse-spin-forces-and-non-equilibrium-particle-dynamics-circularly-polarized-vacuum-optical00773nas a2200229 4500008004100000245009100041210006900132300001600201490000700217653000700224653000700231100002200238700002100260700002200281700002200303700002200325700002400347700001900371700001700390700002500407856011100432 2017 eng d00aAccuracy and Mechanistic Details of Optical Printing of Single Au and Ag Nanoparticles0 aAccuracy and Mechanistic Details of Optical Printing of Single A a9678–96880 v1110aLF10aMF1 aGargiulo, Juliàn1 aVioli, Ianina, L1 aCerrota, Santiago1 aChvátal, Lukáš1 aCortès, Emiliano1 aPerassi, Eduardo, M1 aDiaz, Fernando1 aZemánek, P.1 aStefani, Fernando, D uhttps://www.isibrno.cz/cs/accuracy-and-mechanistic-details-optical-printing-single-au-and-ag-nanoparticles00731nas a2200217 4500008004100000245011400041210006900155300000700224490000700231653000700238653000700245100002000252700001400272700001400286700001900300700002200319700001400341700001700355700001400372856012700386 2017 eng d00aDifferentiation between Staphylococcus aureus and Staphylococcus epidermidis strains using Raman spectroscopy0 aDifferentiation between Staphylococcus aureus and Staphylococcus a100 v1210aBF10aMF1 aRebrošová, K.1 aŠiler, M1 aSamek, O.1 aRůžička, F.1 aBernatová, Silva1 aJežek, J1 aZemánek, P.1 aHolá, V. uhttps://www.isibrno.cz/cs/differentiation-between-staphylococcus-aureus-and-staphylococcus-epidermidis-strains-using-raman00593nas a2200181 4500008004100000022001400041245008000055210006900135300001400204490000700218653000700225653000700232100002600239700001400265700002100279700001700300856009400317 2017 eng d a0146-959200aDynamics of an optically bound structure made of particles of unequal sizes0 aDynamics of an optically bound structure made of particles of un a1436-14390 v4210aLF10aMF1 aKarásek, Vítězslav1 aŠiler, M1 aBrzobohatý, Oto1 aZemánek, P. uhttps://www.isibrno.cz/cs/dynamics-optically-bound-structure-made-particles-unequal-sizes00575nas a2200169 4500008004100000245009400041210006900135300000900204490000700213653000700220653000700227100001500234700001600249700001400265700001700279856010900296 2017 eng d00aEffects of Infrared Optical Trapping on Saccharomyces cerevisiae in a Microfluidic System0 aEffects of Infrared Optical Trapping on Saccharomyces cerevisiae a26400 v1710aBF10aMF1 aPilát, Z.1 aJonáš, A.1 aJežek, J1 aZemánek, P. uhttps://www.isibrno.cz/cs/effects-infrared-optical-trapping-saccharomyces-cerevisiae-microfluidic-system00728nas a2200217 4500008004100000245011600041210006900157300000700226490000700233653000700240653000700247100001900254700002000273700001400293700001600307700001400323700001400337700001600351700001700367856012600384 2017 eng d00aMorphological and Production Changes in Planktonic and Biofilm Cells Monitored Using SEM and Raman Spectroscopy0 aMorphological and Production Changes in Planktonic and Biofilm C aS10 v2310aBF10aMF1 aHrubanová, K.1 aKrzyžánek, V.1 aSamek, O.1 aSkoupý, R.1 aŠiler, M1 aJežek, J1 aObruča, S.1 aZemánek, P. uhttps://www.isibrno.cz/cs/morphological-and-production-changes-planktonic-and-biofilm-cells-monitored-using-sem-and-raman00637nas a2200181 4500008004100000245008700041210006900128300001100197490000800208653000700216653000700223100002600230700003100256700002800287700001300315700001700328856011000345 2017 eng d00aOmnidirectional Transport in Fully Reconfigurable Two Dimensional Optical Ratchets0 aOmnidirectional Transport in Fully Reconfigurable Two Dimensiona a1380020 v11810aLF10aMF1 aArzola, Alejandro, V.1 aVillasante-Barahona, Mario1 aVolke-Sepúlveda, Karen1 aJákl, P1 aZemánek, P. uhttps://www.isibrno.cz/cs/omnidirectional-transport-fully-reconfigurable-two-dimensional-optical-ratchets00481nas a2200181 4500008004100000245003300041210003300074300001400107490000700121653000700128653000700135100002000142700001700162700002500179700002200204700001700226856005600243 2017 eng d00aOptical Binding of Nanowires0 aOptical Binding of Nanowires a3485-34920 v1710aLF10aMF1 aSimpson, S., H.1 aZemánek, P.1 aMaragò, Onofrio, M.1 aJones, Philip, H.1 aHanna, Simon uhttps://www.isibrno.cz/cs/optical-binding-nanowires00855nas a2200253 4500008004100000245014000041210006900181300000700250490000700257653000700264653000700271100001600278700001900294700001500313700002000328700002200348700001400370700001600384700002200400700001900422700001800441700001700459856012500476 2017 eng d00aThe presence of PHB granules in cytoplasm protects non-halophilic bacterial cells against the harmful impact of hypertonic environments0 apresence of PHB granules in cytoplasm protects nonhalophilic bac a100 v3910aBF10aMF1 aObruča, S.1 aSedláček, P.1 aMravec, F.1 aKrzyžánek, V.1 aNebesářová, J.1 aSamek, O.1 aKučera, D.1 aBenešová, Pavla1 aHrubanová, K.1 aMilerová, M.1 aMárová, I. uhttps://www.isibrno.cz/cs/presence-phb-granules-cytoplasm-protects-non-halophilic-bacterial-cells-against-harmful-impact00691nas a2200241 4500008004100000245006400041210006400105300001000169490000600179653000700185653000700192100002000199700001400219700001400233700001900247700001900266700001400285700001400299700001700313700001800330700001700348856008400365 2017 eng d00aRapid identification of staphylococci by Raman spectroscopy0 aRapid identification of staphylococci by Raman spectroscopy a148460 v710aBF10aMF1 aRebrošová, K.1 aŠiler, M1 aSamek, O.1 aRůžička, F.1 aBernatová, S.1 aHolá, V.1 aJežek, J1 aZemánek, P.1 aSokolová, J.1 aPetráš, P. uhttps://www.isibrno.cz/cs/rapid-identification-staphylococci-raman-spectroscopy00705nas a2200217 4500008004100000245009700041210006900138300001400207490000700221653000700228653000700235100001600242700001500258700001400273700002200287700001400309700001700323700001500340700001700355856011500372 2017 eng d00aThermal tuning of spectral emission from optically trapped liquid-crystal droplet resonators0 aThermal tuning of spectral emission from optically trapped liqui a1855-18640 v3410aBF10aMF1 aJonáš, A.1 aPilát, Z.1 aJežek, J1 aBernatová, Silva1 aFořt, T.1 aZemánek, P.1 aAas, Mehdi1 aKiraz, Alper uhttps://www.isibrno.cz/cs/thermal-tuning-spectral-emission-optically-trapped-liquid-crystal-droplet-resonators00619nas a2200205 4500008004100000022001400041245007000055210006900125300000900194490000600203653000700209653000700216100001400223700001300237700002100250700001800271700001700289700001700306856009000323 2017 eng d a2045-232200aThermally induced micro-motion by inflection in optical potential0 aThermally induced micromotion by inflection in optical potential a16970 v710aLF10aMF1 aŠiler, M1 aJákl, P1 aBrzobohatý, Oto1 aRyabov, Artem1 aFilip, Radim1 aZemánek, P. uhttps://www.isibrno.cz/cs/thermally-induced-micro-motion-inflection-optical-potential00727nas a2200217 