Todd French scite author profile

We use the lipophilic fluorescence probe Laurdan to study cell membranes. The generalized polarization (GP) of Laurdan-labeled cells contains useful information about membrane fluidity and polarity. A high GP is usually associated with low fluidity, low polarity, or high cholesterol content of the membranes, and a low GP is the opposite. We have combined the GP method and two-photon fluorescence microscopy to provide an alternative approach to study cell membranes. Using two-photon excitation in a conventional microscope offers great advantages for studying biological samples. These advantages include efficient background rejection, low photodamage, and improved depth discrimination. We performed GP measurements on mouse fibroblast cells and observed that both intensity and GP images are not spatially uniform. We tested for possible GP artifacts arising from cellular autofluorescence and lifetime quenching, using a procedure for background fluorescence subtraction and by direct lifetime measurements in the microscope. GP measured in a single cell displays a broad distribution, and the GP of 40 different cells grown on the same cover glass is also statistically distributed. The correlations between intensity and GP images were analyzed, and no monotonic dependence between the two was found. By digitally separating high and low GP values, we found that high GP values often associate with the regions of the plasma membrane and low GP values link with the nuclear membranes. Our results also show local GP variations within the plasma and nuclear membranes.

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Time‐resolved fluorescence microscopy using two‐photon excitation

So¹,

French²,

Yu³

et al. 1995

Bioimaging

131

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We have developed a high sensitivity time‐resolved two‐photon scanning microscope. At an excitation wavelength of 960 nm, a spatial point spread function of 0.3 μm (FWHM) radially and 0.9 μm (FWHM) axially is measured for an 1.25 N.A. objective. The light source is a mode‐locked titanium‐sapphire laser. The time resolution is 400 ps with common chromophores used in microscopy. Time resolution is obtained using the frequency‐domain heterodyning technique in which the laser is synchronized at a very high cross‐correlation frequency to the rest of the electronics. We demonstrate spatial and time resolution using well‐characterized fluorescent microspheres. We show two applications of two‐photon time‐resolved fluorescence microscopy: time‐resolved imaging of multiple dye labeled cells and quantitative cellular calcium concentration using a lifetime indicator.

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Two‐photon fluorescence lifetime imaging microscopy of macrophage‐mediated antigen processing

French

Weaver

et al. 1997

Journal of Microscopy

100

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SummaryTwo-photon fluorescence lifetime imaging microscopy was used noninvasively to monitor a fluorescent antigen during macrophage-mediated endocytosis, intracellular vacuolar encapsulation, and protease-dependent processing. Fluorescein-conjugated bovine serum albumin (FITC-BSA) served as the soluble exogenous antigen. As a relatively nonfluorescent probe in the native state, the antigen was designed to reflect sequential intracellular antigen processing events through time-dependent changes in fluorescence properties. Using two-photon lifetime imaging microscopy, antigen processing events were monitored continuously for several hours. During this time, the initial fluorescein fluorescence lifetime of 0 . 5 ns increased to Ϸ 3 . 0 ns. Control experiments using fluorescein conjugated poly-L-lysine and poly-D-lysine demonstrated that the increase in fluorescence parameters observed with FITC-BSA were due to intracellular proteolysis since addition of the inert D-isomer did not promote an increase in fluorescence lifetime or intensity. Comparisons of intravacuolar and extracellular FITC-dextran concentration suggested active localization of dextran in the vacuoles by the macrophage. In addition, the kinetics of degradation observed using two-photon microscopy were similar to results obtained on the flow cytometer, thus validating the use of flow cytometry for future studies.

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Fluorescence lifetime imaging by asynchronous pump-probe microscopy

Dong¹,

So²,

French³

et al. 1995

Biophysical Journal

105

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We report the development of a scanning lifetime fluorescence microscope using the asynchronous, pump-probe (stimulated emission) approach. There are two significant advantages of this technique. First, the cross-correlation signal produced by overlapping the pump and probe lasers results in i) an axial sectioning effect similar to that in confocal and two-photon excitation microscopy, and ii) improved spatial resolution compared to conventional one-photon fluorescence microscopy. Second, the low-frequency, cross-correlation signal generated allows lifetime-resolved imaging without using fast photodetectors. The data presented here include 1) determination of laser sources' threshold powers for linearity in the pump-probe signal; 2) characterization of the pump-probe intensity profile using 0.28 microns fluorescent latex spheres; 3) high frequency (up to 6.7 GHz) lifetime measurement of rhodamine B in water; and 4) lifetime-resolved images of fluorescent latex spheres, human erythrocytes and a mouse fibroblast cell stained by rhodamine DHPE, and a mouse fibroblast labeled with ethidium bromide and rhodamine DHPE.

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Chapter 14 Fluorescence Lifetime Imaging Techniques for Microscopy

French¹,

Chen

et al. 1998

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Todd French

Fluorescence generalized polarization of cell membranes: a two-photon scanning microscopy approach

Time‐resolved fluorescence microscopy using two‐photon excitation

Two‐photon fluorescence lifetime imaging microscopy of macrophage‐mediated antigen processing

Fluorescence lifetime imaging by asynchronous pump-probe microscopy

Chapter 14 Fluorescence Lifetime Imaging Techniques for Microscopy

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