Abstract: Compositions, devices and methods for performing an Ultra Rapid Droplet Digital Polymerase Chain Reaction (UR-ddPCR) are provided, for detecting and quantifying target nucleic acid obtained from a sample. The disclosed UR-ddPCR method includes an optional ultra-rapid DNA/RNA extraction method that is compatible with ddPCR and an ultra-rapid thermal cycling (UR-TC) method, the combination of which reduces the tissue-to-result time by about 83%, to ˜20 mins, preferably, <20 mins, when compared to ˜2 hrs required for standard ddPCR. The thermal cycling time of UR-ddPCR is shortened compared to standard ddPCR to reduce the denaturation time from 30 seconds to about 1 to about 3 seconds and the annealing/extension step from 60 seconds to about 1 to about 10 seconds, eliminating final the 10-minute heat inactivation step used in standard commercial (Bio-Rad) ddPCR reactions.

Abstract: A system is presented for analyzing and interpreting histologic images. The system includes an imaging device and a diagnostic module. The imaging device captures an image of a tissue sample at an optical section of the tissue sample, where the tissue sample has a thickness larger than the optical section. The system may further include an image interpretation subsystem located remotely from the imaging device and configured to receive the images from the imaging device. The diagnostic module is configured to receive the images for the tissue sample from the imaging device and generates a diagnosis for the tissue sample by applying a machine learning algorithm to the images. The diagnostic module may be interface directly with the imaging device or located remotely at the image interpretation subsystem.

Abstract: Devices and systems for analyzing biological samples are provided. Devices include a hollow body extending from a first end to a second end. The body defines a sample collecting portion. A first opening at the first end of the body is operable to receive a source of negative pressure and a second opening at the second end of the body is operable to receive a biological sample. The body also includes an optically transparent region disposed in a region corresponding to the sample collecting portion, the optically transparent region being configured to transmit electromagnetic radiation therethrough from an imaging device capable of imaging the biological sample when disposed in the sample collecting portion.

Abstract: A system is presented for analyzing and interpreting histologic images. The system includes an imaging device and a diagnostic module. The imaging device captures an image of a tissue sample at an optical section of the tissue sample, where the tissue sample has a thickness larger than the optical section. The system may further include an image interpretation subsystem located remotely from the imaging device and configured to receive the images from the imaging device. The diagnostic module is configured to receive the images for the tissue sample from the imaging device and generates a diagnosis for the tissue sample by applying a machine learning algorithm to the images. The diagnostic module may be interface directly with the imaging device or located remotely at the image interpretation subsystem.

Abstract: Devices and systems for analyzing biological samples are provided. Devices include a hollow body extending from a first end to a second end. The body defines a sample collecting portion. A first opening at the first end of the body is operable to receive a source of negative pressure and a second opening at the second end of the body is operable to receive a biological sample. The body also includes an optically transparent region disposed in a region corresponding to the sample collecting portion, the optically transparent region being configured to transmit electromagnetic radiation therethrough from an imaging device capable of imaging the biological sample when disposed in the sample collecting portion.

Abstract: Devices and systems for analyzing biological samples are provided. Devices include a hollow body extending from a first end to a second end. The body defines a sample collecting portion. A first opening at the first end of the body is operable to receive a source of negative pressure and a second opening at the second end of the body is operable to receive a biological sample. The body also includes an optically transparent region disposed in a region corresponding to the sample collecting portion, the optically transparent region being configured to transmit electromagnetic radiation therethrough from an imaging device capable of imaging the biological sample when disposed in the sample collecting portion.

Abstract: Devices and systems for analyzing biological samples are provided. Devices include a hollow body extending from a first end to a second end. The body defines a sample collecting portion. A first opening at the first end of the body is operable to receive a source of negative pressure and a second opening at the second end of the body is operable to receive a biological sample. The body also includes an optically transparent region disposed in a region corresponding to the sample collecting portion, the optically transparent region being configured to transmit electromagnetic radiation therethrough from an imaging device capable of imaging the biological sample when disposed in the sample collecting portion.

Abstract: The present invention generally relates to dye-loaded nanoparticles. In particular, the present invention provides methods for the staining and visualization of tumor and tumor boundaries using dye-loaded nanoparticles.