<?xml version="1.0" encoding="utf-8"?><rss version="2.0"><channel><title>Latest technologies from New Jersey Institute of Technology</title><link>http://njit.technologypublisher.com</link><description>Be the first to know about the latest inventions and technologies available from New Jersey Institute of Technology</description><language>en-US</language><pubDate>Wed, 15 Jul 2026 13:27:21 GMT</pubDate><lastBuildDate>Wed, 08 Jul 2026 11:46:16 GMT</lastBuildDate><docs>http://blogs.law.harvard.edu/tech/rss</docs><webMaster>techtransfer@njit.edu</webMaster><copyright>Copyright 2026, New Jersey Institute of Technology</copyright><item><title>Additive Biomanufacturing of Cell Laden Hydrogels for Living Tissue Constructs</title><caseId>M18-038-01</caseId><link>http://njit.technologypublisher.com/technology/62067</link><description>Additive Biomanufacturing of Cell‑Laden Hydrogels for Living Tissue Constructs (Additive Manufacturing of Cell‑Laden Functional Hydrogel and Live Cell Constructs, Tech ID: 18‑038)

Technology Overview: This technology enables additive manufacturing of hydrogels containing living cells, allowing precise spatial control over both biological and structural features of 3D tissue constructs. This approach supports high cell viability while enabling fabrication of complex geometries with embedded functionality. This platform advances tissue engineering, regenerative medicine, and in‑vitro modeling b...</description><pubDate>Wed, 08 Jul 2026 11:46:16 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/62067</guid></item><item><title>Alamouti‑Ordered Sub‑Packet HARQ for MIMO</title><caseId>05-052</caseId><link>http://njit.technologypublisher.com/technology/60423</link><description>Method and apparatus for ordering retransmissions in an NxM MIMO system

Technology Overview: A MIMO HARQ method where a transmitter splits a coded stream into N sub-packets for N transmit antennas, while the receiver independently decodes across M receive antennas. Upon a NACK, the transmitter orders the next retransmission using an Alamouti‑based scheme, improving the likelihood of successful combining/decoding on subsequent attempts.

Industry Pain Point: Standard MIMO retransmissions may not optimally exploit space-time diversity across sub-packets, causing throughput loss under fading and...</description><pubDate>Fri, 13 Feb 2026 14:46:21 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60423</guid></item><item><title>Virtual MIMO Retransmission with Relays</title><caseId>06-035</caseId><link>http://njit.technologypublisher.com/technology/60422</link><description><![CDATA[Apparatus and Method for Collaborate Hybrid Automatic Repeat Request (HARQ) in Broadband Wireless Communication System Using Relay Station

Technology Overview: A collaborative Hybrid ARQ (HARQ) protocol in which a source and relay form a virtual multiple‑antenna group during retransmissions. The transmitter estimates distance to the relay, decides whether to invoke collaborative HARQ, and&mdash;upon a NACK&mdash;sends a coded retransmission jointly with the relay using multiple‑antenna signal processing to improve reliability and throughput.

Industry Pain Point: Conventional HARQ retransmiss...]]></description><pubDate>Fri, 13 Feb 2026 14:44:51 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60422</guid></item><item><title><![CDATA[Collaborative VM Pooling for SLA & Efficiency]]></title><caseId>16-006</caseId><link>http://njit.technologypublisher.com/technology/60421</link><description><![CDATA[Collaborative VM Pooling for SLA &amp; Efficiency (Virtual Machine Resource Utilization in a Data Center, Tech ID: 16‑006) 

Technology Overview: A resource‑management method that predicts application workloads, computes average service rates per VM pool, then forms collaborative sets of VMs drawn across pools to meet service‑level requirements&mdash;distributing incoming requests among selected VMs to raise utilization while controlling latency and cost. 

Industry Pain Point: Standard VM schedulers over‑ or under‑provision resources, ignoring cross‑pool collaboration&mdash;leading to SLA vio...]]></description><pubDate>Fri, 13 Feb 2026 14:41:35 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60421</guid></item><item><title>Non‑Volatile Memory Coding for Rewrite Without Erase</title><caseId>15-015</caseId><link>http://njit.technologypublisher.com/technology/60420</link><description><![CDATA[Asymmetric Error Correction &amp; Flash‑Memory Rewriting Using Polar Codes

Technology Overview: This technology develops non‑linear polar‑code schemes for asymmetric channels and informed‑encoder settings typical of flash memory, enabling error correction combined with constrained rewriting that can avoid costly block erasures. The constructions achieve capacity on asymmetric channels with polynomial complexity, improving practical deployability for memory controllers.

Industry Pain Point: NAND flash has asymmetric program/erase physics; conventional ECC does not natively support rewrite wit...]]></description><pubDate>Fri, 13 Feb 2026 14:33:46 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60420</guid></item><item><title>AI‑Driven Network Optimization Using Predictive Location Intelligence</title><caseId>23-010</caseId><link>http://njit.technologypublisher.com/technology/60419</link><description>Artificial Intelligence Automation to Improve Network Quality Based on Predicted Locations

Technology Overview: This technology applies artificial intelligence to predict user locations and proactively optimize network resources. By anticipating movement patterns and connectivity demand, the system dynamically adjusts network parameters to improve quality‑of‑service, reduce latency, and enhance user experience. The approach is particularly effective in dense urban and mobile environments.

Industry Pain Point: Network optimization is reactive, leading to congestion and degraded performance du...</description><pubDate>Fri, 13 Feb 2026 14:28:29 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60419</guid></item><item><title>Dynamic Route Optimization Engine for Real‑Time Traffic‑Aware Navigation</title><caseId>19-009</caseId><link>http://njit.technologypublisher.com/technology/60418</link><description>Methods for Computing Fastest Route on Road Networks with Dynamic Traffic Information

Technology Overview: This technology delivers real‑time route computation algorithms that dynamically adapt to changing traffic conditions. By continuously incorporating live and predicted traffic data, the system computes optimal routes with lower latency and improved accuracy compared to static navigation methods. The approach scales to large road networks and supports advanced mobility services.

