- Agriculture
- Antibiotic/anti-viral
- Biologics
- Biomarkers
-
By Clinical Application
- Anesthesiology
- Blood & Lymphatic Disease
- CNS & Neurosciences
- Dermatology
- Diabetes, Metabolism, Endocrinology & Obesity
- Ear, Nose, & Throat
- Emergency Services
- Gastroenterology & Digestive Disease
- General & Plastic Surgery
- Health Education, Medical Training and Operations
- Heart and Vascular
- Immunology, Autoimmune & Inflammation
- Infectious Diseases
- Mental Health
- Multiple clinical applications
- Musculoskeletal Disorders, Orthopedics/Bone
- Nephrology/Renal
- Oncology
- Ophthalmology
- Orphan Diseases
- Pediatrics
- Physical Medicine & Rehabilitation
- Radiology
- Regenerative Medicine / Tissue Engineering
- Reproductive Health: Obstetrics & Gynecology
- Respiratory & Pulmonary
- Surgery
- Transplantation
- Urology
- Wound Healing
- COVID-19
- Creative Works
- Diagnostics
- Drug Delivery
- Drug screening and discovery
- Energy, Cleantech & Environmental
- Engineering & Physical Sciences
- Gene therapy
- Imaging
- Materials
- Medical Devices
- Nutraceuticals
- Other
- Research & Design Tools
- RNAi/siRNA
- Sensors & Controls
- Small molecules
- Software & Information Technology
- Stem Cells
- Vaccines
- Veterinary Medicine
Cell lines for the overexpression of GPCRs
Technology Duke inventors have generated five novel cell lines that can be used for the stable overexpression of several GPCRs: HEK293-rATlaR (2pM/mg) HEK293-rATlaR (600fM/mg) NIH-3T3-Flag-Smo 1.1 NIH-3T3-Flag-Smo 1.7 HEK293-Flag-β2AR (2pM/mg, W9)
B-arrestin biosensor cell lines
Technology Duke inventors have created 14 novel biosensor cell lines that can be used for the detection of translocation events, generation of signaling messages, and protein-protein interactions within cells: U2OS-βarrestin2-YFP U2OS-βarrestin1-YFP 293-βarrestin2-YFP 293-βarrestin1-YFP NIH-3T3-Smo-GFP HEK293-rATlaR-CFP,…
Plasmids for the expression of B-arrestins and GRKs
Technology Duke inventors have generated 12 novel plasmids that can be used for the expression of β-arrestins and GRKs: pCDNA3-βarrestin1-Flag pCDNA3-βarrestin2-Flag pGEX-5G/LIC-βarrestin1 pGEX-5G/LIC-βarrestin2 pGEX-4T1-βarrestin1 C-terminus pGEX-4T1-βarrestin2 C-terminus pRK5-bGRK2 pRK5-bGRK3 pRK5-bGRK4 pRK5-hGRK5 pRK5-hGRK6 pRK5-hGRK26caax
Transgenic zebrafish to direct epicardial gene expression
Technology Duke inventors have generated a novel zebrafish model that allows researchers to study epicardial cells during embryonic heart development and myocardial regeneration. This zebrafish line is termed Tg(tcf21:CreER)pd42. Specifically, this transgenic model was created…
iPSC line to identify novel therapies for ARVC
Technology Duke inventors have developed a novel induced pluripotent stem cell (iPSC) line that contains a mutation that impacts the TAX1BP3 gene, which causes arrhythmogenic right ventricular cardiomyopathy/dysplasia (ARVC). Specifically, the iPSCs were derived from…
Hamster a1B-adrenergic receptor HeLa cell line
Technology Duke inventors have generated a human epithelial carcinoma (HeLa) cell line expressing the hamster α1B-adrenergic receptor.
Rat a1A-adrenergic receptor HeLa cell line
Technology Duke inventors have generated a human epithelial carcinoma (HeLa) cell line expressing the hamster α1B-adrenergic receptor.
Human B2-adrenergic receptor CHW cell line
Technology Duke inventors have generated a chinese hamster fibroblast cell line that expresses the human β2–adrenegic receptor.
An induced pluripotent stem cell model of Duchenne muscular dystrophy
Unmet Need Duchenne muscular dystrophy (DMD) is a rare genetic disease that causes the skeletal and heart muscles to weaken. Due to a mutation in dystrophin, an important protein involved in muscle structure, individuals with…
Cell line expressing chimeric Tie2 receptors
Technology Duke inventors have generated a cell line that expresses chimeric Tie2 receptors. Specifically, NIH 3T3 cells were infected with retroviruses containing a plasmid that encoded the extracellular and transmembrain domains of the c-fms receptor…
Methods and compositions to sense m6A RNA modifications using a genetically encoded sensor
Unmet Need Gene expression is highly regulated through the addition of chemical modifications to RNA molecules. One such modification is methylation of adenosine residues to form m6A, a modified nucleotide which is found in thousands…
A platform for high-throughput quantification of gap junction hemichannel docking
Unmet Need Gap junctions are transmembrane channels that facilitate for cell-cell communication. They play a crucial role in normal cellular physiology and their dysfunction or misregulation is associated with many human diseases. Gap junctions are…