Multiphoton scanning laser microscope based on femtosecond fiber laser

IF 0.5 Q4 OPTICS Photonics Letters of Poland Pub Date : 2022-12-31 DOI:10.4302/plp.v14i4.1182
Alicja Kwaśny, J. Bogusławski, G. Soboń
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引用次数: 1

Abstract

We present a multiphoton scanning laser microscope based on a femtosecond frequency-doubled erbium-doped fiber laser. The laser used in the epi-illumination microscope setup generated 95 fs pulses at the wavelength of 780 nm with 44.3 mW average power at 100 MHz pulse repetition rate. The imaging process was controlled by custom software developed in the NI LabVIEW environment. Detection of two-photon fluorescence was proven by acquiring a series of images from various biological samples. Full Text: PDF ReferencesJ.W. Lichtman, J.A. Conchello, "Fluorescence microscopy", Nature methods 2(12), 910 (2005). CrossRef W. Zipfel, R. Williams, W. Webb, "Nonlinear magic: multiphoton microscopy in the biosciences", Nat. Biotechnol. 21, 1369 (2003). CrossRef Coherent, Chameleon Ultra Datasheet (2019). DirectLink J. Boguslawski et al., "In vivo imaging of the human eye using a 2-photon-excited fluorescence scanning laser ophthalmoscope", J. Clin. Invest. 132(2), e154218 (2022). CrossRef M.J. Marzejon et al., "Two-photon microperimetry with picosecond pulses", Biomed. Opt. Expr. 12, 462 (2021). CrossRef A. Fast et al., "Institutional Drivers Influence on CSR Engagement: A Comparison of Developed & Developing Economies", Sci. Rep. 10, 18093 (2020). CrossRef D. Stachowiak et al., "Femtosecond Er-doped fiber laser source tunable from 872 to 1075 nm for two-photon vision studies in humans", Biomed. Opt. Expr. 13, 1899 (2022). CrossRef MenloSystems, T-light Femtosecond Fiber Laser 1560 nm (2013). DirectLink J. Yao, L.V. Wang, "Photoacoustic microscopy", Laser and Photonics Rev. 7, 758 (2013). CrossRef D. Stachowiak et al., "Frequency-doubled femtosecond Er-doped fiber laser for two-photon excited fluorescence imaging", Biomed. Opt. Expr. 11, 4431 (2020). CrossRef B.R. Masters et al., "Mitigating thermal mechanical damage potential during two-photon dermal imaging", J. Biomed. Opt. 9, 1265 (2004). CrossRef
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基于飞秒光纤激光器的多光子扫描激光显微镜
我们提出了一种基于飞秒倍频掺铒光纤激光器的多光子扫描激光显微镜。在落射照明显微镜设置中使用的激光器在780nm的波长下产生95fs脉冲,在100MHz脉冲重复率下具有44.3mW的平均功率。成像过程由在NI LabVIEW环境中开发的自定义软件控制。通过从各种生物样品中获取一系列图像,证明了双光子荧光的检测。全文:PDF参考文献J.W.Lichtman,J.A.Conchello,“荧光显微镜”,自然方法2(12),910(2005)。CrossRef W.Zipfel,R.Williams,W.Webb,“非线性魔术:生物科学中的多光子显微镜”,自然生物技术。211369(2003)。CrossRef相干,变色龙超数据表(2019)。DirectLink J.Boguslawski等人,“使用2光子激发荧光扫描激光检眼镜对人眼进行体内成像”,J.Clin。投资132(2),e154218(2022)。CrossRef M.J.Marzejon等人,“皮秒脉冲双光子微辐射测量”,Biomed。选择Expr。12462(2021)。CrossRef A.Fast等人,“制度驱动因素对企业社会责任参与的影响:发达经济体和发展中经济体的比较”,Sci。众议员1018093(2020)。CrossRef D.Stachowiak等人,“可从872调谐到1075的飞秒掺铒光纤激光源 纳米用于人类双光子视觉研究”,Biomed.Opt.Expr.131899(2022)。CrossRef MenloSystems,T光飞秒光纤激光器1560纳米(2013)。DirectLink J.Yao,L.V.Wang,“光声显微镜”,激光与光子学,2013年,第758版。Stachowiak等人,“用于双光子激发荧光成像的倍频飞秒掺铒光纤激光器”,Biomed。选择Expr。11431(2020)。CrossRef B.R.Masters等人,“减轻双光子真皮成像过程中的热机械损伤潜力”,J.Biomed。选择91265(2004)。CrossRef
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来源期刊
CiteScore
1.40
自引率
0.00%
发文量
24
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