Industry Pain Point: Conventional navigation systems lag behind real‑world traffic changes, reducing routing a...</description><pubDate>Fri, 13 Feb 2026 14:25:27 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60418</guid></item><item><title>Embedded Structural Health Monitoring System for Real‑Time Infrastructure Diagnostics</title><caseId>15-003</caseId><link>http://njit.technologypublisher.com/technology/60417</link><description>Structural Health Monitoring System and Associated Methods

Technology Overview: This technology provides an embedded structural health monitoring (SHM) system designed to continuously assess the integrity and condition of critical infrastructure. By integrating distributed sensing and intelligent data processing, the system detects structural changes such as stress, fatigue, or damage in real time. The platform supports predictive maintenance strategies, enabling operators to identify issues before failures occur and extending the operational lifespan of assets.

Industry Pain Point: Conventi...</description><pubDate>Fri, 13 Feb 2026 14:23:13 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60417</guid></item><item><title>Binary Colloidal Quantum Dot Platform for Tunable Optoelectronic Devices</title><caseId>21-022</caseId><link>http://njit.technologypublisher.com/technology/60416</link><description>Technology Overview: This technology introduces a binary colloidal quantum dot (QD) platform that enables tunable optical and electronic properties through controlled composition of distinct quantum dot species. The technology supports precise bandgap engineering and improved charge transport, making it suitable for advanced optoelectronic applications such as displays, photodetectors, and solar cells.

Industry Pain Point: Single‑component QD systems face limitations in tunability and device performance.

NJIT Solution: Binary QD combinations enable enhanced tunability and optoelectronic perf...</description><pubDate>Fri, 13 Feb 2026 14:21:30 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60416</guid></item><item><title>Single‑Crystal Colloidal Photonics for Infrared Bragg Diffraction</title><caseId>22-021</caseId><link>http://njit.technologypublisher.com/technology/60415</link><description>Method and Apparatus for Fabrication of Large Three‑Dimensional Single Colloidal Crystals for Bragg Diffraction of Infrared Light

Technology Overview: This technology enables large‑area, three‑dimensional single colloidal crystals with high structural order for infrared (IR) Bragg diffraction. The method overcomes domain boundaries and defects common in colloidal self‑assembly, producing monolithic photonic crystals with precise lattice control. The resulting materials support IR filtering, waveguiding, and sensing functions.

Industry Pain Point: Photonic crystal fabrication often yields sma...</description><pubDate>Fri, 13 Feb 2026 14:18:31 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60415</guid></item><item><title>Fiber‑Optic Sensing Platform for Detection of Pipeline Defects</title><caseId>20-031</caseId><link>http://njit.technologypublisher.com/technology/60414</link><description><![CDATA[Systems and Methods of Detecting Pipe Defects

Technology Overview: This technology uses fiber‑optic sensing and signal analysis to detect defects such as corrosion, cracks, or deformation in pipes. By exploiting changes in optical signals along distributed fibers, the system enables continuous, non‑destructive monitoring over long distances. It is suitable for water, oil &amp; gas, and industrial pipelines where early fault detection is critical.

Industry Pain Point: Traditional inspections are periodic, costly, and often miss early‑stage defects.
NJIT Solution: Continuous, distributed fiber...]]></description><pubDate>Fri, 13 Feb 2026 14:15:22 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60414</guid></item><item><title>Privacy‑Preserving Data Hiding for Secure, Invisible Information Embedding</title><caseId>20-030</caseId><link>http://njit.technologypublisher.com/technology/60413</link><description>Systems and Methods for Privacy‑Reserving Data Hiding

Technology Overview: This technology provides privacy‑preserving data hiding that embeds information in digital objects (e.g., images, meshes, signals) while safeguarding content confidentiality and user privacy. The method combines robust watermarking/steganography with privacy controls, enabling provenance, tamper detection, or metadata transport without exposing sensitive content. Designed for modern workflows, it supports streaming, cloud media, and distributed collaboration.

Industry Pain Point: Conventional watermarking leaks conten...</description><pubDate>Fri, 13 Feb 2026 14:12:38 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60413</guid></item><item><title>Indoor Place Prediction Platform for Context‑Aware Location Intelligence</title><caseId>23-011</caseId><link>http://njit.technologypublisher.com/technology/60412</link><description>Technology Overview: This technology provides an indoor place prediction system that infers user location and contextual place (e.g., room type or functional area) within indoor environments. By fusing signals such as device sensors, network data, and learned spatial patterns, the platform delivers accurate, privacy‑aware indoor localization without requiring extensive new infrastructure. The approach supports real‑time inference and adapts to changing indoor layouts, enabling smarter experiences across campuses, enterprise buildings, and public venues.

Industry Pain Point: GPS is unreliable ...</description><pubDate>Fri, 13 Feb 2026 14:08:51 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60412</guid></item><item><title>Channel‑Based Identification Method for Secure Communications and Authentication</title><caseId>21-011</caseId><link>http://njit.technologypublisher.com/technology/60411</link><description>Method and System for Identification via Channels and Computer Program Product

Technology Overview: This technology presents a channel‑based identification and authentication method that exploits physical or communication channel characteristics as unique identifiers. By leveraging inherent channel properties, the system enables secure identification without relying solely on traditional cryptographic keys. This approach enhances security and resilience in wireless and networked systems.

Industry Pain Point: Conventional authentication systems are vulnerable to key compromise and spoofing at...</description><pubDate>Fri, 13 Feb 2026 14:03:34 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60411</guid></item><item><title>Distributed Consensus Architecture for Reliable Communications Networks</title><caseId>20-017</caseId><link>http://njit.technologypublisher.com/technology/60410</link><description>Systems and Methods for Establishing Consensus in Distributed Communications

Technology Overview: This technology provides systems and methods for establishing consensus in distributed communication networks, enabling multiple nodes to reach agreement despite delays, faults, or adversarial behavior. The architecture improves reliability, throughput, and fault tolerance in decentralized environments such as wireless networks, distributed databases, and edge computing systems. The approach is adaptable to different network topologies and operates efficiently under dynamic conditions.

Industry ...</description><pubDate>Fri, 13 Feb 2026 14:00:45 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60410</guid></item><item><title>AI‑Driven Decoding of Graph‑Based Channel Codes via Reinforcement Learning</title><caseId>21-021</caseId><link>http://njit.technologypublisher.com/technology/60409</link><description>Systems and Methods for Decoding of Graph‑Based Channel Codes via Reinforcement Learning

Technology Overview: This technology applies reinforcement learning (RL) to decode graph‑based channel codes used in modern digital communication systems. By learning optimal decoding strategies dynamically, the system improves error‑correction performance and adaptability compared to fixed‑algorithm decoders. This AI‑enabled approach is particularly valuable for next‑generation wireless and data communication systems operating under variable channel conditions.

