00926nas 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-blood00638nas 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/2304-6732/9/1/3701576nas 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 a
Aim: 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-2018-029700723nas 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-glass