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http://www.ontariotumourbank.ca/
The Ontario Tumour Bank is a province-wide biorepository and data bank focused on collection of tumor-related human biospecimens. It provides academic and industry cancer researchers with a diverse selection of high quality tumor-related specimens and data obtained directly by dedicated tumour bank staff, who follow a stringent set of procedures and ethical guidelines. The biospecimens and clinical data are an important resource for scientists engaged in translational research who are developing better diagnostic tools and new drug therapies. Researchers depend on the Ontario Tumour Bank to provide research biospecimens of high quality, diversity, and integrity. Operating at state-of-the-art hospitals and cancer centers across Ontario, the Ontario Tumour Bank coordinates the collection, storage, analysis, annotation, and distribution of tumor and peripheral blood samples. Working in collaboration with local pathologists, medical oncologists, surgeons and other hospital personnel, specially trained staff obtain patient consent, collect tissues and assemble comprehensive clinical information about each donor and the corresponding samples.
Proper citation: Ontario Tumour Bank (RRID:SCR_004732) Copy
http://www.biobank-gso.org/apex/f?p=200:1:2527679222961463
The Virtual Tumour Bank of the Canceropole Grand Sud-Ouest''s mission is to federate the cancer research of four French regions: Aquitaine, Languedoc-Roussillon, Limousin and Midi-Pyrenees. This site allows access to an inventory of the specimens stored in the tumor banks of the Greater South-West region, within the laboratories of Pathology of the University Hospital Centers and Cancer Centers of Bordeaux, Limoges, Montpellier, Nimes and Toulouse. You may search by disease or multiple criteria. These specimens are removed from patients primarily to confirm and accurately characterize their cancer diagnosis, and are therefore stored by the tumor bank for diagnostic and/or therapeutic purposes. These samples can be re-qualified for scientific research pending that a number of conditions are met, including the absence of refusal from the person (in compliance with French regulations). So far, the tumor bank is a major tool for cancer treatment and research. This inventory is a further evidence of the coordination effort between the eight concerned tumor banks that have been mobilized at the service of patients and research within the framework of the Canceropole Grand Sud-Ouest programs. These biological resources are made available to research groups that conduct basic or translational programs in the field of oncology. They will not be made available for projects in fields other than oncology.
Proper citation: Southwest France Tumour Bank (RRID:SCR_004574) Copy
A provincial biobank resource to support translational cancer research at the BC Cancer Agency, across Canada and internationally. This biobank collects biospecimens (tissues and blood), and clinical information and processes these to create anonymous cases that can be studied by cancer researchers to understand how cancer develops, how it grows, how it spreads, and how it responds to treatment. These tissues and data are obtained from patients who undergo surgery to treat a tumor and who have generously provided their consent for the TTR to collect tissues that are unused after diagnosis has been completed. The TTR is a provincial program that currently comprises a core biobank at the Vancouver Island Center, Victoria, that offers participation in the program to patients in Victoria and Nanaimo. The TTR works with other banks and expert translational research groups in BC, to create expanded capacity for collection and opportunities for research access to tissue resources. The TTR operates under the management and oversight of the director, a scientific advisory board, and the UBC BCCA Research Ethics Board. The TTR operates within organizational policies and a commitment to protection of donor privacy that is embodied in all standard operating procedures and aspects of the repository. The TTR is also a founding member and contributor to the development of provincial (BC BioLibrary) and national (CTRNet) initiatives to promote biobanking.
Proper citation: British Columbia Tumour Tissue Repository (RRID:SCR_004597) Copy
https://moffitt.org/research-science/shared-resources/tissue/
A central tissue repository at Moffitt specializing in protocol-driven human tissue collection, storage, processing and dissemination. Tissue Core provides investigators with access to high quality, well-annotated human specimens obtained from representative of the patient populations. The advent of powerful molecular technologies has opened the door to developing more effective treatments of patients with cancer. Access to high quality specimens with associated clinical, treatment, recurrence outcome data will be critical to developing and validating the tests needed for diagnosis and prediction of response to therapy. Since its commencement in 1993, the Tissue Core has collected more than 8,000 cases of human liquid cancers and solid primary and metastatic tumors both malignant and benign with adjacent normal, from variety of sites and diagnoses. Collected samples are mostly remnant tissues obtained from patients undergoing therapeutic surgical procedures at the Center. The core also ensures tissue release compliance with USF-IRB and Privacy Board recommendations. * Protocol driven sample collection, processing and distribution * Collection of sample and patient demographic information. * Nucleic acid extractions from tissue sections, FNA, core biopsies blood and bone marrow. * Histology services: H&E slides, staining, sectioning, paraffin blocks, OCT blocks, sample microdissection * WBC, plasma and serum isolation. * Project development and support: Facility staff provides advice and guidance to researchers.