4500008004100000245010000041210006900141300000700210490000800217653000700225100001500232700001600247700002000263700001900283700001900302700001400321700001600335700002200351700002200373856011400395 2016 eng d00aAccumulation of PHA granules in Cupriavidus necator as seen by confocal fluorescence microscopy0 aAccumulation of PHA granules in Cupriavidus necator as seen by c a100 v36310aMF1 aMravec, F.1 aObruča, S.1 aKrzyžánek, V.1 aSedláček, P.1 aHrubanová, K.1 aSamek, O.1 aKučera, D.1 aBenešová, Pavla1 aNebesářová, J. uhttps://www.isibrno.cz/cs/accumulation-pha-granules-cupriavidus-necator-seen-confocal-fluorescence-microscopy00703nas a2200217 4500008004100000245008600041210006900127300001300196490000700209653000700216100001600223700001900239700002000258700001500278700001900293700001400312700001600326700002200342700001700364856010400381 2016 eng d00aAccumulation of Poly(3-hydroxybutyrate) Helps Bacterial Cells to Survive Freezing0 aAccumulation of Poly3hydroxybutyrate Helps Bacterial Cells to Su ae01577780 v1110aMF1 aObruča, S.1 aSedláček, P.1 aKrzyžánek, V.1 aMravec, F.1 aHrubanová, K.1 aSamek, O.1 aKučera, D.1 aBenešová, Pavla1 aMárová, I. uhttps://www.isibrno.cz/cs/accumulation-poly3-hydroxybutyrate-helps-bacterial-cells-survive-freezing00557nas a2200181 4500008004100000245005100041210005000092300001600142490000700158653000700165100002100172700002700193700002000220700002200240700002600262700001700288856007000305 2016 eng d00aChiral particles in the dual-beam optical trap0 aChiral particles in the dualbeam optical trap a26382-263910 v2410aMF1 aBrzobohatý, Oto1 aHernandez, Raul, Josue1 aSimpson, S., H.1 aMazzulla, Alfredo1 aCipparrone, Gabriella1 aZemánek, P. uhttps://www.isibrno.cz/cs/chiral-particles-dual-beam-optical-trap00590nas a2200169 4500008004100000245009900041210006900140300001200209490000700221653000700228100001400235700001400249700001300263700001500276700001700291856011200308 2016 eng d00aDirect measurement of the temperature profile close to an optically trapped absorbing particle0 aDirect measurement of the temperature profile close to an optica a870-8730 v4110aMF1 aŠiler, M1 aJežek, J1 aJákl, P1 aPilát, Z.1 aZemánek, P. uhttps://www.isibrno.cz/cs/direct-measurement-temperature-profile-close-optically-trapped-absorbing-particle00830nas a2200241 4500008004100000245012200041210006900163300001200232490000700244653000700251100001900258700002300277700002100300700002000321700001500341700001600356700001600372700001900388700002100407700001900428700001300447856012800460 2016 eng d00aDirect measurements of the extraordinary optical momentum and transverse spin-dependent force using a nano-cantilever0 aDirect measurements of the extraordinary optical momentum and tr a731-7350 v1210aMF1 aAntognozzi, M.1 aBermingham, C., R.1 aHarniman, R., L.1 aSimpson, S., H.1 aSenior, J.1 aHayward, R.1 aHoerber, H.1 aDennis, M., R.1 aBekshaev, A., Y.1 aBliokh, K., Y.1 aNori, F. uhttps://www.isibrno.cz/cs/direct-measurements-extraordinary-optical-momentum-and-transverse-spin-dependent-force-using-nano00709nas a2200169 4500008004100000245019100041210006900232300001400301490000800315653000700323100001600330700001900346700001500365700001400380700001700394856012800411 2016 eng d00aEvaluation of 3-hydroxybutyrate as an enzyme-protective agent against heating and oxidative damage and its potential role in stress response of poly(3-hydroxybutyrate) accumulating cells0 aEvaluation of 3hydroxybutyrate as an enzymeprotective agent agai a1365-13760 v10010aMF1 aObruča, S.1 aSedláček, P.1 aMravec, F.1 aSamek, O.1 aMárová, I. uhttps://www.isibrno.cz/cs/evaluation-3-hydroxybutyrate-enzyme-protective-agent-against-heating-and-oxidative-damage-and-its00716nas a2200229 4500008004100000245007900041210006900120300001500189490000700204653000700211100001500218700001400233700001900247700001500266700001300281700001500294700002200309700001900331700001700350700001700367856010200384 2016 eng d00aHolographic Raman tweezers controlled by Multimodal Natural User Interface0 aHolographic Raman tweezers controlled by Multimodal Natural User a015602:1-90 v1810aMF1 aTomori, Z.1 aKeša, P.1 aNikorovič, M.1 aKaňka, J.1 aJákl, P1 aŠerý, M.1 aBernatová, Silva1 aValušová, E.1 aAntalík, M.1 aZemánek, P. uhttps://www.isibrno.cz/cs/holographic-raman-tweezers-controlled-multimodal-natural-user-interface00691nas a2200193 4500008004100000245010700041210006900148300000700217490000700224653000700231100001900238700001400257700002000271700002200291700001700313700001700330700002000347856013000367 2016 eng d00aMorphological and Production Changes in Stressed Red Yeasts Monitored Using SEM and Raman Spectroscopy0 aMorphological and Production Changes in Stressed Red Yeasts Moni aS30 v2210aMF1 aHrubanová, K.1 aSamek, O.1 aHaroniková, A.1 aBernatová, Silva1 aZemánek, P.1 aMárová, I.1 aKrzyžánek, V. uhttps://www.isibrno.cz/cs/morphological-and-production-changes-stressed-red-yeasts-monitored-using-sem-and-raman-spectroscopy00504nas a2200133 4500008004100000245009600041210006900137300001100206490000700217653000700224100001700231700001700248856010500265 2016 eng d00aNoise-to-signal transition of a Brownian particle in the cubic potential: I. general theory0 aNoisetosignal transition of a Brownian particle in the cubic pot a0654010 v1810aMF1 aFilip, Radim1 aZemánek, P. uhttps://www.isibrno.cz/cs/noise-signal-transition-brownian-particle-cubic-potential-i-general-theory00612nas a2200169 4500008004100000245010800041210006900149300001100218490000700229653000700236100001700243700001400260700002100274700001300295700001700308856011700325 2016 eng d00aNoise-to-signal transition of a Brownian particle in the cubic potential: II. optical trapping geometry0 aNoisetosignal transition of a Brownian particle in the cubic pot a0654020 v1810aMF1 aZemánek, P.1 aŠiler, M1 aBrzobohatý, Oto1 aJákl, P1 aFilip, Radim uhttps://www.isibrno.cz/cs/noise-signal-transition-brownian-particle-cubic-potential-ii-optical-trapping-geometry00784nas a2200217 4500008004100000245010600041210006900147300001400216490000700230653000700237100002000244700002400264700001900288700002000307700001700327700002200344700002200366700003200388700002500420856012100445 2016 eng d00aPhotonic Torque Microscopy of the Nonconservative Force Field for Optically Trapped Silicon Nanowires0 aPhotonic Torque Microscopy of the Nonconservative Force Field fo a4181-41880 v1610aMF1 aIrrera, Alessia1 aMagazzu, Alessandro1 aArtoni, Pietro1 aSimpson, S., H.1 aHanna, Simon1 aJones, Philip, H.1 aPriolo, Francesco1 aGucciardi, Pietro, Giuseppe1 aMaragò, Onofrio, M. uhttps://www.isibrno.cz/cs/photonic-torque-microscopy-nonconservative-force-field-optically-trapped-silicon-nanowires00584nas a2200169 4500008004100000245009000041210006900131300001200200490000600212653000700218100001600225700001600241700002000257700001500277700001700292856010500309 