Industry Pain Point: Conventional decoding...</description><pubDate>Fri, 13 Feb 2026 13:57:24 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60409</guid></item><item><title>Transformer‑Based Surrogate Modeling for Fast Electric Circuit Performance Prediction</title><caseId>24-019</caseId><link>http://njit.technologypublisher.com/technology/60408</link><description>Transformer‑Based Surrogate Model Module for Electric Circuit Performance Modeling

Technology Overview: This technology applies transformer‑based machine learning models as surrogate predictors for electric circuit performance. By learning complex relationships between circuit configurations and performance metrics, the system enables rapid, near‑instant prediction without computationally expensive simulations. This approach significantly accelerates design iteration and optimization in electronic design automation workflows.

Industry Pain Point: Physics‑based circuit simulations are computa...</description><pubDate>Fri, 13 Feb 2026 13:54:31 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60408</guid></item><item><title>AI‑Driven Automation Platform for Electronic Circuit Design</title><caseId>23-006</caseId><link>http://njit.technologypublisher.com/technology/60407</link><description>Algorithmic Circuit Design Automation

Technology Overview: This technology introduces an algorithmic automation framework for electronic circuit design, leveraging advanced computational methods to accelerate and optimize circuit synthesis and layout. The platform reduces human‑intensive trial‑and‑error by autonomously generating and refining circuit designs based on performance objectives and constraints. It is well suited for increasingly complex integrated circuits where traditional design workflows struggle with scale, speed, and cost.

Industry Pain Point: Manual circuit design is time‑c...</description><pubDate>Fri, 13 Feb 2026 13:51:46 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60407</guid></item><item><title>Neural Accelerated Vision for Real Time, Low Power Image Processing</title><caseId>M23-019-01</caseId><link>http://njit.technologypublisher.com/technology/60406</link><description><![CDATA[Neural‑Accelerated Vision for Real‑Time, Low‑Power Image Processing (Neural Network Acceleration of Image Processing, Tech ID: 23‑019)

Technology Overview: This NJIT technology accelerates image‑processing workloads using neural network&ndash;based hardware/algorithm co‑design, enabling real‑time performance at the edge. By mapping common vision operators (e.g., filtering, feature extraction, segmentation) to learned neural primitives and accelerator‑friendly pipelines, the system reduces latency and power draw while preserving accuracy. It is ideal for embedded, battery‑powered, or thermally...]]></description><pubDate>Fri, 13 Feb 2026 13:49:31 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60406</guid></item><item><title>Neural‑Network‑Accelerated Image Processing for High‑Performance Vision Systems</title><caseId>23-019</caseId><link>http://njit.technologypublisher.com/technology/60405</link><description><![CDATA[Technology Overview: This technology accelerates image‑processing pipelines using neural network&ndash;based hardware and algorithmic optimization. The approach enables faster, more energy‑efficient execution of common vision tasks such as filtering, feature extraction, and classification. By offloading computation to neural network accelerators, the system supports real‑time performance in resource‑constrained environments.

Industry Pain Point: Conventional image‑processing pipelines are computationally heavy and energy‑intensive.
NJIT Solution: Neural‑network acceleration enables real‑time,...]]></description><pubDate>Fri, 13 Feb 2026 13:46:38 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60405</guid></item><item><title>Non‑Volatile Processing‑In‑Sensor Accelerator for AI‑Enabled Imaging Systems</title><caseId>23-013</caseId><link>http://njit.technologypublisher.com/technology/60404</link><description>Technology Overview: This technology integrates non‑volatile memory directly into image sensors, enabling processing‑in‑sensor (PIS) acceleration for AI‑driven imaging tasks. By performing computation at the sensor level, the system dramatically reduces data movement, latency, and energy consumption. The architecture is well suited for edge AI, smart cameras, and autonomous systems.

Industry Pain Point: Conventional imaging pipelines waste energy and time transferring raw data to external processors.

NJIT Solution: Processing‑in‑sensor architecture enables low‑latency, energy‑efficient AI co...</description><pubDate>Fri, 13 Feb 2026 13:44:03 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60404</guid></item><item><title>Resistive Switching RRAM Architecture for Next‑Generation Non‑Volatile Memory</title><caseId>23-003</caseId><link>http://njit.technologypublisher.com/technology/60403</link><description>Resistive Switching in a RRAM Device

Technology Overview: This technology introduces a resistive random‑access memory (RRAM) device architecture based on controlled resistive switching mechanisms. The system enables stable, repeatable switching between resistance states, supporting high‑density, low‑power non‑volatile memory. The design is compatible with CMOS fabrication processes and is applicable to memory, neuromorphic computing, and in‑memory processing architectures.

Industry Pain Point: Conventional non‑volatile memory technologies face scaling, power, and endurance limitations.

NJIT...</description><pubDate>Fri, 13 Feb 2026 13:40:58 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60403</guid></item><item><title>High‑Speed Wireless Communications Using Reflected Laser Light</title><caseId>23-007</caseId><link>http://njit.technologypublisher.com/technology/60402</link><description>System and Method of High‑Speed Wireless Communications Using Reflected Laser Light

Technology Overview: This technology enables high‑speed wireless data transmission using reflected laser light, offering an alternative to traditional RF‑based communications. The system modulates data onto a laser beam and recovers information from reflected optical signals, enabling secure, high‑bandwidth communication without direct line‑of‑sight receivers. This approach reduces spectrum congestion and is inherently resistant to RF interference, making it suitable for dense or sensitive environments.

Indus...</description><pubDate>Fri, 13 Feb 2026 13:36:46 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60402</guid></item><item><title>Micro Jet Enhanced Nanopowder Processing</title><caseId>M06-057-02</caseId><link>http://njit.technologypublisher.com/technology/60401</link><description><![CDATA[Micro‑Jet Enhanced Nanopowder Processing (Fluidized Bed Systems &amp; Methods Including Micro‑Jet Flow, Tech ID: 06‑057) 

Technology Overview: An earlier issued family member describing the same micro‑jet‑assisted fluidization approach: a standard upflow gas plus a downward micro‑jet near the distributor to deagglomerate nano‑scale powders and maintain uniform fluidization across the column. This patent anchors the family&rsquo;s core claims and design variants for nozzle placement and gas‑flow configurations. 