Proper citation: Moffitt Cancer Center Tissue Core (RRID:SCR_004406) Copy
Biospecimen repository of normal and diseased human material from a variety of tissues and conditions along with clinical annotation. Both frozen aliquots and paraffin embedded tissue are available. Biospecimens are available to qualified researchers with IRB approval. * Preliminary inquires please contact Cheryl Spencer at cheryl.spencer (at) bmc.org
Proper citation: Boston University Biospecimen Archive Research Core (RRID:SCR_005363) Copy
THIS RESOURCE IS NO LONGER IN SERVICE, documented on July 16, 2013. Located in Spain, the Andalusian Regional Tumour Bank is a regional tumor bank. In the last decades cancer knowledge is growing exponentially due human genome knowledge and technological advantages. However, this disease is the biggest problem of health in Europe, with more than 2,5 million new cases per year. The diagnosis and treatment of cancer is now allowing to identify the characteristics that the disease has on each person. The next step is meant to be a great revolution in the treatment of cancer. This scientific development is dependent on the availability of human tumour samples preserved in demanding conditions. Current technology requires the availability of tissue morphological and molecular conditions similar to those that had the sample before being removed. Tumor banks are responsible for these new quality requirements to foster the development of research and health care of patients.
Proper citation: Andalusian Regional Tumour Bank (RRID:SCR_004885) Copy
http://www.einstein.yu.edu/centers/ictr/
Patient-derived specimens are essential to research in genomics, proteomics, and biomarkers. We provide banking for biological fluid and tissue specimens as well as human DNA and RNA. We provide secure archival sample storage as well as clinically-annotated specimen biobanks for defined research projects. The core serves the human research blood and tissue banking needs of clinical and translational researchers. Samples can be banked by an individual PI or by a consortium of investigators. All samples are tracked and archived using a secure tracking database, the Einstein-Montefiore Bio-Repository Databank (EM-BRED), http://informatics30.aecom.yu.edu/em-bred/default.aspx. EM-BRED provides qualified investigators with a solution to securely link patient specimens to clinical and pathological data. It consists of a user-friendly query engine that allows for comprehensive specimen search, and ultimately to build clinical annotations of relevance. The facility works under the best practices set out by NCI and ISBER (2006) for collection, storage, and retrieval of human biological materials for research.
Proper citation: Einstein-Montefiore Institute for Clinical and Translational Research Biorepository (RRID:SCR_005297) Copy
Portal for preclinical information and research materials, including web-accessible data and tools, NCI-60 Tumor Cell Line Screen, compounds in vials and plates, tumor cells, animals, and bulk drugs for investigational new drug (IND)-directed studies. DTP has been involved in the discovery or development of more than 70 percent of the anticancer therapeutics on the market today, and will continue helping the academic and private sectors to overcome various therapeutic development barriers, particularly through supporting high-risk projects and therapeutic development for rare cancers. Initially DTP made its drug discovery and development services and the results from the human tumor cell line assay publicly accessible to researchers worldwide. At first, the site offered in vitro human cell line data for a few thousand compounds and in vitro anti-HIV screening data for roughly 42,000 compounds. Today, visitors can find: * Downloadable in vitro human tumor cell line data for some 43,500 compounds and 15,000 natural product extracts * Results for 60,000 compounds evaluated in the yeast assay * In vivo animal model results for 30,000 compounds * 2-D and 3-D chemical structures for more than 200,000 compounds * Molecular target data, including characterizations for at least 1,200 targets, plus data from multiple cDNA microarray projects In addition to browsing DTP's databases and downloading data, researchers can request individual samples or sets of compounds on 96-well plates for research, or they can submit their own compounds for consideration for screening via DTP's online submission form. Once a compound is submitted for screening, researchers can follow its progress and retrieve data using a secure web interface. The NCI has collected information on almost half a million chemical structures in the past 50 years. DTP has made this information accessible and useful for investigators through its 3-D database, a collection of three-dimensional structures for more than 200,000 drugs. Investigators use the 3-D database to screen compounds for anticancer therapeutic activity. Also available on DTP's website are 127,000 connection tables for anticancer agents. A connection table is a convenient way of depicting molecular structures without relying on drawn chemical structures. As unique lists of atoms and their connections, the connection tables can be indexed and stored in computer databases where they can be used for patent searches, toxicology studies, and precursor searching, for example., THIS RESOURCE IS NO LONGER IN SERVICE. Documented on September 16,2025.