2016 eng d00aPrecise, contactless measurement of the surface tension of picolitre aerosol droplets0 aPrecise contactless measurement of the surface tension of picoli a274-2850 v710aMF1 aBzdek, B.R.1 aPower, R.M.1 aSimpson, S., H.1 aReid, J.P.1 aRoyall, C.P. uhttps://www.isibrno.cz/cs/precise-contactless-measurement-surface-tension-picolitre-aerosol-droplets00766nas a2200229 4500008004100000245010600041210006900147300000900216490000700225653000700232100001400239700001600253700001400269700001900283700002200302700001600324700001700340700001400357700002200371700001700393856012600410 2016 eng d00aQuantitative Raman Spectroscopy Analysis of Polyhydroxyalkanoates Produced by Cupriavidus necator H160 aQuantitative Raman Spectroscopy Analysis of Polyhydroxyalkanoate a18080 v1610aMF1 aSamek, O.1 aObruča, S.1 aŠiler, M1 aSedláček, P.1 aBenešová, Pavla1 aKučera, D.1 aMárová, I.1 aJežek, J1 aBernatová, Silva1 aZemánek, P. uhttps://www.isibrno.cz/cs/quantitative-raman-spectroscopy-analysis-polyhydroxyalkanoates-produced-cupriavidus-necator-h1600507nas a2200145 4500008004100000245007200041210006900113300001100182490000700193653000700200100002000207700002200227700001700249856009500266 2016 eng d00aSynchronization of colloidal rotors through angular optical binding0 aSynchronization of colloidal rotors through angular optical bind a0238420 v9310aMF1 aSimpson, S., H.1 aChvátal, Lukáš1 aZemánek, P. uhttps://www.isibrno.cz/cs/synchronization-colloidal-rotors-through-angular-optical-binding00537nas a2200145 4500008004100000245009200041210006900133300001100202490000700213653000700220100001800227700001700245700001700262856011200279 2016 eng d00aThermally-induced passage and current of particles in highly unstable optical potential0 aThermallyinduced passage and current of particles in highly unst a0421080 v1610aMF1 aRyabov, Artem1 aZemánek, P.1 aFilip, Radim uhttps://www.isibrno.cz/cs/thermally-induced-passage-and-current-particles-highly-unstable-optical-potential00549nas a2200157 4500008004100000245007700041210006900118300001800187490000700205653000700212100002100219700001800240700001400258700002100272856009800293 2015 eng d00aAberration resistant axial localization using a self-imaging of vortices0 aAberration resistant axial localization using a selfimaging of v a15316–153310 v2310aMF1 aBaránek, Michal1 aBouchal, Petr1 aŠiler, M1 aBouchal, Zdeněk uhttps://www.isibrno.cz/cs/aberration-resistant-axial-localization-using-self-imaging-vortices00505nas a2200145 4500008004100000245007500041210006900116300001200185490000700197653000700204100002200211700002100233700001700254856008800271 2015 eng d00aBinding of a pair of Au nanoparticles in a wide Gaussian standing wave0 aBinding of a pair of Au nanoparticles in a wide Gaussian standin a157-1610 v2210aMF1 aChvátal, Lukáš1 aBrzobohatý, Oto1 aZemánek, P. uhttps://www.isibrno.cz/cs/binding-pair-au-nanoparticles-wide-gaussian-standing-wave00696nas a2200193 4500008004100000245010700041210006900148300001400217490000700231653000700238100002100245700002600266700001400292700002200306700001300328700002000341700001700361856012400378 2015 eng d00aComplex rotational dynamics of multiple spheroidal particles in a circularly polarized, dual beam trap0 aComplex rotational dynamics of multiple spheroidal particles in a7273-72870 v2310aMF1 aBrzobohatý, Oto1 aArzola, Alejandro, V.1 aŠiler, M1 aChvátal, Lukáš1 aJákl, P1 aSimpson, S., H.1 aZemánek, P. uhttps://www.isibrno.cz/cs/complex-rotational-dynamics-multiple-spheroidal-particles-circularly-polarized-dual-beam-trap00725nas a2200205 4500008004100000245011700041210006900158300001200227490000700239653000700246100002000253700001900273700001400292700001600306700001700322700002200339700001400361700001700375856012700392 2015 eng d00aCryo-SEM and Raman Spectroscopy Study of the Involvement of Polyhydroxyalkanoates in Stress Response of Bacteria0 aCryoSEM and Raman Spectroscopy Study of the Involvement of Polyh a183-1840 v2110aMF1 aKrzyžánek, V.1 aHrubanová, K.1 aSamek, O.1 aObruča, S.1 aMárová, I.1 aBernatová, Silva1 aŠiler, M1 aZemánek, P. uhttps://www.isibrno.cz/cs/cryo-sem-and-raman-spectroscopy-study-involvement-polyhydroxyalkanoates-stress-response-bacteria00705nas a2200217 4500008004100000245008600041210006900127490000700196653000700203100001400210700002200224700001400246700001400260700001500274700002000289700001900309700001700328700001400345700001900359856010900378 2015 eng d00aIdentification of individual biofilm-forming bacterial cells using Raman tweezers0 aIdentification of individual biofilmforming bacterial cells usin0 v2010aMF1 aSamek, O.1 aBernatová, Silva1 aJežek, J1 aŠiler, M1 aŠerý, M.1 aKrzyžánek, V.1 aHrubanová, K.1 aZemánek, P.1 aHolá, V.1 aRůžička, F. uhttps://www.isibrno.cz/cs/identification-individual-biofilm-forming-bacterial-cells-using-raman-tweezers00697nas a2200217 4500008004100000245008200041210006900123300001600192490000700208653000700215100002100222700001400243700002200257700001900279700001400298700002000312700001400332700001700346700001400363856010200377 2015 eng d00aInfluence of Culture Media on Microbial Fingerprints Using Raman Spectroscopy0 aInfluence of Culture Media on Microbial Fingerprints Using Raman a29635-296470 v1510aMF1 aMlynariková, K.1 aSamek, O.1 aBernatová, Silva1 aRůžička, F.1 aJežek, J1 aHaroniková, A.1 aŠiler, M1 aZemánek, P.1 aHolá, V. uhttps://www.isibrno.cz/cs/influence-culture-media-microbial-fingerprints-using-raman-spectroscopy00722nas a2200205 4500008004100000245010800041210006900149300001200218490000700230653000700237100001900244700002200263700001400285700001500299700001700314700002200331700001900353700002000372856012400392 2015 eng d00aMonitoring of Multilayered Bacterial Biofilm Morphology by Cryo-SEM for Raman Spectroscopy Measurements0 aMonitoring of Multilayered Bacterial Biofilm Morphology by CryoS a187-1880 v2110aMF1 aHrubanová, K.1 aBernatová, Silva1 aSamek, O.1 aŠerý, M.1 aZemánek, P.1 aNebesářová, J.1 aRůžička, F.1 aKrzyžánek, V. uhttps://www.isibrno.cz/cs/monitoring-multilayered-bacterial-biofilm-morphology-cryo-sem-raman-spectroscopy-measurements00617nas a2200181 4500008004100000245008000041210006900121300001400190490000700204653000700211100002100218700001400239700001500253700002200268700002600290700001700316856010200333 2015 eng d00aNon-spherical gold nanoparticles trapped in optical tweezers: shape matters0 aNonspherical gold nanoparticles trapped in optical tweezers shap a8179-81890 v2310aMF1 aBrzobohatý, Oto1 aŠiler, M1 aTrojek, J.1 aChvátal, Lukáš1 aKarásek, Vítězslav1 aZemánek, P. uhttps://www.isibrno.cz/cs/non-spherical-gold-nanoparticles-trapped-optical-tweezers-shape-matters00444nas a2200133 4500008004100000245006300041210006300104300001400167490000800181653000700189100001400196700001700210856008300227 