243 results about "IH Antibody" patented technology

Apparatus, methods, and computer-readable media are provided for segmentation, processing (e.g., preprocessing and/or postprocessing), and/or feature extraction from tissue images such as, for example, images of nuclei and/or cytoplasm. Tissue images processed by various embodiments described herein may be generated by Hematoxylin and Eosin (H&E) staining, immunofluorescence (IF) detection, immunohistochemistry (IHC), similar and/or related staining processes, and/or other processes. Predictive features described herein may be provided for use in, for example, one or more predictive models for treating, diagnosing, and/or predicting the occurrence (e.g., recurrence) of one or more medical conditions such as, for example, cancer or other types of disease.

Methods for identifying Quantifiable Internal Reference Standards (QIRS) for immunohistochemistry (IHC). Also disclosed are methods for using QIRS to quantify test antigens in IHC.

This invention relates to methods of analyzing a tissue sample from a subject. In particular, the invention combines morphological staining and/or immunohistochemistry (IHC) with fluorescence in situ hybridization (FISH) within the same section of a tissue sample. The analysis can be automated or manual. The invention also relates to kits for use in the above methods.

A computerized method for immunohistochemistry analysis of tissue utilizes digital images of multiple adjacent tissue sections aligned within a computerized software and processed with an algorithm to quantify a two-dimensional IHC signature score for each respective slide image. In various embodiments, the IHC score is performed over several adjacent sections and further processed to produce a three-dimensional IHC quantification referred to as an IHC signature map.

The invention discloses a preparation method of a brain tissue rapid freezing section. According to the method, acetone is used as a freezing embedding medium and a liquid nitrogen intermediate medium, so that brain tissue can be rapidly frozen , and formation of ice crystals on the brain tissue can be effectively reduced; besides, factors affecting manufacturing quality, such as temperatures during material drawing and sectioning, fixing and soring conditions after sectioning and the like, of the freezing section are optimized, and the quality of the finally prepared section is further guaranteed. According to the brain tissue rapid freezing section obtained with the method, the freezing section which has stability and can well protect antigens and the enzyme activity is provided for further immunofluorescence, immunohistochemistry and in situ hybridization tests on the brain tissue, and a pathological section meeting requirements is provided for future clinical diagnosis related to nervous system diseases and scientific researches. Particularly, molecular and biochemical index detection can be further performed on other tissue of a mouse which is not subjected to perfusion treatment in the scientific research.

A sample processing system that may be configured to achieve parallel or coincidental sample processing such as histochemical processing may involve a plurality of samples arranged for coincidental movement perhaps by use of angular microscopic slide movements to cause processing activity that may include repeated elimination and reapplication of a fluidic substance perhaps through the action of capillary motion in order to refresh a microenvironment adjacent to a sample such as a biopsy or other such sample. Snap in antibody and other substances may be included to ease operator actions and to permit location specific substance applications perhaps by including single container multiple chamber multiple fluidic substance magazines, linearly disposed multiple substance source, and primary antibody cartridges. Through refreshing of a microenvironment, depletion of the microenvironment is avoided and the time necessary for slide processing may be dramatically shortened from a more common 60 to 120 minutes to perhaps less than 15 minutes so as to permit use of such a system in an intraoperative or surgical environment such as recommended by the College of American Pathologists intraoperative guidelines or the like. Patients may thus avoid a need to be subjected to an additional surgical procedure when lab results become available to see if tumors or the like were fully removed in a prior procedure.

Disclosed is a set of glass slides used for carrying out immunohistochemistry staining and storage to a tissue slice. A bearing face of an object bearing unit is provided with grooves which are different in depth and shape and are used for containing the tissue slice. The inner surfaces of the grooves are smooth. Each groove is corresponding to a mounting unit. A mounting unit sheet is matched with the shapes of the grooves. Straight lines which are vertically crossed in a vertical and horizontal mode use the centers of the mounting units as a base point and are arranged on the mounting units, each square is formed, the side length of each square is 10 micrometers, and sealing rings are arranged on the edges of the mounting units. The set of glass slides effectively avoids the problems that a tissue slice is easy to drop off, an antibody overflows, cover glass shifts, and tissue transfer is damaged in an existing immunohistochemistry detection process, is simple in structure, low in cost, and capable of well ensuring stability of the tissue slice and the cover glass and effectiveness of contact reaction of the antibody and a tissue, and can measure and calculate the size and the area of a detected tissue through scale marks on the mounting units.