Proper citation: Developmental Therapeutics Program (RRID:SCR_003057) Copy
http://sourceforge.net/projects/mutascope/
Software suite to analyze data from high throughput sequencing of PCR amplicons, with an emphasis on normal-tumor comparison for the accurate and sensitive identification of low prevalence mutations.
Proper citation: Mutascope (RRID:SCR_001265) Copy
http://www.braintumourbank.ca/pages/about.html
THIS RESOURCE IS NO LONGER IN SERVICE, documented May 10, 2017. The mission of the Canadian Virtual Brain Tumour Bank (CVBTB) is to facilitate clinical, molecular and translational research through the provision of well-characterized tissue linked to clinical data and to become a standardized national tissue resource whereby scientific needs are met, addressed and accelerated through a common public accessible core the CVBTB. Recognizing the need to encourage systemic banking of brain tumor tissues throughout the country and to link banks of brain tumor tissue samples with academic and scientific institutions that require these samples, the CVBTB was established. Under the sponsorship of Schering Plough Canada Inc. and in association with the Canadian Brain Tumour Consortium (CBTC), the CVBTB looks to act as a resource for all researchers to provide them with information on the types of brain tumor tissue samples available and to direct them to the tumor tissue banking sites holding these samples. The CVBTB also looks to provide information on standard operating procedures regarding aspects of tumor tissue banking such as tissue accrual, storage and shipment and the processing of blood samples such as serum and lymphocytes. The CVBTB currently consists of four brain tumour tissue banking sites (Toronto Western Hospital - Toronto, Ontario; London Health Sciences Centre - London, Ontario; McGill University - Montreal, Quebec; University of Calgary - Calgary, Alberta) and is continuously looking for more institutions to be a part of the CVBTB. If your institution would like to become a part of the CVBTB, please contact the CVBTB coordinator.
Proper citation: Canadian Virtual Brain Tumour Bank (RRID:SCR_004221) Copy
http://bioinformatics.oxfordjournals.org/content/early/2012/05/10/bioinformatics.bts271.full.pdf
THIS RESOURCE IS NO LONGER IN SERVICE. Documented on March 7,2024. Software for somatic single nucleotide variant (SNV) and small indel detection from sequencing data of matched tumor-normal samples. The method employs a novel Bayesian approach which represents continuous allele frequencies for both tumor and normal samples, whilst leveraging the expected genotype structure of the normal. This is achieved by representing the normal sample as a mixture of germline variation with noise, and representing the tumor sample as a mixture of the normal sample with somatic variation. A natural consequence of the model structure is that sensitivity can be maintained at high tumor impurity without requiring purity estimates. The method has superior accuracy and sensitivity on impure samples compared to approaches based on either diploid genotype likelihoods or general allele-frequency tests.
Proper citation: Strelka (RRID:SCR_005109) Copy
https://github.com/ding-lab/msisensor
A C++ software program for automatically detecting somatic and germline variants at microsatellite regions. It computes length distributions of microsatellites per site in paired tumor and normal sequence data, subsequently using these to statistically compare observed distributions in both samples.
Proper citation: MSIsensor (RRID:SCR_006418) Copy
http://bioinf.wehi.edu.au/socrates/
Software for detecting genomic rearrangements in tumors that utilizes only split-read data. It features single nucleotide resolution, high sensitivity, and high specificity in simulated data. It takes advantage of parallelism for efficient use of resources.
Proper citation: Socrates (RRID:SCR_006411) Copy
Statistical software to estimate tumor purity, ploidy and absolute copy numbers from next generation sequencing data.