2015 eng d00aOptical trapping in secondary maxima of focused laser beam0 aOptical trapping in secondary maxima of focused laser beam a114 - 1210 v16210aMF1 aŠiler, M1 aZemánek, P. uhttps://www.isibrno.cz/cs/optical-trapping-secondary-maxima-focused-laser-beam00734nas a2200205 4500008004100000245011800041210006900159300001400228490000700242653000700249100001400256700002000270700002200290700001900312700001400331700001700345700002000362700001700382856012900399 2015 eng d00aSEM and Raman Spectroscopy Applied to Biomass Analysis for Application in the Field of Biofuels and Food Industry0 aSEM and Raman Spectroscopy Applied to Biomass Analysis for Appli a1775-17760 v2110aMF1 aSamek, O.1 aHaroniková, A.1 aVaškovicová, N.1 aHrubanová, K.1 aJežek, J1 aMárová, I.1 aKrzyžánek, V.1 aZemánek, P. uhttps://www.isibrno.cz/cs/sem-and-raman-spectroscopy-applied-biomass-analysis-application-field-biofuels-and-food-industry-000799nas a2200229 4500008004100000245011800041210006900159300001200228490000700240653000700247100001900254700001800273700001500291700002200306700002000328700001400348700002200362700002000384700001800404700002000422856012700442 2015 eng d00aSEM and Raman Spectroscopy Applied to Biomass Analysis for Application in the Field of Biofuels and Food Industry0 aSEM and Raman Spectroscopy Applied to Biomass Analysis for Appli a687-7000 v9510aMF1 aBurdiková, Z.1 aSvindrych, Z.1 aHickey, C.1 aWilkinson, M., G.1 aAuty, M., A. E.1 aSamek, O.1 aBernatová, Silva1 aKrzyžánek, V.1 aPeriasamy, A.1 aSheehan, J., J. uhttps://www.isibrno.cz/cs/sem-and-raman-spectroscopy-applied-biomass-analysis-application-field-biofuels-and-food-industry00758nas a2200217 4500008004100000245011300041210006900154300000900223490000600232653000700238100002100245700001400266700001500280700002200295700002600317700001800343700002100361700001600382700001700398856012500415 2015 eng d00aThree-Dimensional Optical Trapping of a Plasmonic Nanoparticle using Low Numerical Aperture Optical Tweezers0 aThreeDimensional Optical Trapping of a Plasmonic Nanoparticle us a81060 v510aMF1 aBrzobohatý, Oto1 aŠiler, M1 aTrojek, J.1 aChvátal, Lukáš1 aKarásek, Vítězslav1 aPaták, Aleš1 aPokorná, Zuzana1 aMika, Filip1 aZemánek, P. uhttps://www.isibrno.cz/cs/three-dimensional-optical-trapping-plasmonic-nanoparticle-using-low-numerical-aperture-optical00513nas a2200157 4500008004100000245006600041210006600107300001100173490000700184653000700191100001200198700001500210700002100225700002000246856008900266 2015 eng d00aTransitional behavior in hydrodynamically coupled oscillators0 aTransitional behavior in hydrodynamically coupled oscillators a0229160 v9110aMF1 aBox, S.1 aDebono, L.1 aPhillips, D., B.1 aSimpson, S., H. uhttps://www.isibrno.cz/cs/transitional-behavior-hydrodynamically-coupled-oscillators00820nas a2200277 4500008004100000245007500041210007100116300001600187490000700203653000700210100001800217700002200235700001900257700001900276700001700295700001700312700001400329700001400343700001500357700001700372700001300389700001400402700001700416700001500433856009400448 2014 eng d00aAlgal Biomass Analysis by Laser-Based Analytical Techniques—A Review0 aAlgal Biomass Analysis by LaserBased Analytical Techniques—A Rev a17725-177520 v1410aMF1 aPořízka, P.1 aProcházková, P.1 aProcházka, D.1 aSládková, L.1 aNovotný, J.1 aPetrilak, M.1 aBrada, M.1 aSamek, O.1 aPilát, Z.1 aZemánek, P.1 aAdam, V.1 aKizek, R.1 aNovotný, J.1 aKaiser, J. uhttps://www.isibrno.cz/cs/algal-biomass-analysis-laser-based-analytical-techniques-review00706nas a2200229 4500008004100000245007000041210006900111300001600180490000700196653000700203100001400210700002100224700002200245700001400267700002000281700001400301700001700315700001900332700001400351700001800365856009300383 2014 eng d00aCandida parapsilosis Biofilm Identification by Raman Spectroscopy0 aCandida parapsilosis Biofilm Identification by Raman Spectroscop a23924-239350 v1510aMF1 aSamek, O.1 aMlynariková, K.1 aBernatová, Silva1 aJežek, J1 aKrzyžánek, V.1 aŠiler, M1 aZemánek, P.1 aRůžička, F.1 aHolá, V.1 aMahelová, M. uhttps://www.isibrno.cz/cs/candida-parapsilosis-biofilm-identification-raman-spectroscopy00650nas a2200181 4500008004100000245009400041210006900135300001600204490000700220653000700227100001300234700002600247700001400273700002200287700002800309700001700337856011400354 2014 eng d00aOptical sorting of nonspherical and living microobjects in moving interference structures0 aOptical sorting of nonspherical and living microobjects in movin a29746-297600 v2210aMF1 aJákl, P1 aArzola, Alejandro, V.1 aŠiler, M1 aChvátal, Lukáš1 aVolke-Sepúlveda, Karen1 aZemánek, P. uhttps://www.isibrno.cz/cs/optical-sorting-nonspherical-and-living-microobjects-moving-interference-structures00609nas a2200157 4500008004100000245011300041210006900154300001600223490000700239653000700246100002600253700001300279700002200292700001700314856012000331 2014 eng d00aRotation, oscillation and hydrodynamic synchronization of optically trapped oblate spheroidal microparticles0 aRotation oscillation and hydrodynamic synchronization of optical a16207-162210 v2210aMF1 aArzola, Alejandro, V.1 aJákl, P1 aChvátal, Lukáš1 aZemánek, P. uhttps://www.isibrno.cz/cs/rotation-oscillation-and-hydrodynamic-synchronization-optically-trapped-oblate-spheroidal00531nas a2200145 4500008004100000245007600041210006900117300001500186490000700201653000700208100002600215700002800241700002100269856009500290 2013 eng d00aDynamical analysis of an optical rocking ratchet: Theory and experiment0 aDynamical analysis of an optical rocking ratchet Theory and expe a062910:1-90 v8710aMF1 aArzola, Alejandro, V.1 aVolke-Sepúlveda, Karen1 aMateos, Jose, L. uhttps://www.isibrno.cz/cs/dynamical-analysis-optical-rocking-ratchet-theory-and-experiment00668nas a2200181 4500008004100000245010500041210006900146300001200215490000600227653000700233100002100240700002600261700001400287700002200301700002300323700001700346856012300363 2013 eng d00aExperimental demonstration of optical transport, sorting and self-arrangement using a `tractor beam'0 aExperimental demonstration of optical transport sorting and self a123-1270 v710aMF1 aBrzobohatý, Oto1 aKarásek, Vítězslav1 aŠiler, M1 aChvátal, Lukáš1 aČižmár, Tomáš1 aZemánek, P. uhttps://www.isibrno.cz/cs/experimental-demonstration-optical-transport-sorting-and-self-arrangement-using-tractor-beam00809nas a2200253 4500008004100000245009800041210006900139300001600208490000700224653000700231100002200238700001400260700001500274700001500289700001400304700001300318700001400331700002000345700001700365700001400382700002300396700001900419856011700438 2013 eng d00aFollowing the mechanisms of bacteriostatic versus bacericidal action using Raman spectroscopy0 aFollowing the mechanisms of bacteriostatic versus