Industry Pain Point: Nanopowders often fail to fluidize uniformly, hindering cons...]]></description><pubDate>Fri, 13 Feb 2026 13:24:21 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60401</guid></item><item><title>Opposing Jet Assisted Nanopowder Fluidization</title><caseId>M06-057-01</caseId><link>http://njit.technologypublisher.com/technology/60400</link><description><![CDATA[Opposing‑Jet Assisted Nanopowder Fluidization (Fluidized Bed Systems &amp; Methods Including Micro‑Jet Flow, Tech ID: 06‑057) 

Technology Overview: An enhanced fluidized‑bed architecture that supplements the usual upward fluidizing gas with a strategically positioned opposing (downward) micro‑jet, creating localized turbulence and shear to aerate agglomerates and break up nano‑clusters. The opposing jet near the gas distributor enables full‑column fluidization and vigorous powder circulation&mdash;improving mixing and processing of otherwise cohesive nanopowders. 

Industry Pain Point: Conven...]]></description><pubDate>Fri, 13 Feb 2026 13:20:41 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60400</guid></item><item><title>Low Residue Combustible MICs</title><caseId>M12-032-01</caseId><link>http://njit.technologypublisher.com/technology/60399</link><description><![CDATA[Low‑Residue Combustible MICs (Foamed Celluloid Mortar Propellant Increment Containers, Tech ID: 12‑032) 

Technology Overview: An economical, low‑residue mortar increment container (MIC) constructed from foamed celluloid (&asymp;50&ndash;84% nitrocellulose, &asymp;15&ndash;50% camphor; tunable with energetic plasticizers). The MIC design aims to burn cleanly and resist moisture‑related performance loss, offering improved manufacturing and ballistic consistency relative to felt‑fiber MICs. 

Industry Pain Point: Legacy felt MICs require multi‑step processing and can absorb moisture, reducing pr...]]></description><pubDate>Fri, 13 Feb 2026 13:15:53 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60399</guid></item><item><title>High‑Uniformity Functional Films</title><caseId>13-052</caseId><link>http://njit.technologypublisher.com/technology/60398</link><description>System and Method for Fabrication of Uniform Polymer Films Containing Nano and Micro Particles Via Continuous Drying Process

Technology Overview: A scalable system and method to fabricate highly uniform polymer films embedded with nano‑ and microparticles (e.g., actives, pigments, fillers) using a continuous drying process. The approach enables controlled particle distribution and film microstructure at production speeds suitable for industrial roll‑to‑roll lines, supporting applications from pharma oral thin films to functional coatings.

Industry Pain Point: Conventional batch casting and d...</description><pubDate>Fri, 13 Feb 2026 13:04:50 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60398</guid></item><item><title>Advanced Protective Materials for High‑Performance Protective Wear</title><caseId>22-016</caseId><link>http://njit.technologypublisher.com/technology/60397</link><description>Protective Material and Associated Protective Wear

Technology Overview: This technology introduces advanced protective materials engineered to provide enhanced protection while maintaining flexibility and wearability. The material system is designed to mitigate mechanical, thermal, or chemical hazards depending on configuration, enabling next‑generation protective clothing and equipment. The approach supports integration into wearable formats without compromising comfort or mobility.

Industry Pain Point: Existing protective wear often trades off protection for comfort and mobility.

NJIT Sol...</description><pubDate>Fri, 13 Feb 2026 12:55:42 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60397</guid></item><item><title>Spherical Composite Powder for Enhanced Reactivity and Material Performance</title><caseId>19-005</caseId><link>http://njit.technologypublisher.com/technology/60395</link><description>Technology Overview: This technology provides a method for producing spherical composite powders with tightly controlled morphology and internal structure. The spherical geometry improves flowability, packing density, and reactivity compared to irregular powders. By combining multiple material components within a single spherical particle, the technology enables tailored thermal, mechanical, or energetic performance. It is particularly well suited for additive manufacturing, energetic materials, and advanced powder metallurgy.

Industry Pain Point: Irregular powder morphologies limit processab...</description><pubDate>Fri, 13 Feb 2026 12:51:08 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60395</guid></item><item><title>Molecular‑Like Hierarchical Self‑Assembly Platform for Advanced Particle Monolayers</title><caseId>14-011</caseId><link>http://njit.technologypublisher.com/technology/60394</link><description>System and Method for Molecular‑Like Hierarchical Self‑Assembly of Monolayers of Mixtures of Particles

Technology Overview This technology enables hierarchical self‑assembly of particle monolayers that behave in a molecular‑like fashion despite being composed of micro‑ or nano‑scale particles. The system precisely organizes heterogeneous particle mixtures into ordered monolayers with controlled spatial arrangements. This approach bridges the gap between molecular self‑assembly and colloidal manufacturing, allowing engineered interfaces with tunable optical, electrical, or chemical properties....</description><pubDate>Fri, 13 Feb 2026 12:47:02 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60394</guid></item><item><title>Energy Packet Switching Architecture for Software‑Defined Power Networks</title><caseId>18-034</caseId><link>http://njit.technologypublisher.com/technology/60389</link><description><![CDATA[Energy Packet Switches

Technology Overview: This NJIT technology introduces energy packet switches that discretize electrical power into addressable packets and route them dynamically across a network. Analogous to data packet routing in the internet, the system enables fine‑grained control over energy flow, timing, and prioritization. This architecture supports distributed energy resources, storage integration, and dynamic load management&mdash;key requirements for next‑generation smart grids, data centers, and industrial energy systems.

Industry Pain Point: Traditional power distribution l...]]></description><pubDate>Fri, 13 Feb 2026 12:23:50 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60389</guid></item><item><title>High‑Oxidation‑State Periodate Battery for High‑Energy Density Storage</title><caseId>18-032</caseId><link>http://njit.technologypublisher.com/technology/60386</link><description>High Oxidation State Periodate Battery

Technology Overview: This technology introduces a periodate‑based battery chemistry that leverages high oxidation state electroactive species to achieve increased energy density. The battery design supports high theoretical capacity and is adaptable to non‑lithium‑based energy storage architectures. This approach offers potential advantages in cost, resource availability, and safety for applications requiring compact, high‑energy power sources.

Industry Pain Point: Conventional battery chemistries face cost, safety, and resource‑supply constraints.

