High-throughput (HT) sequencing, microarray screening and protein expression profiling technologies drive discovery efforts in today's genomics and proteomics laboratories. These tools allow ...
As instruments grow faster, leaders say clinical impact will depend on trust, standards, data, and assays built for real ...
The rapid evolution of omic technologies such as spanning genomics, transcriptomics, and proteomics, is reshaping how we ...
Protein function is inherently spatial—the same molecule can elicit distinct biological outcomes depending on its localization, interacting partners, and surrounding microenvironment. Conventional ...
Proteins are workhorses that carry out most of the biological functions in our cells. While the genes we inherit from our parents, our so-called genome, are fixed and usually remain unchanged ...
Proteomics—a term first coined in the mid-1990s—refers to the study of the complete set of proteins expressed in a cell, tissue, or organism. In contrast to genomics and transcriptomics, proteomics is ...
Proteins found in blood plasma can provide critical insights into human health, acting as biomarkers that scientists can use to understand disease and provide personalized care. Yet, capturing the ...
Our program draws training faculty—currently more than 40—from more than 12 departments and six schools across the CWRU campus, ensuring you’ll acquire the expertise needed to succeed in the ...
Proteins are workhorses that carry out most of the biological functions in our cells. While the genes we inherit from our parents, our so-called genome, are fixed and usually remain unchanged ...
Proteomics is a research field focusing on the large-scale study of proteins in biological contexts. The goal is to describe various biological questions related to aging, drug treatment, disease, and ...