bacericidal ac a13188-131990 v1810aMF1 aBernatová, Silva1 aSamek, O.1 aPilát, Z.1 aŠerý, M.1 aJežek, J1 aJákl, P1 aŠiler, M1 aKrzyžánek, V.1 aZemánek, P.1 aHolá, V.1 aDvořáčková, M.1 aRůžička, F. uhttps://www.isibrno.cz/cs/following-mechanisms-bacteriostatic-versus-bacericidal-action-using-raman-spectroscopy00648nas a2200205 4500008004100000245007800041210006900119300001200188490000600200653000700206100001500213700001700228700001400245700001500259700001300274700001500287700002200302700001700324856010100341 2013 eng d00aHolographic Raman tweezers controlled by hand gestures and voice commands0 aHolographic Raman tweezers controlled by hand gestures and voice a331-3360 v310aMF1 aTomori, Z.1 aAntalík, M.1 aKeša, P.1 aKaňka, J.1 aJákl, P1 aŠerý, M.1 aBernatová, Silva1 aZemánek, P. uhttps://www.isibrno.cz/cs/holographic-raman-tweezers-controlled-hand-gestures-and-voice-commands00500nas a2200145 4500008004100000245007300041210006900114300001000183490000800193653000700201100001400208700002200222700001700244856009300261 2013 eng d00aMetallic nanoparticles in a standing wave: optical force and heating0 aMetallic nanoparticles in a standing wave optical force and heat a84-900 v12610aMF1 aŠiler, M1 aChvátal, Lukáš1 aZemánek, P. uhttps://www.isibrno.cz/cs/metallic-nanoparticles-standing-wave-optical-force-and-heating00407nas a2200133 4500008004100000245005200041210005100093300001000144490000800154653000700162100001400169700001700183856007300200 2013 eng d00aOptical forces in a non-diffracting vortex beam0 aOptical forces in a nondiffracting vortex beam a78-830 v12610aMF1 aŠiler, M1 aZemánek, P. uhttps://www.isibrno.cz/cs/optical-forces-non-diffracting-vortex-beam00590nas a2200169 4500008004100000245009100041210006900132300001400201490000700215653000700222100002100229700001400250700001400264700001300278700001700291856011200308 2013 eng d00aOptical manipulation of aerosol droplets using a holographic dual and single beam trap0 aOptical manipulation of aerosol droplets using a holographic dua a4601-46040 v3810aMF1 aBrzobohatý, Oto1 aŠiler, M1 aJežek, J1 aJákl, P1 aZemánek, P. uhttps://www.isibrno.cz/cs/optical-manipulation-aerosol-droplets-using-holographic-dual-and-single-beam-trap00583nas a2200181 4500008004100000245007600041210007100117300001200188490000800200653000700208100001500215700001400230700001500244700001700259700001500276700001700291856009300308 2013 eng d00aOptical trapping of microalgae at 735–1064 nm: Photodamage assessment0 aOptical trapping of microalgae at 735–1064 nm Photodamage assess a27 - 310 v12110aMF1 aPilát, Z.1 aJežek, J1 aŠerý, M.1 aTrtílek, M.1 aNedbal, L.1 aZemánek, P. uhttps://www.isibrno.cz/cs/optical-trapping-microalgae-735-1064-nm-photodamage-assessment00669nas a2200193 4500008004100000245010100041210006900142300001600211490000700227653000700234100001500241700001600256700001700272700002100289700001400310700001500324700001700339856011900356 2013 eng d00aSpectral tuning of lasing emission from optofluidic droplet microlasers using optical stretching0 aSpectral tuning of lasing emission from optofluidic droplet micr a21380-213940 v2110aMF1 aAas, Mehdi1 aJonáš, A.1 aKiraz, Alper1 aBrzobohatý, Oto1 aJežek, J1 aPilát, Z.1 aZemánek, P. uhttps://www.isibrno.cz/cs/spectral-tuning-lasing-emission-optofluidic-droplet-microlasers-using-optical-stretching00961nas a2200301 4500008004100000245011800041210006900159300001200228490001000240653000700250100001800257700001900275700001500294700002100309700001500330700001500345700001700360700001700377700001400394700001500408700002200423700002000445700001900465700001700484700001700501700001400518856012700532 2012 eng d00aApplication of laser-induced breakdown spectroscopy to the analysis of algal biomass for industrial biotechnology0 aApplication of laserinduced breakdown spectroscopy to the analys a169-1760 v74-7510aMF1 aPořízka, P.1 aProcházka, D.1 aPilát, Z.1 aKrajčarová, L.1 aKaiser, J.1 aMalina, R.1 aNovotný, J.1 aZemánek, P.1 aJežek, J1 aŠerý, M.1 aBernatová, Silva1 aKrzyžánek, V.1 aDobranská, K.1 aNovotný, K.1 aTrtílek, M.1 aSamek, O. uhttps://www.isibrno.cz/cs/application-laser-induced-breakdown-spectroscopy-analysis-algal-biomass-industrial-biotechnology00564nas a2200145 4500008004100000245010500041210006900146300001600215490000700231653000700238100001500245700002200260700001700282856011900299 2012 eng d00aOptical alignment and confinement of an ellipsoidal nanorod in optical tweezers: a theoretical study0 aOptical alignment and confinement of an ellipsoidal nanorod in o a1224–12360 v2910aMF1 aTrojek, J.1 aChvátal, Lukáš1 aZemánek, P. uhttps://www.isibrno.cz/cs/optical-alignment-and-confinement-ellipsoidal-nanorod-optical-tweezers-theoretical-study00545nas a2200157 4500008004100000245008300041210006900124300001600193490000700209653000700216100001400223700001300237700002100250700001700271856009900288 2012 eng d00aOptical forces induced behavior of a particle in a non-diffracting vortex beam0 aOptical forces induced behavior of a particle in a nondiffractin a24304-243190 v2010aMF1 aŠiler, M1 aJákl, P1 aBrzobohatý, Oto1 aZemánek, P. uhttps://www.isibrno.cz/cs/optical-forces-induced-behavior-particle-non-diffracting-vortex-beam00653nas a2200205 4500008004100000245008000041210006900121300001200190490000700202653000700209100001500216700002200231700001400253700001500267700001400282700001700296700001500313700001700328856010200345 2012 eng d00aRaman microspectroscopy of algal lipid bodies: beta-carotene quantification0 aRaman microspectroscopy of algal lipid bodies betacarotene quant a541-5460 v2410aMF1 aPilát, Z.1 aBernatová, Silva1 aJežek, J1 aŠerý, M.1 aSamek, O.1 aZemánek, P.1 aNedbal, L.1 aTrtílek, M. uhttps://www.isibrno.cz/cs/raman-microspectroscopy-algal-lipid-bodies-beta-carotene-quantification00504nas a2200145 4500008004100000245007500041210006900116300001100185490000800196653000700204100001400211700002300225700001700248856009300265 2012 eng d00aSpeed enhancement of multi-particle chain in a traveling standing wave0 aSpeed enhancement of multiparticle chain in a traveling standing a0511030 v10010aMF1 aŠiler, M1 aČižmár, Tomáš1 aZemánek, P. uhttps://www.isibrno.cz/cs/speed-enhancement-multi-particle-chain-traveling-standing-wave00531nas a2200157 4500008004100000245007400041210006900115300001400184490000600198653000700204100001400211700001700225700001600242700001800258856009700276 2011 eng d00aCharacterization of oil-producing microalgae using Raman spectroscopy0 aCharacterization of oilproducing microalgae using Raman spectros a701–7090 v810aMF1 aSamek, O.1 aZemánek, P.1 aJonáš, A.1 aTelle, H., H. uhttps://www.isibrno.cz/cs/characterization-oil-producing-microalgae-using-raman-spectroscopy00535nas a2200157 4500008004100000245006700041210006700108300001100175490000700186653000700193100002100200700002600221700002300247700001700270856009000287 