Proper citation: AbsCN-seq (RRID:SCR_006409) Copy
http://bioinfo-out.curie.fr/projects/snp_gap/
Software for automatic detection of absolute segmental copy numbers and genotype status in complex cancer genome profiles measured by single-nucleotide polymorphism (SNP) arrays. The method is based on pattern recognition of segmented and smoothed copy number and allelic imbalance profiles. The method performs well even for poor-quality data, low tumor content, and highly rearranged tumor genomes.
Proper citation: Genome Alteration Print (RRID:SCR_012016) Copy
http://www.capitalbiosciences.com/
Biological products including Cell Immortalization Products, Clinically Defined Human Tissue, cDNA ORF Clones, Premade Adenoviruses, Purified Proteins, Viral Expression Systems and others as well as services like Custom Recombinant Adenovirus Production, Custom Recombinant Lentivirus Production, Protein Detection and Quantification and Stable Cell Line Production for academic and governmental research institutes, pharmaceutical and biotechnology industry. Capital Biosciences offers most types of human tissues, normal and diseased, with extensive clinical history and follow up information. Standard specimen format: Snap-frozen(flash-frozen), Formalin fixed and paraffin embedded (FFPE) tissues, Blood and blood products, Bone marrow, Total RNA, Genomic DNA, Total Proteins, Primary cell cultures, Viable frozen tissue. Tumor tissue samples include: Bladder cancer, Glioblastoma, Medulloblastoma, Breast Carcinoma, Cervical Cancer, Colorectal Cancer, Endometrial Cancer, Esophageal Cancer, Head and Neck (H&N) Carcinoma, Hepatocellular Carcinoma (HCC), Hodgkin's lymphoma, Kidney, Renal Cell Carcinoma, Lung Cancer, Non-Small Cell (NCSLC), Lung Cancer, Small Cell (SCLC), Melanoma, Mesothelioma, non-Hodgkin's Lymphoma, Ovarian Adenocarcinoma, Pancreatic Cancer, Prostate Cancer, Stomach Cancer.
Proper citation: Capital Biosciences (RRID:SCR_004879) Copy
http://cran.r-project.org/web/packages/expands/
Software that characterizes coexisting subpopulations (SPs) in a tumor using copy number and allele frequencies derived from exome- or whole genome sequencing input data. The model amplifies the statistical power to detect coexisting genotypes, by fully exploiting run-specific tradeoffs between depth of coverage and breadth of coverage. ExPANdS predicts the number of clonal expansions, the size of the resulting SPs in the tumor bulk, the mutations specific to each SP and tumor purity. The main function runExPANdS provides the complete functionality needed to predict coexisting SPs from single nucleotide variations (SNVs) and associated copy numbers. The robustness of the subpopulation predictions by ExPANdS increases with the number of mutations provided. It is recommended that at least 200 mutations are used as an input to obtain stable results.
Proper citation: ExPANdS (RRID:SCR_005199) Copy
http://gmt.genome.wustl.edu/somatic-sniper/current/
Software program to identify single nucleotide positions that are different between tumor and normal (or, in theory, any two bam files). It takes a tumor bam and a normal bam and compares the two to determine the differences. It outputs a file in a format very similar to Samtools consensus format. It uses the genotype likelihood model of MAQ (as implemented in Samtools) and then calculates the probability that the tumor and normal genotypes are different. This probability is reported as a somatic score. The somatic score is the Phred-scaled probability (between 0 to 255) that the Tumor and Normal genotypes are not different where 0 means there is no probability that the genotypes are different and 255 means there is a probability of 1 ? 10(255/-10) that the genotypes are different between tumor and normal. This is consistent with how the SAM format reports such probabilities. It is currently available as source code via github or as a Debian APT package.
Proper citation: SomaticSniper (RRID:SCR_005108) Copy
Tool for calling indels in Tumor-Normal paired sample mode.
Proper citation: SomaticIndelDetector (RRID:SCR_005107) Copy
http://www.broadinstitute.org/science/programs/genome-biology/computational-rd/somaticcall-manual
Software program that finds single-base differences (substitutions) between sequence data from tumor and matched normal samples. It is designed to be highly stringent, so as to achieve a low false positive rate. It takes as input a BAM file for each sample, and produces as output a list of differences (somatic mutations). Note: This software package is no longer supported and information on this page is provided for archival purposes only.
Proper citation: SomaticCall (RRID:SCR_001196) Copy
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