Live Stimulated Raman Histology for the Near-Instant Assessment of Central Nervous System Samples.

Central nervous system tumors encompass many heterogeneous neoplasms with different outcomes and treatment strategies. The current classification of these tumors is based on molecular parameters in addition to histopathology to define tumor entities. This genomic characterization of tumors is also becoming increasingly essential for physicians to identify targeted therapy options. The deployment of such genomic profiling relies on an efficient surgical sampling. To perform an appropriate tumor resection and a correct sampling of the tumor, the neurosurgeon may request an intraoperative pathological consultation. Stimulated Raman histology (SRH), an emerging nondestructive imaging technology, can address this challenge. SRH allows for a rapid and label-free microscopic examination of unprocessed tissues samples in near-perfect concordance with standard histology. In this study we showed that SRH enabled the near-instant microscopic examination of various central nervous system samples without any tissue processing such as labeling, freezing nor sectioning. Since SRH imaging is a nondestructive approach, we demonstrated that the tissue could be readily recovered after SRH imaging and reintroduced into the conventional pathology workflow including immunohistochemistry and genomic profiling to establish a definitive diagnosis.

Assessment of Compressive Raman versus Hyperspectral Raman for Microcalcification Chemical Imaging.

We experimentally implement a compressive Raman technology (CRT) that incorporates chemometric analysis directly into the spectrometer hardware by means of a digital micromirror device (DMD). The DMD is a programmable optical filter on which optimized binary filters are displayed. The latter are generated with an algorithm based on the Cramer-Rao lower bound. We compared the developed CRT microspectrometer with two conventional state-of-the-art Raman hyperspectral imaging systems on samples mimicking microcalcifications relevant for breast cancer diagnosis. The CRT limit of detection significantly improves, when compared to the CCD based system, and CRT ultimately allows 100× and 10× faster acquisition speeds than the CCD- and EMCCD-based systems, respectively.

FCS diffusion laws in two-phase lipid membranes: determination of domain mean size by experiments and Monte Carlo simulations.

Many efforts have been undertaken over the last few decades to characterize the diffusion process in model and cellular lipid membranes. One of the techniques developed for this purpose, fluorescence correlation spectroscopy (FCS), has proved to be a very efficient approach, especially if the analysis is extended to measurements on different spatial scales (referred to as FCS diffusion laws). In this work, we examine the relevance of FCS diffusion laws for probing the behavior of a pure lipid and a lipid mixture at temperatures below, within and above the phase transitions, both experimentally and numerically. The accuracy of the microscopic description of the lipid mixtures found here extends previous work to a more complex model in which the geometry is unknown and the molecular motion is driven only by the thermodynamic parameters of the system itself. For multilamellar vesicles of both pure lipid and lipid mixtures, the FCS diffusion laws recorded at different temperatures exhibit large deviations from pure Brownian motion and reveal the existence of nanodomains. The variation of the mean size of these domains with temperature is in perfect correlation with the enthalpy fluctuation. This study highlights the advantages of using FCS diffusion laws in complex lipid systems to describe their temporal and spatial structure.

Disposable microscope objective lenses for fluorescence correlation spectroscopy using latex microspheres.

We explore the combination of a latex microsphere with a low NA lens to form a high performance optical system, and enable the detection of single molecules by fluorescence correlation spectroscopy (FCS). Viable FCS experiments at concentrations 1-1000 nM with different objectives costing less than $40 are demonstrated. This offers a simple and low-cost alternative to the conventional complex microscope objectives.