2011 eng d00aDynamic size tuning of multidimensional optically bound matter0 aDynamic size tuning of multidimensional optically bound matter a1011050 v9910aMF1 aBrzobohatý, Oto1 aKarásek, Vítězslav1 aČižmár, Tomáš1 aZemánek, P. uhttps://www.isibrno.cz/cs/dynamic-size-tuning-multidimensional-optically-bound-matter00572nas a2200157 4500008004100000245008900041210006900130300001200199490000600211653000700217100002300224700002100247700002100268700001700289856010800306 2011 eng d00aThe holographic optical micro-manipulation system based on counter-propagating beams0 aholographic optical micromanipulation system based on counterpro a50–560 v810aMF1 aČižmár, Tomáš1 aBrzobohatý, Oto1 aDholakia, Kishan1 aZemánek, P. uhttps://www.isibrno.cz/cs/holographic-optical-micro-manipulation-system-based-counter-propagating-beams00538nas a2200133 4500008004100000245010900041210006900150300001700219490000700236653000700243100001400250700001700264856012300281 2011 eng d00aParametric study of optical forces acting upon nanoparticles in a single, or a standing, evanescent wave0 aParametric study of optical forces acting upon nanoparticles in a044016:1–90 v1310aMF1 aŠiler, M1 aZemánek, P. uhttps://www.isibrno.cz/cs/parametric-study-optical-forces-acting-upon-nanoparticles-single-or-standing-evanescent-wave00601nas a2200169 4500008004100000245008900041210006900130300001800199490000700217653000700224100002100231700002600252700001400278700001500292700001700307856010700324 2011 eng d00aStatic and dynamic behavior of two optically bound microparticles in a standing wave0 aStatic and dynamic behavior of two optically bound microparticle a19613–196260 v1910aMF1 aBrzobohatý, Oto1 aKarásek, Vítězslav1 aŠiler, M1 aTrojek, J.1 aZemánek, P. uhttps://www.isibrno.cz/cs/static-and-dynamic-behavior-two-optically-bound-microparticles-standing-wave00676nas a2200205 4500008004100000245009100041210006900132300001600201490000700217653000700224100001600231700002000247700001400267700001700281700001400298700001600312700001400328700001700342856011100359 2010 eng d00aDiffusive Mixing of Polymers Investigated by Raman Microspectroscopy and Microrheology0 aDiffusive Mixing of Polymers Investigated by Raman Microspectros a14223-142300 v2610aMF1 aJonáš, A.1 aDe Luca, A., C.1 aPesce, G.1 aRusciano, G.1 aSasso, A.1 aCaserta, S.1 aGuido, S.1 aMarrucci, G. uhttps://www.isibrno.cz/cs/diffusive-mixing-polymers-investigated-raman-microspectroscopy-and-microrheology00641nas a2200193 4500008004100000022001400041245007300055210006900128300001800197490000700215653000700222100002100229700002300250700002600273700001400299700002100313700001700334856009600351 2010 eng d a1094-408700aExperimental and theoretical determination of optical binding forces0 aExperimental and theoretical determination of optical binding fo a25389–254020 v1810aMF1 aBrzobohatý, Oto1 aČižmár, Tomáš1 aKarásek, Vítězslav1 aŠiler, M1 aDholakia, Kishan1 aZemánek, P. uhttps://www.isibrno.cz/cs/experimental-and-theoretical-determination-optical-binding-forces00378nas a2200133 4500008004100000245003800041210003700079300001600116490000700132653000700139100002100146700001700167856006000184 2010 eng d00aGripped by light: Optical binding0 aGripped by light Optical binding a1767–17910 v8210aMF1 aDholakia, Kishan1 aZemánek, P. uhttps://www.isibrno.cz/cs/gripped-light-optical-binding00484nas a2200133 4500008004100000245007800041210006900119300001800188490000700206653000700213100001400220700001700234856009900251 2010 eng d00aParticle jumps between optical traps in a one-dimensional optical lattice0 aParticle jumps between optical traps in a onedimensional optical a083001:1–200 v1210aMF1 aŠiler, M1 aZemánek, P. uhttps://www.isibrno.cz/cs/particle-jumps-between-optical-traps-one-dimensional-optical-lattice00574nas a2200145 4500008004100000245011400041210006900155300001400224490000600238653000700244100001400251700002600265700001800291856011900309 2010 eng d00aThe potential of Raman spectroscopy for the identification of biofilm formation by Staphylococcus epidermidis0 apotential of Raman spectroscopy for the identification of biofil a378–3830 v710aMF1 aSamek, O.1 aAl-Marashi, J., F. M.1 aTelle, H., H. uhttps://www.isibrno.cz/cs/potential-raman-spectroscopy-identification-biofilm-formation-staphylococcus-epidermidis00691nas a2200205 4500008004100000245010200041210006900143300001600212490000700228653000700235100001400242700001600256700001500272700001700287700001500304700001700319700001400336700001700350856011800367 2010 eng d00aRaman Microspectroscopy of Individual Algal Cells: Sensing Unsaturation of Storage Lipids in vivo0 aRaman Microspectroscopy of Individual Algal Cells Sensing Unsatu a8635–86510 v1010aMF1 aSamek, O.1 aJonáš, A.1 aPilát, Z.1 aZemánek, P.1 aNedbal, L.1 aTříska, J.1 aKotas, P.1 aTrtílek, M. uhttps://www.isibrno.cz/cs/raman-microspectroscopy-individual-algal-cells-sensing-unsaturation-storage-lipids-vivo00662nas a2200181 4500008004100000245009300041210006900134300001400203490000700217653000700224100002400231700001900255700002700274700001900301700001600320700002500336856011900361 2009 eng d00aDetecting Sequential Bond Formation Using Three-Dimensional Thermal Fluctuation Analysis0 aDetecting Sequential Bond Formation Using ThreeDimensional Therm a1541-15470 v1010aMF1 aBartsch, Tobias, F.1 aFisinger, Samo1 aKochanczyk, Martin, D.1 aHuang, Rongxin1 aJonáš, A.1 aFlorin, Ernst-Ludwig uhttps://www.isibrno.cz/cs/detecting-sequential-bond-formation-using-three-dimensional-thermal-fluctuation-analysis00595nas a2200169 4500008004100000245008800041210006900129300001100198490000800209653000700217100001400224700001900238700002300257700001600280700002500296856010400321 2009 eng d00aDirect Measurement of the Nonconservative Force Field Generated by Optical Tweezers0 aDirect Measurement of the Nonconservative Force Field Generated a1081010 v10310aMF1 aWu, Pinyu1 aHuang, Rongxin1 aTischer, Christian1 aJonáš, A.1 aFlorin, Ernst-Ludwig uhttps://www.isibrno.cz/cs/direct-measurement-nonconservative-force-field-generated-optical-tweezers00556nas a2200157 4500008004100000245008600041210006900127260000800196300001800204490000700222653000700229100001500236700002600251700001700277856010400294 2009 eng d00aExtreme axial optical force in a standing wave achieved by optimized object shape0 aExtreme axial optical force in a standing wave achieved by optim bOSA a10472–104880 v1710aMF1 aTrojek, J.1 aKarásek, Vítězslav1 aZemánek, P. uhttps://www.isibrno.cz/cs/extreme-axial-optical-force-standing-wave-achieved-optimized-object-shape00563nas a2200145 4500008004100000245010100041210006900142300001100211490000700222653000700229100002600236700002100262700001700283856011700300 2009 eng d00aLongitudinal optical