NJI...</description><pubDate>Fri, 13 Feb 2026 12:11:40 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60386</guid></item><item><title>Benchtop RO Scaling Evaluation Platform</title><caseId>16-024</caseId><link>http://njit.technologypublisher.com/technology/60385</link><description><![CDATA[Method and Device for Testing the Effectiveness of Magnetic Treatment of Feed Water for Reducing Mineral Scaling in Reverse Osmosis Processes

Technology Overview: A dual‑branch benchtop flow setup that quantifies the effectiveness of magnetic treatment on RO feed water under controlled supersaturation. Both branches run at identical flow and transmembrane pressure through RO membranes, but only one stream is exposed to a magnetic field&mdash;enabling direct, statistically robust comparisons of scale deposition.

Industry Pain Point: Utilities and industrial users face mineral scaling that deg...]]></description><pubDate>Fri, 13 Feb 2026 12:09:02 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60385</guid></item><item><title>In‑Situ Fluidic Impedance Sensing Technology for Real‑Time PFAS Groundwater Monitoring</title><caseId>19-014</caseId><link>http://njit.technologypublisher.com/technology/60383</link><description><![CDATA[Fluidic Impedance Platform for In‑Situ Detection and Quantification of PFAS in Groundwater

Technology Overview: This NJIT technology introduces a fluidic impedance&ndash;based sensing platform for the in‑situ detection and quantification of per‑ and polyfluoroalkyl substances (PFAS) in groundwater. The system integrates microfluidic channels with impedance spectroscopy to measure PFAS‑induced changes in electrical properties directly within environmental water matrices. By enabling real‑time, on‑site monitoring without the need for extensive sample collection or laboratory analysis, the platf...]]></description><pubDate>Fri, 13 Feb 2026 12:06:51 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60383</guid></item><item><title>Ultrasonic Destruction Platform for Remediation of Organic Chemicals</title><caseId>M20-010-01</caseId><link>http://njit.technologypublisher.com/technology/60382</link><description>Ultrasonic Destruction Platform for Remediation of Organic Chemicals (Ultrasound Device for Destruction of Organic Chemicals, Tech ID: 20‑010)

Technology Overview: This technology utilizes high‑intensity ultrasonic energy to destruct organic contaminants in water, soils, and industrial waste streams. The system induces cavitation phenomena that generate localized high temperatures and pressures, breaking down complex organic molecules into less harmful byproducts. The platform offers a non‑chemical, scalable approach to environmental remediation and waste treatment.

Industry Pain Point: Many...</description><pubDate>Fri, 13 Feb 2026 12:04:58 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60382</guid></item><item><title>Dual‑Frequency Ultrasound Platform for Rapid Remediation of Contaminated Solids</title><caseId>20-010</caseId><link>http://njit.technologypublisher.com/technology/60381</link><description>Coupled High and Low‑Frequency Ultrasonic Systems and Methods for Remediation of Contaminated Solids

Technology Overview: This NJIT technology couples low‑frequency (LF) bulk agitation with high‑frequency (HF) cavitation to accelerate desorption and degradation of contaminants from soils, sludge, and solid matrices. LF loosens and transports contaminants; HF generates localized cavitation to fragment, oxidize, or detach persistent pollutants, shortening treatment time and reducing chemical use.

Industry Pain Point: Conventional remediation of solids is slow, chemical‑intensive, and often inc...</description><pubDate>Fri, 13 Feb 2026 12:02:12 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60381</guid></item><item><title>Electrified Membrane Flow‑Cell Reactor for Nitrate Removal and Green Ammonia Production</title><caseId>22-013</caseId><link>http://njit.technologypublisher.com/technology/60380</link><description>Electrified Membrane Flow‑Cell Reactor for Concurrent Nitrate Reduction and Ammonia Production from Wastewater

Technology Overview: This technology introduces an electrified membrane flow‑cell reactor that simultaneously removes nitrate from wastewater and converts it into ammonia. By integrating electrochemical reduction with membrane‑based separation, the system enables selective nitrate conversion while capturing ammonia as a valuable product. The platform supports energy‑efficient operation and aligns with circular‑economy approaches by transforming a regulated contaminant into a useful c...</description><pubDate>Fri, 13 Feb 2026 12:00:16 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60380</guid></item><item><title>Hollow‑Fiber MOF‑Integrated Platform for Advanced Gas and Component Separation</title><caseId>22-023</caseId><link>http://njit.technologypublisher.com/technology/60379</link><description>Hollow Fiber Membrane Supported Metal Organic Framework (MOF) Based Device

Technology Overview: This technology integrates metal‑organic frameworks (MOFs) within hollow‑fiber membrane structures to enable high‑performance separation of gases or chemical species. The MOF‑supported architecture enhances selectivity and permeability while maintaining mechanical stability. This hybrid platform offers tunability through MOF selection and is suitable for challenging separation problems where conventional membranes fall short.

Industry Pain Point: Traditional membranes lack selectivity and efficien...</description><pubDate>Fri, 13 Feb 2026 11:58:18 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60379</guid></item><item><title>Porous Composite Membrane Platform for High‑Efficiency Solvent Extraction</title><caseId>21-017</caseId><link>http://njit.technologypublisher.com/technology/60376</link><description>Technology Overview: This technology introduces a porous composite membrane engineered for efficient solvent extraction processes. The membrane architecture enhances mass transfer while maintaining selectivity and mechanical stability. The system is applicable to chemical separations, environmental remediation, and solvent recovery applications, offering improved efficiency over conventional extraction techniques.

Industry Pain Point: Traditional solvent extraction processes are energy‑intensive and inefficient for low‑concentration targets.

NJIT Solution: This membrane enables high‑efficien...</description><pubDate>Fri, 13 Feb 2026 11:50:42 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60376</guid></item><item><title>Reactive Electrochemical Membrane Filtration for Advanced Water Treatment</title><caseId>16-033</caseId><link>http://njit.technologypublisher.com/technology/60375</link><description>Technology Overview: This technology integrates electrochemical reactions with membrane filtration to enable simultaneous separation and degradation of contaminants in water and wastewater streams. The membrane acts both as a physical barrier and an electrochemically active surface, allowing targeted reactions that degrade or transform pollutants during filtration. This dual‑function design improves treatment efficiency while reducing fouling and chemical consumption compared to conventional systems.

