WATER, MEMBRANES & ENVIRONMENTAL SOLUTIONS

• 08‑029 → Carbon Nanotube Mediated Membrane Extraction
• 16‑033 → Reactive Electrochemical Membrane Filtration
• 21‑017 → Porous Composite Membrane for Solvent Extraction
• 22‑009 → System for Ultrapurification of Organic Solvent
• 22‑023 → Hollow Fiber Membrane Supported MOF‑Based Device
• 22‑013 → Electrified Membrane Flow‑Cell Reactor (Nitrate Reduction & Ammonia Production from Wastewater)
• 20‑010 → Ultrasound Device for Destruction of Organic Chemicals
• 20-010 → Coupled High/Low‑Frequency Ultrasound Systems for Remediation of Contaminated Solids
• 19‑014 → Fluidic Impedance Platform for In‑Situ Detection and Quantification of PFAS in Groundwater
• 16‑024→ Method and Device for Testing the Effectiveness of Magnetic Treatment of Feed Water for Reducing Mineral Scaling in Reverse Osmosis Processes

MEDICAL DEVICES, IMAGING & DIGITAL HEALTH

• 12‑034 → Non‑Invasive Glucose Monitoring Using Near‑Infrared Spectroscopy
• 16‑027 → Miniature Quantitative Optical Coherence Elastography (Fiber‑Optic Probe with Fabry–Perot Cavity)
• 20‑012 → Scan‑less Optically Computed OCT Using a Spatial Light Modulator
• 22‑004 → Optically Computed Phase Microscopy
• 21‑016 → Intelligent Surgical Marker
• 17‑027 → Exoskeleton with Admittance Control
• 22‑005 → System and Method for Quantification and Feedback of Eye Deviations
• 22‑022 → System to Visualize, Measure, and Track Skin Abnormalities
• 24‑029 → System and Method for Interior Anatomical Visualization of a Subject (Enhanced Imaging & Display)
• 15‑023 → Biocompatible and Implantable Optical Conduits
• 19-021 → Iontophoretic Microneedle Device
• 18‑027 → Toothbrush Suction Apparatus and Method
• 11‑054→ Method for Determining Acceptance of Progressive Addition Lenses (PALs)

DIAGNOSTICS, SENSORS & ANALYTICAL PLATFORMS

• 08‑009 → Dielectric Spectroscopy Assays for Screening of Ion Channel Ligands
• 17‑020 → Biomarker Detection and Self‑Separation of Serum during Capillary Flow
• 18‑005 → Microfluidic Biochip with Enhanced Sensitivity
• 17‑032 → Enhanced Sensitivity and Specificity for Point‑of‑Care (POC) Micro Biochip
• 20‑016 → Relative Quantitation Using Electrochemical Mass Spectrometry
• 21‑013 → Absolute Quantitation of Nitrosamines
• 22‑018 → Microelectrode‑Based Electrochemical Cell
• 21‑024 → In‑Vitro Contractile Force Indicator
• 15‑007 → Polydiacetylene and Polydiacetylene/ZnO Nanocomposite Sensors
• 18‑006 → Automated Addressable Microfluidic Technology (Minimally Disruptive Manipulation in Living Cultures)
• 23‑005 → Addressable Microfluidics Systems and Methods for In Vivo Applications
• 15‑024 → Microfluidic Diagnostic Assembly
• 08‑093→ Fluorophore Chelated Lanthanide Luminescent Probes with Improved Quantum Efficiency 

DRUG DELIVERY, EXCIPIENTS & BIOPHARMA MANUFACTURING

• 12‑045 → Systems and Methods for Superdisintegrant‑Based Composite Particles for Dispersion and Dissolution of Agents
• 12‑045 → Methods for Superdisintegrant‑Based Composite Particles for Dispersion and Dissolution of Active Pharmaceutical Agents
• 16‑022 → Dry Processed Surface Coated Engineering/Engineered Excipients
• 17‑047 → Polymeric Films Loaded with Uniformly Distributed Drug Particles
• 19‑020 → Continuous Production of Active Pharmaceutical Ingredients (11779859 & 12239943)
• 21‑009 → Targeted Nanoparticle for the Treatment of Traumatic Brain Injury and other CNS Diseases
• 22‑017 → Amino Alcohol Ionizable Lipids (two applications listed)
• 22‑020 → Powder Blend Processability Improvements via Minimal Surface Coating Agents
• 24‑014 → Method of Using Binary Coating Agents in Powder Coating (Enhanced Properties; Cohesive Powders)
• 21‑002 → Hydrophilic Functional Particles in the Delivery of Hydrophobic Drugs
• 18‑039 → Injectable Formulations of Anesthetics for Any Pathological Pain
• 23-008 → Gene Delivery Platform for the Prevention and Treatment of Hair Loss
• 23-014→Pyroptosis‑Triggering Lipid Nanoparticles
• 13‑013→ Growth Matrices for Stem Cell Propagation in vitro and in Tissue Regeneration

BIOMATERIALS & REGENERATIVE THERAPIES

• 12‑012 → Scaffold for Tissue Growth and Repair
• 16‑014 → System and Method for a Piezoelectric Collagen Scaffold
• 18‑030 → Injectable Self‑Assembling Antibacterial Peptide Hydrogels
• 17‑010 → Photoluminescent Hydrogel
• 18‑038 → Additive Manufacturing of Cell‑Laden Functional Hydrogel and Live Cell Constructs
• 18‑038 → Dual Printing Additive Manufacturing of 3D Scaffolds with Channel Diameters 100–500 µm
• 08‑018 → Electrospun Electroactive Polymers for Regenerative Medicine Applications

NJIT offers a diverse portfolio of innovative technologies and inventions arising from cutting‑edge faculty research. These technologies are available for licensing, startup formation, and industry collaboration.

Whether you are seeking a specific solution or exploring new R&D opportunities, NJIT partners with companies and organizations to translate research into real‑world impact.

If you don’t see exactly what you’re looking for, tell us—our portfolio is continually growing, and many innovations are available on a confidential or pre‑publication basis.

For specific requests or partnership inquiries: TECHTRANSFER@NJIT.EDU