Abstract
In vivo optical microscopic imaging techniques have recently emerged as important tools for the study of neurobiological development and pathophysiology. In particular, two-photon microscopy has proved to be a robust and highly flexible method for in vivo imaging in highly scattering tissue. However, two-photon imaging typically requires extrinsic dyes or contrast agents, and imaging depths are limited to a few hundred microns. Here we demonstrate Optical Coherence Microscopy (OCM) for in vivo imaging of neuronal cell bodies and cortical myelination up to depths of ~1.3 mm in the rat neocortex. Imaging does not require the administration of exogenous dyes or contrast agents, and is achieved through intrinsic scattering contrast and image processing alone. Furthermore, using OCM we demonstrate in vivo, quantitative measurements of optical properties (index of refraction and attenuation coefficient) in the cortex, and correlate these properties with laminar cellular architecture determined from the images. Lastly, we show that OCM enables direct visualization of cellular changes during cell depolarization and may therefore provide novel optical markers of cell viability.
Highlights
Staining methods used by Golgi, Cajal, and Nissl led to seminal observations about the microscopic organization of the brain
Fundamental limits to the penetration depth of two-photon microscopy are set by attenuation from scattering [7], aberrations and out-of-focus fluorescence may degrade contrast at larger imaging depths [5]
Optical Coherence Microscopy (OCM) enables a range of new measurements in the living brain
Summary
Staining methods used by Golgi, Cajal, and Nissl led to seminal observations about the microscopic organization of the brain. Cyto-architecture in the brain is studied by staining of bulk tissues, specific cell populations, or organelles in histological specimens followed light microscopic observation. Advances in light microscopy [1] and cell-labeling techniques have enabled in vivo imaging of neuro-anatomy and function. Twophoton microscopy [2,3], in particular, has become the method of choice for in vivo cortical imaging up to depths of a few hundred microns. Imaging depths approaching a millimeter can be achieved with two-photon microscopy using sparse labeling and regenerative amplifiers [4,5] or longer wavelength excitation [6]. Fundamental limits to the penetration depth of two-photon microscopy are set by attenuation from scattering [7], aberrations and out-of-focus fluorescence may degrade contrast at larger imaging depths [5]
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