Industry Pain Point: Conventional water treatment requires multiple unit operations and chemi...</description><pubDate>Fri, 13 Feb 2026 11:48:04 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60375</guid></item><item><title>Iontophoretic Microneedle Patch for Precise, Painless Transdermal Delivery</title><caseId>19-021</caseId><link>http://njit.technologypublisher.com/technology/60374</link><description>Iontophoretic Microneedle Device

Technology Overview: This technology integrates microneedle arrays with iontophoresis to achieve precise, minimally invasive transdermal drug delivery. The microneedles create micro‑channels in the stratum corneum, while controlled electric fields drive charged therapeutics across the skin at programmable rates. The platform supports small molecules, peptides, and vaccines, enabling clinic‑grade dosing without hypodermic needles.

Industry Pain Point: Oral and injectable routes face low bioavailability, pain, and adherence challenges.
NJIT Solution: Painless, ...</description><pubDate>Fri, 13 Feb 2026 11:33:56 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60374</guid></item><item><title><![CDATA[Inside‑Out Imaging: Enhanced Interior Anatomical Visualization & Guidance]]></title><caseId>24-029</caseId><link>http://njit.technologypublisher.com/technology/60373</link><description><![CDATA[System and Method for Interior Anatomical Visualization of a Subject

Technology Overview: This technology delivers an enhanced imaging and display system that fuses multi‑modal inputs to visualize interior anatomy&mdash;e.g., wound beds, subcutaneous structures&mdash;and present real‑time identification, analysis, and treatment options. The workflow augments clinician perception with computational overlays to support faster, more accurate decisions in emergency, surgical, and point‑of‑care settings.

Industry Pain Point: Clinicians lack integrated, real‑time tools that connect imaging, analyt...]]></description><pubDate>Fri, 13 Feb 2026 11:27:38 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60373</guid></item><item><title>Digital Platform to Visualize, Measure, and Track Skin Abnormalities</title><caseId>22-022</caseId><link>http://njit.technologypublisher.com/technology/60372</link><description>System to Visualize, Measure, and Track Skin Abnormalities

Technology Overview: This technology delivers a digital imaging and analytics platform for visualization, measurement, and longitudinal tracking of skin abnormalities. By combining imaging capture with computational analysis, the system enables objective monitoring of lesion size, color, and morphology over time. It supports remote assessment and teledermatology workflows, improving early detection and ongoing patient monitoring.

Industry Pain Point: Traditional skin assessments rely on subjective visual inspection and lack reliable ...</description><pubDate>Fri, 13 Feb 2026 11:24:15 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60372</guid></item><item><title>Digital Quantification and Biofeedback Platform for Eye Deviation Assessment</title><caseId>22-005</caseId><link>http://njit.technologypublisher.com/technology/60371</link><description>System and Method for Quantification and Feedback of Eye Deviations

Technology Overview: This technology provides a digital system for quantitative measurement and feedback of eye deviations, enabling precise assessment of ocular alignment and movement. Using computational analysis and visual feedback, the platform delivers objective metrics that support clinical decision‑making and therapy monitoring. The system is designed for repeatable, user‑friendly operation, making it suitable for clinical, rehabilitation, and research environments.

Industry Pain Point: Current methods for assessing e...</description><pubDate>Fri, 13 Feb 2026 11:21:06 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60371</guid></item><item><title>Intelligent Surgical Marker for Real‑Time Intraoperative Guidance</title><caseId>21-016</caseId><link>http://njit.technologypublisher.com/technology/60370</link><description>Technology Overview: This technology introduces an intelligent surgical marker that enhances intraoperative visualization and surgical precision. The marker integrates optical or imaging‑detectable features that enable real‑time tracking during surgical procedures. It assists surgeons in accurately identifying anatomical landmarks or surgical targets, improving outcomes and reducing procedural variability.

Industry Pain Point: Existing surgical markers provide limited intraoperative feedback and are prone to placement error.

NJIT Solution: This marker provides real‑time, detectable guidance,...</description><pubDate>Fri, 13 Feb 2026 11:15:00 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60370</guid></item><item><title>Optically Computed Phase Microscopy for High‑Contrast, Label‑Free Imaging</title><caseId>22-004</caseId><link>http://njit.technologypublisher.com/technology/60369</link><description>Technology Overview: This technology enables optically computed phase microscopy, allowing high‑contrast, quantitative imaging of transparent samples without fluorescent labels. By computationally extracting phase information directly from optical signals, the system reveals structural and morphological details that are otherwise difficult to visualize using conventional bright‑field microscopy. The approach supports real‑time imaging with reduced hardware complexity, making it attractive for both research and clinical diagnostic settings.

Industry Pain Point: Traditional phase‑contrast imagi...</description><pubDate>Fri, 13 Feb 2026 11:11:09 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60369</guid></item><item><title>Scan‑less Optically Computed OCT for High‑Speed, High‑Resolution Imaging</title><caseId>20-012</caseId><link>http://njit.technologypublisher.com/technology/60368</link><description>Scan‑less Optically Computed Optical Coherence Tomography Using a Spatial Light Modulator

Technology Overview: This technology enables scan‑less optical coherence tomography (OCT) by using a spatial light modulator to perform optically computed imaging. The approach eliminates mechanical beam scanning, enabling faster image acquisition, reduced system complexity, and improved reliability. High‑resolution depth‑resolved images can be captured in real time, making the technology attractive for clinical diagnostics and industrial inspection where speed and stability are critical.

Industry Pain ...</description><pubDate>Fri, 13 Feb 2026 11:07:04 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60368</guid></item><item><title><![CDATA[Time‑Resolved Biosensing Labels & Kits]]></title><caseId>08-093</caseId><link>http://njit.technologypublisher.com/technology/60366</link><description><![CDATA[Time‑Resolved Biosensing Labels &amp; Kits (Fluorophore Chelated Lanthanide Luminescent Probes with Improved Quantum Efficiency, Tech ID: 08‑093) 

Technology Overview: A class of lanthanide‑chelate fluorescent probes that integrate a tailored organic fluorophore (antenna) with a chelated lanthanide ion to achieve enhanced quantum efficiency for ultrasensitive detection of biomolecules. The portfolio also covers synthetic methods, macromolecular conjugates, and assay kits for life‑science detection workflows. 

