Provided herein are methods for inkjet printing objects, including objects which may be used as elements of microfluidic devices. The microfluidic devices incorporating the elements are also provided. Such microfluidic devices include those configured to quantify the expression and activity of exosomal matrix metalloprotease, MMP14. These microfluidic devices may be used in methods of monitoring breast cancer in patients having breast cancer.

Various embodiments may provide a method of illuminating a sample surface. The method may include arranging an illumination subsystem, the illumination subsystem including an optical source and at least one lens, having an optic axis at an incident angle greater than 0° and less than 90° to a normal of the sample surface such that a reference illumination distribution is directly generated on the sample surface based on optical light emitted by the illumination subsystem. The method may also include arranging an adjustment optical subsystem such that an adjusted illumination distribution which is more symmetrical compared to the reference illumination distribution is generated on the sample surface based on optical light emitted by the illumination subsystem.

A reagent strip and a reagent analyzer for reading the reagent strip is described. The reagent strip includes a substrate, at least one reagent pad positioned on the substrate, and a photo luminescent phosphor spot positioned at a fixed location on the substrate. The photo luminescent phosphor spot is formulated to exhibit a predetermined addressable attribute.

A method for analyzing a biochip image is provided, including: (S1) acquiring and preprocessing the biochip image to obtain a preprocessed image; (S2) performing a correction for angle deflection on the preprocessed image to obtain a deflection-corrected image; and (S3) performing an enhancement processing on the deflection-corrected image, and identifying a positive or negative of an area of interest in the preprocessed image according to an image on which the enhancement processing has been performed. An apparatus (100) for analyzing a biochip image, a method for analyzing an image, a computer device (200) and a storage medium are disclosed.

Provided herein are methods for preparing biological samples for spatial proteomic analysis, methods of determining a location of a protein analyte in a biological sample, and methods of determining a location of a protein analyte and a nucleic acid analyte in a biological sample.

Multiplexed fluorescent imaging which is essential for finding out how various biomolecules are spatially distributed in cells or tissues is disclosed. The present disclosure may obtain 10 or more different biomolecule images with one labeling and imaging by newly designing selection of fluorophores, detection spectral ranges, and signal unmixing algorithm. The present disclosure is a blind unmixing technology for unmixing an image without an emission spectrum of fluorophore, and in this technology, 4 pairs of fluorophores are used, and each pair consists of two fluorophores in which emission spectra are overlapped. Each pair of fluorophores is strongly excited by only one excitation laser. Two images with different detection spectral ranges are obtained for each pair, and two images are unmixed via mutual information minimization without fluorophore emission spectrum information. Two images also may be unmixed via Gram-Schmidt orthogonalization and fluorescence measurement based unmixing. This signal unmixing is repeated for each pair of fluorophores. Furthermore, a total of 10 or more fluorophores may be simultaneously used by adding two large stoke's shift fluorophores emitting light in wavelength ranges that does not overlap with the emission spectra of the above 8 fluorophores.

An optical system configured to measure a raised or receded surface feature on a surface of a sample may comprise a broadband light source; a tunable filter configured to filter broadband light emitted from the broadband light source and to generate a first light beam at a selected wavelength; a linewidth control element configured to receive the first light beam and to generate a second light beam having a predefined linewidth and a predetermined coherence length; collimating optics optically coupled to the second light beam and configured to collimate the second light beam; collinearizing optics optically coupled to the collimating optics and configured to align the collimated second light beam onto the raised or receded surface feature of the sample, and a processor system and at least one digital imager configured to measure a height of the raised surface or depth of the receded surface from light reflected at least from those surfaces.

Methods of deep ultraviolet fluorescence (DUVF) and multi spectral imaging (MSI) detection are disclosed herein for the detection and identification of pathogens on plants. DUV light and visible or near-infrared light are used to illuminate plants or plant leaves such that the light intensity reflected or emitted by the plant or plant leaves can be used to identify the type of pathogen and measure the amount of pathogen on the plant or plant leaves and, additionally, be used to measure the plant's stress response to such pathogen. Also provided herein is a biophotonic analyzer device that uses both DUVF and MSI detection for the monitoring and surveillance of plant health and for the identification and enumeration of pathogens on plants or plant leaves.

Exemplary systems, devices, methods, apparatus and computer-accessible media for providing and/or utilizing optical frequency domain imaging (OFDI) and fluorescence of structures and, e.g., multimodality imaging using OFDI techniques and fluorescence imaging techniques are described. For example, an arrangement can provide at least one electro-magnetic radiation to an anatomical structure. Such exemplary arrangement can include at least one optical core and at least one cladding at least partially surrounding the fiber(s). A region between the optical core(s) and the cladding(s) can have an index that is different from indexes of the optical core(s) and the cladding(s). The arrangement can also include at least one apparatus which is configured to transmit the radiation(s) via the optical core(s) and the cladding(s) to the anatomical structure.

The present disclosure provides apparatuses, systems, and methods for performing particle analysis through flow cytometry at comparatively high event rates and for gathering high resolution images of particles.