binding of several spherical particles studied by the coupled dipole method0 aLongitudinal optical binding of several spherical particles stud a0340090 v1110aMF1 aKarásek, Vítězslav1 aBrzobohatý, Oto1 aZemánek, P. uhttps://www.isibrno.cz/cs/longitudinal-optical-binding-several-spherical-particles-studied-coupled-dipole-method00496nas a2200145 4500008004100000245006500041210006300106300001800169490000700187653000700194100002100201700002300222700001700245856008800262 2008 eng d00aHigh quality quasi-Bessel beam generated by round-tip axicon0 aHigh quality quasiBessel beam generated by roundtip axicon a12688–127000 v1610aMF1 aBrzobohatý, Oto1 aČižmár, Tomáš1 aZemánek, P. uhttps://www.isibrno.cz/cs/high-quality-quasi-bessel-beam-generated-round-tip-axicon00505nas a2200133 4500008004100000245009500041210006900136300001600205490000700221653000700228100001600235700001700251856010300268 2008 eng d00aLight at work: The use of optical forces for particle manipulation, sorting, and analysis.0 aLight at work The use of optical forces for particle manipulatio a4813–48510 v2910aMF1 aJonáš, A.1 aZemánek, P. uhttps://www.isibrno.cz/cs/light-work-use-optical-forces-particle-manipulation-sorting-and-analysis00611nas a2200193 4500008004100000022001400041245006000055210005800115300001100173490000800184653000700192100002600199700002300225700002100248700001700269700002400286700002100310856008600331 2008 eng d a0031-900700aLong-range one-dimensional longitudinal optical binding0 aLongrange onedimensional longitudinal optical binding a1436010 v10110aMF1 aKarásek, Vítězslav1 aČižmár, Tomáš1 aBrzobohatý, Oto1 aZemánek, P.1 aGarcés-Chávez, V.1 aDholakia, Kishan uhttps://www.isibrno.cz/cs/long-range-one-dimensional-longitudinal-optical-binding00516nas a2200169 4500008004100000022001400041245005700055210005700112300001700169490000700186653000700193100001300200700002300213700001500236700001700251856007800268 2008 eng d a0003-695100aStatic optical sorting in a laser interference field0 aStatic optical sorting in a laser interference field a161110:1–30 v9210aMF1 aJákl, P1 aČižmár, Tomáš1 aŠerý, M.1 aZemánek, P. uhttps://www.isibrno.cz/cs/static-optical-sorting-laser-interference-field00604nas a2200169 4500008004100000022001400041245009700055210006900152300001100221490000700232653000700239100001400246700002300260700001600283700001700299856011800316 2008 eng d a1367-263000aSurface delivery of a single nanoparticle under moving evanescent standing-wave illumination0 aSurface delivery of a single nanoparticle under moving evanescen a1130100 v1010aMF1 aŠiler, M1 aČižmár, Tomáš1 aJonáš, A.1 aZemánek, P. uhttps://www.isibrno.cz/cs/surface-delivery-single-nanoparticle-under-moving-evanescent-standing-wave-illumination00516nas a2200133 4500008004100000245009000041210006900131300001600200490000600216653000700222100002600229700001700255856011000272 2007 eng d00aAnalytical description of longitudinal optical binding of two spherical nanoparticles0 aAnalytical description of longitudinal optical binding of two sp aS215–S2200 v910aMF1 aKarásek, Vítězslav1 aZemánek, P. uhttps://www.isibrno.cz/cs/analytical-description-longitudinal-optical-binding-two-spherical-nanoparticles00566nas a2200181 4500008004100000022001400041245006800055210006700123300001600190490000600206653000700212100001300219700001500232700001400247700001500261700001700276856009100293 2007 eng d a1464-425800aAxial optical trap stiffness influenced by retro-reflected beam0 aAxial optical trap stiffness influenced by retroreflected beam aS251–S2550 v910aMF1 aJákl, P1 aŠerý, M.1 aJežek, J1 aLiška, M.1 aZemánek, P. uhttps://www.isibrno.cz/cs/axial-optical-trap-stiffness-influenced-retro-reflected-beam00513nas a2200157 4500008004100000245005900041210005900100300001400159490000700173653000700180100002100187700002200208700001700230700002300247856008500270 2007 eng d00aCellular and colloidal separation using optical forces0 aCellular and colloidal separation using optical forces a467–4950 v8210aMF1 aDholakia, Kishan1 aMacDonald, M., P.1 aZemánek, P.1 aČižmár, Tomáš uhttps://www.isibrno.cz/cs/cellular-and-colloidal-separation-using-optical-forces00495nas a2200133 4500008004100000245008900041210006900130300001400199490000800213653000700221100001400228700001700242856010200259 2007 eng d00aOptical forces acting on a nanoparticle placed into an interference evanescent field0 aOptical forces acting on a nanoparticle placed into an interfere a409–4200 v27510aMF1 aŠiler, M1 aZemánek, P. uhttps://www.isibrno.cz/cs/optical-forces-acting-nanoparticle-placed-interference-evanescent-field00514nas a2200133 4500008004100000245009000041210006900131300001600200490000700216653000700223100002300230700001700253856011000270 2007 eng d00aOptical tracking of spherical micro-objects in spatially periodic interference fields0 aOptical tracking of spherical microobjects in spatially periodic a2262–22720 v1510aMF1 aČižmár, Tomáš1 aZemánek, P. uhttps://www.isibrno.cz/cs/optical-tracking-spherical-micro-objects-spatially-periodic-interference-fields00620nas a2200193 4500008004100000245008100041210006900122300001400191490000600205653000700211100001300218700001500231700001400246700001700260700001400277700001500291700001600306856010400322 2007 eng d00aOpto-fluidic micromanipulation system based on integrated polymer waveguides0 aOptofluidic micromanipulation system based on integrated polymer a2148-21510 v910aMF1 aJákl, P1 aŠerý, M.1 aJežek, J1 aZemánek, P.1 aOrmos, P.1 aValkai, S.1 aKelemen, L. uhttps://www.isibrno.cz/cs/opto-fluidic-micromanipulation-system-based-integrated-polymer-waveguides00531nas a2200181 4500008004100000245005000041210005000091260000800141300001800149490000700167653000700174100001800181700002100199700001900220700002800239700001700267856006500284 2007 eng d00aTransverse particle dynamics in a Bessel beam0 aTransverse particle dynamics in a Bessel beam bOSA a13972–139870 v1510aMF1 aMilne, Graham1 aDholakia, Kishan1 aMcGloin, David1 aVolke-Sepúlveda, Karen1 aZemánek, P. uhttp://www.opticsexpress.org/abstract.cfm?URI=oe-15-21-1397200446nas a2200145 4500008004100000245004900041210004900090300001400139490000700153653000700160100002600167700002100193700001700214856006900231 2006 eng d00aAnalysis of optical binding in one dimension0 aAnalysis of optical binding in one dimension a149–1560 v8410aMF1 aKarásek, Vítězslav1 aDholakia, Kishan1 aZemánek, P. uhttps://www.isibrno.cz/cs/analysis-optical-binding-one-dimension00531nas a2200157 4500008004100000245007100041210006900112300001400181490000700195653000700202100001400209700002300223700001600246700001700262856009400279 2006 eng d00aFormation of long and thin polymer fiber using nondiffracting beam0 aFormation of long and thin polymer fiber using nondiffracting be a8506-85150 v1410aMF1 aJežek, J1 