Industry Pain Point: Standard organic dyes suffer from short lifetimes and backgrou...]]></description><pubDate>Fri, 13 Feb 2026 10:58:26 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60366</guid></item><item><title>Point‑of‑Care Visual Biosensor Chip</title><caseId>15-024</caseId><link>http://njit.technologypublisher.com/technology/60365</link><description><![CDATA[Microfluidic Diagnostic Assembly

Technology Overview: This NJIT technology is a consumable, chip‑based microfluidic diagnostic assembly designed for rapid, point‑of‑screening detection of human diseases and pathogens. The thumb‑sized device integrates continuous‑flow micro/nanofluidic channels with antibody immunocomplex designs that yield a direct &ldquo;all‑or‑none&rdquo; visual readout&mdash;eliminating external readers for many screening scenarios. The assembly is optimized for straightforward use, portability, and manufacturability in population‑scale screening.

Industry Pain Point: Man...]]></description><pubDate>Fri, 13 Feb 2026 10:55:54 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60365</guid></item><item><title>Addressable In‑Vivo Microfluidic Platform for Targeted Biological Manipulation</title><caseId>23-005</caseId><link>http://njit.technologypublisher.com/technology/60364</link><description>Addressable Microfluidics Systems and Methods for In Vivo Applications

Technology Overview: This technology introduces addressable microfluidic systems designed for in‑vivo applications, enabling precise, localized delivery or removal of fluids within living organisms. The platform supports targeted manipulation without disturbing surrounding tissue, allowing dynamic studies of biological systems directly in vivo. This capability is critical for advanced therapeutic delivery, localized diagnostics, and controlled biological experimentation.

Industry Pain Point: Current in‑vivo delivery metho...</description><pubDate>Fri, 13 Feb 2026 10:52:55 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60364</guid></item><item><title>In‑Vitro Contractile Force Sensing Platform for Quantitative Tissue Mechanics</title><caseId>21-024</caseId><link>http://njit.technologypublisher.com/technology/60362</link><description>In‑Vitro Contractile Force Indicator

Technology Overview: This technology provides an in‑vitro contractile force indicator that enables quantitative measurement of cellular and tissue‑level mechanical forces. The platform converts contractile activity into measurable signals, allowing researchers to monitor functional performance of engineered tissues or cell cultures in real time. The system is particularly useful for evaluating muscle, cardiac, and cytoskeletal behavior under physiological or pharmacological conditions.

Industry Pain Point: Existing in‑vitro assays inadequately capture mec...</description><pubDate>Fri, 13 Feb 2026 10:42:04 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60362</guid></item><item><title>Microelectrode Electrochemical Cell for Fast, Precise Reaction Contro</title><caseId>22-018</caseId><link>http://njit.technologypublisher.com/technology/60361</link><description>Microelectrode‑Based Electrochemical Cell

Technology Overview: This technology features a microelectrode‑based electrochemical cell that enhances mass transport, kinetics, and signal fidelity. The architecture reduces ohmic losses and diffusion limitations, enabling rapid response and tighter control of electrochemical reactions. The platform is adaptable to sensing, electrosynthesis, and energy‑conversion use cases where precision and efficiency are critical.

Industry Pain Point: Conventional cells struggle with sluggish transport and poor control at small scales.
NJIT Solution: Microelectr...</description><pubDate>Fri, 13 Feb 2026 10:37:02 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60361</guid></item><item><title>Ultra‑Sensitive Analytical Platform for Absolute Quantitation of Nitrosamines</title><caseId>21-013</caseId><link>http://njit.technologypublisher.com/technology/60360</link><description>Absolute Quantitation of Nitrosamines

Technology Overview: This technology enables absolute quantitation of nitrosamines at ultra‑trace levels using advanced analytical techniques. The platform addresses a critical regulatory and safety challenge in pharmaceutical and chemical manufacturing, where nitrosamine impurities must be detected and controlled at parts‑per‑billion or lower. The method improves accuracy, repeatability, and regulatory compliance.

Industry Pain Point: Existing analytical methods struggle with reliable quantitation of trace nitrosamines under evolving regulatory standard...</description><pubDate>Fri, 13 Feb 2026 10:30:21 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60360</guid></item><item><title>High‑Sensitivity Microfluidic Biochip for Advanced Diagnostic Detection</title><caseId>18-005</caseId><link>http://njit.technologypublisher.com/technology/60358</link><description><![CDATA[Microfluidic Biochip with Enhanced Sensitivity

Technology Overview: This technology is a microfluidic biochip engineered for enhanced analytical sensitivity in biochemical and diagnostic applications. The device integrates optimized microchannel geometries and surface functionalization to increase target&ndash;analyte interactions while minimizing sample volumes. Its design enables precise fluid control, rapid assay times, and improved signal‑to‑noise ratios compared to conventional lab‑on‑a‑chip systems. The platform is adaptable to a wide range of biomarkers and detection modalities, making...]]></description><pubDate>Fri, 13 Feb 2026 09:44:06 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60358</guid></item><item><title>Chitosan–FGF Matrices for Stem Cell Culture</title><caseId>13-013</caseId><link>http://njit.technologypublisher.com/technology/60357</link><description>Growth Matrices for Stem Cell Propagation in vitro and in Tissue Regeneration

Technology Overview: A family of biomaterial growth matrices (e.g., chitosan‑based systems with FGF and defined components) that support robust in‑vitro stem cell propagation and promote tissue regeneration. The matrices are engineered to optimize growth factor presentation and microenvironmental cues for enhanced cell expansion and potential lineage‑specific outcomes.

Industry Pain Point: Maintaining stem cell potency and scalability while reducing batch‑to‑batch variability remains challenging with conventional s...</description><pubDate>Fri, 13 Feb 2026 09:31:41 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60357</guid></item><item><title>Pyroptosis‑Triggering Lipid Nanoparticles for Targeted Immunogenic Cell Death</title><caseId>23-014</caseId><link>http://njit.technologypublisher.com/technology/60356</link><description>Technology Overview: This technology introduces lipid nanoparticle (LNP) formulations engineered to trigger pyroptosis, an immunogenic form of programmed cell death. By delivering payloads that selectively activate pyroptotic pathways, the platform enables localized cell destruction while stimulating innate immune responses. The technology is adaptable to cancer immunotherapy, inflammatory disease modulation, and combination therapies with checkpoint inhibitors or biologics.

Industry Pain Point: Many cancer therapies induce non‑immunogenic cell death, limiting durable therapeutic response.

