Cancer researchers are uncovering new insights using our Phenoptics™ Quantitative Pathology Research Solutions. In an ovarian cancer case study, Dr. Feldman uses this instrumentation to modernize pathology.
Cancer researchers are uncovering new insights using our Phenoptics™ Quantitative Pathology Research Solutions. In a squamous cell carcinoma cancer case study, Dr. Fox uses the instrumentation to help develop predictive biomarkers.
Cancer researchers are uncovering new insights using our Phenoptics™ Quantitative Pathology Research Solutions. In a lymphoma cancer case study, Dr. Rodig uses the instrumentation to gain insight into tumor pathogenesis.
Cancer researchers are uncovering new insights using our Phenoptics™ Quantitative Pathology Research Solutions. In a lung cancer case study, Dr. Rimm uses this instrumentation to evaluate tumor infiltrating lymphocytes.
Cancer researchers are uncovering new insights using our Phenoptics™ Quantitative Pathology Research Solutions. In a colorectal case study, Dr. Galon uses this instrumentation to uncover more details about cancer and the immune system.
Cancer researchers are uncovering new insights using our Phenoptics™ Quantitative Pathology Research Solutions. In a breast cancer case study, Dr. Rimm uses this instrumentation in her immune-oncology research.
Two years after forming a strategic collaboration AMRI and PerkinElmer are helping to eliminate research and clinical data silos and advance precision medicine.
Research at Institut Pasteur de Lille using PerkinElmer’s Opera® High-Content Screening System and Acapella® Image Analysis Software contributes substantial new information to our understanding of M. tuberculosis.
Cancer researchers now can visualize more of a tumor than ever before using PerkinElmer’s Phenoptics Quantitative Pathology Research Solutions. In a melanoma case study, Dr. Tumeh uses this instrumentation to develop biomarkers in his cancer immunology research.
Using the Attivo and SciBite TERMite platforms, researchers can now unlock the value of unstructured data found in electronic medical records, to reveal medical discoveries that would otherwise be lost in too much data.
PerkinElmer’s NexION 2000 Single Cell ICP-MS has the ability to detect metal in a single ovarian cancer cell, which will lead to new cancer strategies and therapies.
Researchers have developed an optimized and validated routine method for collecting stool samples to extract DNA for the first time. The method uses PerkinElmer's chemagic MSM I extraction instrument and is expected to accelerate microbiome research.
A new generation of high-content imaging systems such as the PerkinElmer Operetta CLS High Content Imaging System and Harmony High Content Imaging and Analysis Software are helping scientists to blaze new trails in cancer drug therapy.
Scientists at UCLA's David Geffen School of Medicine are working with bioluminescent, fluorescent, and positron emission tomography (PET) technologies to reduce infections in post-surgical orthopedic patients as well as fight against metabolic cancer.
PerkinElmer and University of Colorado scientists review the current state of high-content (3D) imaging technologies that are advancing rapidly in the biological and biochemical sectors.
How to improve the odds of developing successful new drugs using Big Data and state-of-the-art analytical tools.
Researchers offer evidence of the importance of epithelial-to-mesenchymal transition (EMT) in the progression of chronic kidney disease.
PerkinElmer's Phenoptics™ quantitative pathology research system helped researchers reveal a predictive biomarker for Merkel cell carcinoma.
Using TIBCO Spotfire® visualization tools, PerkinElmer demonstrates this analytical versatile software in the study of infectious diseases.
PerkinElmer-GIS Centre for Precision Oncology leverages genome expertise and leading edge imaging instrumentation to develop new cancer therapies.
In a medical first, UNC researchers engineer and record skin cells becoming cancer killers using PerkinElmer’s IVIS system.
Monash Institute of Pharmaceutical Sciences is working to develop an inhaled oxytocin treatment for PPH, excessive bleeding after childbirth that kills an estimated 140,000 women a year.
Researchers at the University of Oklahoma have discovered potent polyphenols in brown seaweed that target and prevent the spread of pancreatic cancer cells. Their research is a potential blueprint for fighting the most lethal form of cancer, saving thousands of lives each year.
Using a suite of PerkinElmer's analytical imaging instruments, Dementias Platform United Kingdom (DPUK) is taking a whole-body approach to early detection, better treatment, and prevention of neurodegenerative conditions including Parkinson’s Disease, Motor Neurone Diseases, Multiple Sclerosis, Huntington’s Disease, Creutzfeldt–Jakob Disease, and Alzheimer’s Disease.
Scientists morph stem cells into mini-brains to prove that the Zika virus causes massive brain cell death in fetuses.
Groundbreaking research using PerkinElmer's Vectra multispectral imaging platform may lead to new immunotherapy treatments for cancer.
A profile of how one Big Pharma site is saving big dollars through a single-source provider of laboratory services.
Using high content cellular imaging to engineer new drug therapies to combat human diseases.
High-tech imaging systems help identify new drugs to fight multiple sclerosis.
Visualizing tumors with PerkinElmer’s Solaris™ imaging system.