A microfluidic exosome profiling platform integrating exosome isolation and targeted proteomic analysis is disclosed. This platform is capable of quantitative exosomal biomarker profiling directly from plasma samples with markedly enhanced sensitivity and specificity. Identification of distinct subpopulation of patient-derived exosomes is demonstrated by probing surface proteins and multiparameter analyses of intravesicular biomarkers in the selected subpopulation. The expression of IGF-1R and its phosphorylation level in non-small cell lung cancer (NSCLC) patient plasma is assessed as a non-invasive alternative to the conventional biopsy and immunohistochemistry. Detection of ovarian cancer also is assessed. The microfluidic chip, which may be fabricated of a glass substrate and a layer of poly(dimethylsiloxane), includes a serpentine microchannel to mix a fluid and a microchamber for the collection and detection of exosomes.

The invention provides a method for detecting endometrial receptivity through MST1 and phosphorylated MST1. The method comprises the steps that a human endometrial carcinoma cell line Ishikawa and HEK293T cells are kept and cultured in a 10% FBS and mycillin containing double-antibody DMEM/F12 culture solution; an immunoblotting experiment is carried out; co-immunoprecipitation is carried out; immunohistochemistry is carried out; adjustment of MST1 on the transcriptional activity of HOXA10 is analyzed through chromosome co-immunoprecipitation (ChIP)/PCRs; human choriocarcinoma cell (BeWo) sphere adhering experiments are carried out. According to the method, the expression level of MST1 and MST1 phosphorylation modification in endometrial tissue is detected conveniently and fast, and the receptivity state of the endometrium can be directly reflected.

The invention provides a high-specificity and high-sensitivity coordination combination anti-human TK1 antibody prepared from an antigenic determinant consisting of 23 peptide at an N end, 20 peptide at a C end and 28 peptide at the C end of human cervical cancer cells, and application thereof to tumor diagnosis. The antigenic determinant comprises the following amino acid sequences: 1) the 23 peptide (3-25) at the N end: CINLPTVLPGSPSKTRGQIQVIL: 2) the 20 peptide (206-225) at the C end: CPVPGKPGEAVAARKLFAPQ; and 3) the 28 peptide at the C end: AGPDNKENCPVPGKPGEAVAARKLFAPQ. The invention simultaneously provides a method applying the antigen for preparing the antibody. An antibody kit provided by the invention has the characteristics of high sensitivity, high specificity, low cost and the like, tumor rehabilitation populations are periodically monitored by an enhanced chemiluminescence dot blot detection method, immunohistochemistry detection and the detection kit, and the recurrence and transfer risk and the prognosis of the tumor rehabilitation people are evaluated.

The invention relates to medicine application of 20(S)-ginsenoside Rg3, in particular to application of 20(S)-ginsenoside Rg3 in preparation of medicines for treating a non-small cell lung cancer. In the invention, selecting a human non-small cell lung cancer cell strain (A549 lung adenocarcinoma, H460 large cell lung cancer and LTEP-78 lung squamous carcinoma) to be inoculated under the skin of a naked mouse, and observing the influence of the SPG-Rg3 on the non-small cell lung cancer; and carrying out CD34 immunohistochemistry staining and TUNEL immunofluorescence staining on tumor tissues, and observing the influence of the SPG-Rg3 on tumor angiogenesis and apoptosis. The inclusion proves that the 20(S)-ginsenoside Rg3 can remarkably inhibit the growth of the non-small cell lung cancer, has the action mechanism related with the promotion of the tumor apoptosis and the inhibition of the tumor angiogenesis and unobvious cooperation action when being combined with cyclophosphamide for application, and can be used for the clinical chemotherapy of the non-small cell lung cancer.

Described herein are computer-implemented methods for analysis of a tissue sample. An example method includes: annotating the whole tumor regions or set of tumorous sub-regions either on a biomarker image or an H&E image (e.g. from an adjacent serial section of the biomarker image); registering at least a portion of the biomarker image to the H&E image; detecting different cellular and regional tissue structures within the registered H&E image; computing a probability map based on the different detected structures within the registered H&E image; deriving nuclear metrics from each of the biomarker and H&E images; deriving probability metrics from the probability map; and classifying tumor nuclei in the biomarker image based on the computed nuclear and probability metrics.

The invention belongs to the biotechnology field, relates to application of PSMD4 protein, and in particular relates to application of the PSMD4 protein in preparation of a liver cancer prognostic evaluation kit. The invention adopts an immunohistochemistry technology, a microscope photograph technology and computer image processing software to test the relative transcript level of PSMD4 protein of tumor tissues relative to the tumors and determine the correlation between the relative transcript level of PSMD4 protein and the prognosis of hepatocellular carcinoma patients after operation by a manner of combining the postoperative follow-up information. The PSMD4 protein can be used for preparing a protein molecular marker for judging prognosis of the liver cancer patients, and has important instruction significance to postoperative monitor and sequential therapy of the hepatocellular carcinoma patients.