aČižmár, Tomáš1 aNeděla, V.1 aZemánek, P. uhttps://www.isibrno.cz/cs/formation-long-and-thin-polymer-fiber-using-nondiffracting-beam00598nas a2200157 4500008004100000245010700041210006900148300001400217490000700231653000700238100001400245700002300259700001500282700001700297856012600314 2006 eng d00aOptical forces generated by evanescent standing waves and their usage for sub-micron particle delivery0 aOptical forces generated by evanescent standing waves and their a157–1650 v8410aMF1 aŠiler, M1 aČižmár, Tomáš1 aŠerý, M.1 aZemánek, P. uhttps://www.isibrno.cz/cs/optical-forces-generated-evanescent-standing-waves-and-their-usage-sub-micron-particle-delivery00470nas a2200145 4500008004100000245006100041210005800102300001400160490000700174653000700181100002300188700001400211700001700225856008200242 2006 eng d00aAn optical nanotrap array movable over a milimetre range0 aoptical nanotrap array movable over a milimetre range a197–2030 v8410aMF1 aČižmár, Tomáš1 aŠiler, M1 aZemánek, P. uhttps://www.isibrno.cz/cs/optical-nanotrap-array-movable-over-milimetre-range00621nas a2200181 4500008004100000245008400041210006900125300001500194490000700209653000700216100002300223700001400246700001500260700001700275700002400292700002100316856010200337 2006 eng d00aOptical sorting and detection of sub-micron objects in a motional standing wave0 aOptical sorting and detection of submicron objects in a motional a035105:1-60 v7410aMF1 aČižmár, Tomáš1 aŠiler, M1 aŠerý, M.1 aZemánek, P.1 aGarcés-Chávez, V.1 aDholakia, Kishan uhttps://www.isibrno.cz/cs/optical-sorting-and-detection-sub-micron-objects-motional-standing-wave00545nas a2200157 4500008004100000245007800041210006900119300000700188490000600195653000700201100002300208700002000231700002100251700001700272856009800289 2006 eng d00aSub-micron particle organization by self-imaging of non-diffracting beams0 aSubmicron particle organization by selfimaging of nondiffracting a430 v810aMF1 aČižmár, Tomáš1 aKollárová, V.1 aBouchal, Zdeněk1 aZemánek, P. uhttps://www.isibrno.cz/cs/sub-micron-particle-organization-self-imaging-non-diffracting-beams00521nas a2200157 4500008004100000245006000041210006000101300002400161490000700185653000700192100002300199700002400222700002100246700001700267856007900284 2005 eng d00aOptical conveyor belt for delivery of submicron objects0 aOptical conveyor belt for delivery of submicron objects a174101-1–174101-30 v8610aMF1 aČižmár, Tomáš1 aGarcés-Chávez, V.1 aDholakia, Kishan1 aZemánek, P. uhttps://www.isibrno.cz/cs/optical-conveyor-belt-delivery-submicron-objects00482nas a2200157 4500008004100000245005600041210005400097300001400151490000800165653000700173100001700180700001400197700001700211700001400228856008200242 2005 eng d00aTwo-and three-beam interferometric optical tweezers0 aTwoand threebeam interferometric optical tweezers a393–4040 v25110aMF1 aCasaburi, A.1 aPesce, G.1 aZemánek, P.1 aSasso, A. uhttps://www.isibrno.cz/cs/two-and-three-beam-interferometric-optical-tweezers00514nas a2200145 4500008004100000245007800041210006900119300001200188490000800200653000700208100001700215700002600232700001400258856009600272 2004 eng d00aOptical forces acting on Rayleigh particle placed into interference field0 aOptical forces acting on Rayleigh particle placed into interfere a401-4150 v24010aMF1 aZemánek, P.1 aKarásek, Vítězslav1 aSasso, A. uhttps://www.isibrno.cz/cs/optical-forces-acting-rayleigh-particle-placed-interference-field00586nas a2200181 4500008004100000245007900041210006900120300001400189490000700203653000700210100001300217700001500230700001400245700001600259700001500275700001700290856009700307 2003 eng d00aBehaviour of an optically trapped probe approaching a dielectric interface0 aBehaviour of an optically trapped probe approaching a dielectric a1615-16250 v5010aMF1 aJákl, P1 aŠerý, M.1 aJežek, J1 aJonáš, A.1 aLiška, M.1 aZemánek, P. uhttps://www.isibrno.cz/cs/behaviour-optically-trapped-probe-approaching-dielectric-interface00599nas a2200181 4500008004100000245008500041210006900126300001200195490000800207653000700215100001700222700001600239700001300255700001500268700001400283700001500297856010500312 2003 eng d00aTheoretical comparison of optical traps created by standing wave and single beam0 aTheoretical comparison of optical traps created by standing wave a401-4120 v22010aMF1 aZemánek, P.1 aJonáš, A.1 aJákl, P1 aŠerý, M.1 aJežek, J1 aLiška, M. uhttps://www.isibrno.cz/cs/theoretical-comparison-optical-traps-created-standing-wave-and-single-beam00543nas a2200145 4500008004100000245010000041210006900141300001400210490000700224653000700231100001700238700001600255700001500271856011100286 2002 eng d00aSimplified description of optical forces acting on a nanoparticle in the Gaussian standing wave0 aSimplified description of optical forces acting on a nanoparticl a1025-10340 v1910aMF1 aZemánek, P.1 aJonáš, A.1 aLiška, M. uhttps://www.isibrno.cz/cs/simplified-description-optical-forces-acting-nanoparticle-gaussian-standing-wave00462nas a2200145 4500008004100000245005700041210005700098300001600155490000700171653000700178100001600185700001700201700002100218856007700239 2001 eng d00aSingle beam trapping in front of reflective surfaces0 aSingle beam trapping in front of reflective surfaces a1466–14680 v2610aMF1 aJonáš, A.1 aZemánek, P.1 aFlorin, E., - L. uhttps://www.isibrno.cz/cs/single-beam-trapping-front-reflective-surfaces00559nas a2200157 4500008004100000245008700041210006900128300001600197490000700213653000700220100001700227700001600244700001700260700001500277856010900292 1999 eng d00aOptical trapping of nanoparticles and microparticles using Gaussian standing wave.0 aOptical trapping of nanoparticles and microparticles using Gauss a1448–14500 v2410aMF1 aZemánek, P.1 aJonáš, A.1 aŠrámek, L.1 aLiška, M. uhttps://www.isibrno.cz/cs/optical-trapping-nanoparticles-and-microparticles-using-gaussian-standing-wave00484nas a2200133 4500008004100000245007800041210006900119300001400188490000800202653000700210100001700217700001700234856009900251 1998 eng d00aAtomic dipole trap formed by a blue detuned strong Gaussian standing wave0 aAtomic dipole trap formed by a blue detuned strong Gaussian stan a119–1230 v14610aMF1 aZemánek, P.1 aFoot, C., J. uhttps://www.isibrno.cz/cs/atomic-dipole-trap-formed-blue-detuned-strong-gaussian-standing-wave00531nas a2200157 4500008004100000245007400041210006900115300001400184490000800198653000700206100001700213700001600230700001700246700001500263856009500278 1998 eng d00aOptical trapping of Rayleigh particles using a Gaussian standing wave0 aOptical trapping of Rayleigh particles using a Gaussian standing a273–2850 v15110aMF1 aZemánek, P.1 aJonáš, A.1 aŠrámek, L.1 aLiška, M. uhttps://www.isibrno.cz/cs/optical-trapping-rayleigh-particles-using-gaussian-standing-wave