Luciferase Immunoprecipitation System (LIPS) for Point-of-care Diagnosis of COVID-19 Antibodies

This technology includes a sensitive and specific method to rapidly detect antibodies in biofluids. This assay has been used for the detection of antibodies in blood, urine, and saliva. Until now, no one has used LIPS to detect clinically relevant antibodies to SARS-CoV-2 Nucleocapsid (N) or Spike (S) in saliva. Briefly, LIPS employs recombinantly synthesized target proteins or peptides (e.g., S and N proteins) tagged with light-emitting proteins as targets to be captured by host produced immunoglobulins. These immunoglobulins can be captured by protein A/G beads and immobilized.

Monoclonal Antibody Against Human Alpha-5 Integrin that Does Not Disrupt Adhesive Function

This technology includes a rat monoclonal antibody termed mAb11 was generated against the human alpha-5 integrin subunit and can provide immunological characterizations without disrupting integrin adhesive function. It permits characterization of its localization even if the receptor is bound to its fibronectin ligand. The antibody is commercially available from Millipore Sigma.

In-vivo System to Interrogate the Functions of Mucous Membranes and Identify Mucin/Glycan Mimetics and JAK/STAT Inhibitors for the Treatment of Diseases of the Oral Cavity and Digestive Tract

This technology includes a Drosophila mutant strain that can be used as an in vivo model for diseases of the oral cavity and digestive tract (Sjogren's syndrome, colitis, colon cancer, inflammatory bowel disease), where the mucous membrane is disrupted or non-functional. This mutant lacks a mucous membrane and displays epithelial cell damage, uncontrolled cell proliferation and the up-regulation of conserved signaling pathways (JAK/STAT).

Application of AAV44.9 Vector in Gene Therapy for the Inner Ear

This technology includes a novel AAV isolate (AAV44.9) to be used as gene therapy for the inner ear for the treatment of deafness. The ability of AAV vectors to transduce dividing and non-dividing cells, establish long-term transgene expression, and the lack of pathogenicity has made them attractive for use in gene therapy applications. Vectors based on new AAV isolates may have different host range and different immunological properties, thus allowing for more efficient transduction in certain cell types.

KCNN4 Knockout Mice for Mechanistic Research

This technology includes a transgenic allele for a mouse knockout model for the KCNN4 gene. Secretion of fluids from these salivary glands requires the coordination of multiple water and ion channel proteins. Notably, the majority of these channels have been shown to be up-regulated by increased calcium concentrations. The relevant calcium-activated potassium channels are split into the small, intermediate, and large conductance channels (called the SK, IK, and BK channels). The KCNN4 gene plays a part in the IK and BK channels.

Locally Delivered Alkaline Phosphatase for Treatment of Periodontal Disease

This technology includes a product for local delivery of alkaline phosphatase for the treatment of periodontal disease. Our laboratory has discovered that factors regulating phosphate metabolism and specifically the appropriate balance between phosphate (Pi) and pyrophosphate (PPi) at local sites are needed for formation (development), maintenance and regeneration of the tooth root surface (cementum), periodontal ligament (PDL) and surrounding alveolar bone, i.e., the periodontal apparatus.

Method To Generate Chondrocytes from Human Induced Pluripotent Stem Cells (hIPSCs) and their use in Repairing Human Injury and Degenerative Diseases

This technology includes a method for differentiating human induced pluripotent stem cells (hiPSCs) into stable chondrocytes, capable of producing cartilage, and their use in cartilage repair in human injury and degenerative diseases. In suspension culture, hiPSC aggregates demonstrate gene and protein expression patterns similar to articular cartilage.

Treatment of Periodontal Disease via ENPPI Inhibition

This technology focuses on enhancing cementum production, a key component in treating periodontal regression. The method involves inhibiting ectonucleotide pyrophosphatase phosphodiesterases (ENPP1), enzymes that play a significant role in mineralization processes. Pyrophosphate (PPi) is known to impede the growth of hydroxyapatite crystals, essential for mineralization. ENPP1 catalyzes the hydrolysis of ATP, generating PPi, which then hinders mineralization.

DLX3 Knockout Mice for the Study Mouse Models of Tooth, Hair, and Epidermal Defects

This technology includes K14creDLX3 conditional knockout (cKO) mice which will be used to study ectodermal dysplasia disorders such as Amelogenesis Imperfecta, and to study molecular mechanisms of DLX3 regulation in skin and ectodermal appendages. DLX3 is expressed in the epidermis, hair matrix cells in the hair follicle and in the mesenchymal and epithelial compartment of the tooth during embryonic development.