Abstract: Milling with ultraviolet excitation (MUVE) realizes high-throughput multiplex imaging of large three-dimensional samples. The instrumentation may comprise a UV-source attachment, precision stage attachment, and/or a blade assembly, and the instrumentation may overcome several constraints inherent to current state-of-the-art three-dimensional microscopy. MUVE offers throughput that is orders of magnitude faster than other technology by collecting a two-dimensional array of pixels simultaneously. The proposed instrumentation also utilizes serial ablation and provides the opportunity for true whole-organ imaging at microscopic resolution.

Abstract: Imaging systems and methods, referred to herein as surface ablation lathe tomography (SALT), may be capable of providing whole organ tomography to provide 3D imaging. The system may provide a UV source that excites a sample, and a camera may capture imaging of fluorescent emission cause by the excitation. The tissue sample may be treated or stained with an imaging agent, such as fluorescent markers with fluorescently-tagged antibodies. The sample may also be infused with and/or embedded in paraffin wax. The tissue sample embedded in paraffin may be placed on a rotating mechanism that rotates, while the UV source excites a desired region and the camera captures imaging of a thin surface layer or shell of the sample. The system may also provide an ablation mechanism, such as a microtome blade or lathe, to ablate surface of the sample during rotation to allow imaging of subsequent layers of the sample.

Abstract: Imaging systems and methods, referred to herein as surface ablation lathe tomography (SALT), may be capable of providing whole organ tomography to provide 3D imaging. The system may provide a UV source that excites a sample, and a camera may capture imaging of fluorescent emission cause by the excitation. The tissue sample may be treated or stained with an imaging agent, such as fluorescent markers with fluorescently-tagged antibodies. The sample may also be infused with and/or embedded in paraffin wax. The tissue sample embedded in paraffin may be placed on a rotating mechanism that rotates, while the UV source excites a desired region and the camera captures imaging of a thin surface layer or shell of the sample. The system may also provide an ablation mechanism, such as a microtome blade or lathe, to ablate surface of the sample during rotation to allow imaging of subsequent layers of the sample.

Abstract: Methods and computer program products for super-resolution mapping of nanoprobes having spectrally distinguishable coherent scattering properties. A sample containing a plurality of nanoprobes is illuminated with broadband light, and coherent scattering by the nanoprobes is detected. Scattered light is spectrally associated with respective nanoprobes, allowing a position associated with each nanoprobe to be mapped.