A method for detecting and quantitating multiple and unique fluorescent signals from a cell sample is provided. The method combines immunohistochemistry and a fluorescent-labeled in situ hybridization techniques. The method is useful for identifying specific subcellular components of cells such as chromosomes and proteins.

The present invention is directed to the identification of a biomarker specifically located in the plasma membrane of pancreatic beta cells. It was selected by a Systems Biology approach on Massively Parallel Signal Sequencing datasets obtained in human islets and Affymetrix microarray datasets on human islets, purified rat primary beta and non beta cells and insulinoma cells. Based on a set of specific features the biomarker is a unique candidate for imaging and targeting strategies to study the pancreatic beta cell mass in health and disease (T1 D, T2D, pancreatic cancers, obesity, islet transplantation, beta cell regeneration). The five specific features of the selected biomarkers are: 1) Preferentially expressed in pancreatic islets as compared to surrounding tissues; 2) Higher expression in pancreatic beta cells than in pancreatic alpha cells or than in other islet non-beta cells; 3) Expression levels in pancreatic beta cells are higher or comparable to glucokinase which is an enzyme specifically expressed in the pancreatic beta cell; 4) Located in the membrane and as such targetable with antibodies, peptides or small molecules which allows imaging, targeting and immunohistochemistry; and 5) Expression is not induced during the process of inflammation of the beta cell mass and the protein is not enriched in T-cells and dendritic cells or in other cells participating in the inflammation process.

The invention discloses a method for establishing a human bladder transitional cell carcinoma cell line and a mouse model of bladder carcinoma tissue recombination functional reconstruction. The method includes the primary cell culture, immortalized cell line identification, tissue reorganization and planting, HE staining, and immunohistochemistry. The invention establishes a novel stable human bladder transitional cell carcinoma cell line, and uses the cell line to construct the mouse model of bladder carcinoma tissue recombination functional reconstruction. The occurrence and development of bladder carcinoma are simulated in mice. The method researches on the biological behavior of bladder carcinoma from in vitro molecular and cell biology and in vivo animal models, and provides an effective tool for the discovery of new biomarkers and therapeutic measures.

A number of selected genes/gene products; Application of selected genes/gene products at mRNA or protein levels either singly or in combination; Application of selected genes/gene products at mRNA levels by any of the methods such as: Northern blotting, or reverse transcription and conventional PCR, or reverse transcription and quantitative real-time PCR or gene expression micro-arrays; Application of selected genes/gene products at protein levels by either Western Blotting, or immunohistochemistry, or ELISA or functional assays or gel electrophoretic separation followed by spectroscopic identification (proteamics); Application of selected genes/gene products at peptide levels derived from proteins and spectroscopic methods of identification; Detection of a hyperproliferative condition, a precancerous condition, a predisposition to develop hyperproliferative condition or cancer by applying any one of the selected genes either singly or in combination in breast tissue, breast fluid, breast cells, blood or any other tissues or cells of a mammal; Application of selected genes either singly or in combination with others for designing molecular therapeutic drugs to treat a hyperproliferative condition, a precancerous condition, or predisposition to develop hyperproliferative condition or cancer of the breast or any other tissue of a mammal; Application of selected genes either singly or in combination with others for following up of a therapeutic treatment to a hyperproliferative condition, or precancerous condition, or predisposition to a hyperproliferative condition, or cancer, of the breast or any other tissue of a mammal; Application of selected genes either singly or in combination with others for screening of therapeutic drugs to a hyperproliferative condition, or precancerous condition, or predisposition to a hyperproliferative condition, or cancer, of the breast or any other tissue of a mammal; and Application of selected genes either singly or in combination with others for designing vaccines to prevent a hyperproliferative condition, or precancerous condition, or predisposition to a hyperproliferative condition, or cancer, of the breast or any other tissue of a mammal.

The androgen receptor (AR) is the key driver of prostate differentiation and prostate cancer (PC) progression, and androgen ablation is the cornerstone of advanced PC treatment. Prostate-specific membrane antigen (PSMA) represents another target of interest in PC. Previous publications have reported inconsistent associations between androgen levels and PSMA expression. Using a panel of prototypical human PC cell lines, this relationship is clarified. PSMA is a biomarker that distinguishes AR-positive/PSMA-positive adenocarcinomas from AR-negative variants. PSMA is a cell surface barometer of androgen activity that can be readily identified by immunohistochemistry and/or in vivo imaging. Given that anti-androgen therapy is likely to remain a cornerstone of PC treatment, the associated up-regulation of PSMA, as well as its other characteristics, makes it a compelling target opportunity in PC.