N...</description><pubDate>Fri, 13 Feb 2026 09:27:59 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60356</guid></item><item><title>Gene Delivery Platform for the Prevention and Treatment of Hair Loss</title><caseId>23-008</caseId><link>http://njit.technologypublisher.com/technology/60355</link><description>Gene Delivery for Prevention and Treatment of Baldness

Technology Overview: This technology provides a gene delivery platform targeting hair follicles to address hair loss conditions such as androgenetic alopecia. The system enables localized delivery of genetic material that modulates biological pathways associated with hair growth and follicle regeneration. By targeting the root biological causes of hair loss, this approach offers a potential long‑term alternative to topical or pharmaceutical treatments.

Industry Pain Point: Current hair loss treatments provide limited efficacy and require...</description><pubDate>Fri, 13 Feb 2026 09:19:48 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60355</guid></item><item><title>Hydrophilic Functional Particle Platform for Enhanced Delivery of Hydrophobic Drugs</title><caseId>21-002</caseId><link>http://njit.technologypublisher.com/technology/60354</link><description>Technology Overview: This technology enables hydrophilic functionalized particles that improve solubility, dispersion, and bioavailability of hydrophobic drugs. By engineering particle surfaces to interact favorably with aqueous environments, the platform mitigates one of the most persistent challenges in pharmaceutical development. The technology is adaptable to multiple drug classes and is compatible with conventional formulation workflows.

Industry Pain Point: Poor aqueous solubility limits bioavailability and clinical success of many drug candidates.

NJIT Solution: These particles enable...</description><pubDate>Fri, 13 Feb 2026 09:10:26 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60354</guid></item><item><title>Binary Surface‑Coating Strategy for Enhanced Cohesive Powder Performance</title><caseId>24-014</caseId><link>http://njit.technologypublisher.com/technology/60352</link><description>Method of Using Binary Coating Agents in Powder Coating to Achieve Enhanced Properties of the Coated Powder and Its Blends Having Cohesive Powders

Technology Overview: This technology applies binary surface‑coating agents to cohesive powders to dramatically enhance flowability, blend uniformity, and processability. By synergistically selecting complementary coating agents, the method achieves performance gains using minimal additive quantities. The approach is compatible with existing powder‑coating and mixing equipment and is applicable to pharmaceutical, additive manufacturing, and specialt...</description><pubDate>Fri, 13 Feb 2026 09:05:55 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60352</guid></item><item><title>Surface‑Engineered Powder Coatings for Enhanced Blend Processability</title><caseId>22-020</caseId><link>http://njit.technologypublisher.com/technology/60351</link><description>Powder Blend Processability Improvements Through Minimal Amounts of Synergistically Selected Surface Coating Agents

Technology Overview: This NJIT technology enables improved powder blend processability through the application of minimal amounts of synergistically selected surface‑coating agents. The method enhances powder flow, reduces segregation, and improves blending uniformity without altering bulk material properties. It is applicable to pharmaceutical, chemical, and additive manufacturing powders, where consistent processing is critical to product quality.

Industry Pain Point: Poor po...</description><pubDate>Fri, 13 Feb 2026 09:02:06 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60351</guid></item><item><title>Amino Alcohol Ionizable Lipids for Next Generation Nucleic Acid Delivery</title><caseId>22-017</caseId><link>http://njit.technologypublisher.com/technology/60350</link><description>Technology Overview: This technology introduces a novel class of amino‑alcohol‑based ionizable lipids designed to improve the delivery of nucleic acids, including mRNA and siRNA. The lipids exhibit pH‑responsive ionization, enabling efficient endosomal escape while maintaining low toxicity under physiological conditions. Their chemical tunability allows optimization for encapsulation efficiency, stability, and in‑vivo performance, making them well suited for lipid nanoparticle (LNP) formulations.

Industry Pain Point: Current ionizable lipids used in LNPs face trade‑offs between delivery effic...</description><pubDate>Fri, 13 Feb 2026 08:58:12 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60350</guid></item><item><title>Continuous API Manufacturing Platform for Modern Pharmaceutical Production</title><caseId>M19-020-01</caseId><link>http://njit.technologypublisher.com/technology/60348</link><description>Continuous API Manufacturing Platform for Modern Pharmaceutical Production (Continuous Production of Active Pharmaceutical Ingredients, Tech ID: 19‑020)

Technology Overview: This technology expands on continuous pharmaceutical manufacturing by enabling steady‑state production of APIs with precise control over reaction and separation conditions. The platform improves product consistency, reduces batch variability, and significantly lowers manufacturing footprint and operational costs. It aligns with regulatory initiatives promoting continuous processing for improved drug quality and supply cha...</description><pubDate>Fri, 13 Feb 2026 08:52:38 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60348</guid></item><item><title>Continuous Manufacturing Platform for Active Pharmaceutical Ingredients (APIs)</title><caseId>19-020</caseId><link>http://njit.technologypublisher.com/technology/60347</link><description>Continuous Production of Active Pharmaceutical Ingredients

Technology Overview: This technology provides a continuous manufacturing platform for producing APIs, replacing traditional batch‑based pharmaceutical processing. The system enables precise control over reaction conditions, residence time, and product quality while improving throughput and reproducibility. Continuous production reduces footprint, energy consumption, and batch variability, aligning with regulatory trends encouraging modernized pharmaceutical manufacturing.

Industry Pain Point: Batch API manufacturing is inefficient, c...</description><pubDate>Fri, 13 Feb 2026 08:50:35 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60347</guid></item><item><title>Polymeric Drug‑Loaded Films with Uniform Particle Distribution for Controlled Release</title><caseId>17-047</caseId><link>http://njit.technologypublisher.com/technology/60346</link><description>Compositions and Methods for Preparing Polymeric Films Loaded with Uniformly Distributed Drug Particles

Technology Overview: This technology enables the fabrication of polymeric films containing uniformly distributed drug particles, overcoming aggregation issues common in film‑based drug delivery systems. The method ensures consistent drug loading and controlled release characteristics across the film matrix. It is applicable to oral, transdermal, and implantable delivery formats and is compatible with scalable pharmaceutical manufacturing processes.

Industry Pain Point: Non‑uniform drug dis...</description><pubDate>Fri, 13 Feb 2026 08:47:16 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60346</guid></item><item><title>Dry Processed Surface Coated Excipients for High Performance Tablets</title><caseId>16-022</caseId><link>http://njit.technologypublisher.com/technology/60345</link><description>Dry Processed Surface Coated Engineered Excipients

Technology Overview: This technology uses solvent‑free, dry processing to apply functional coatings to excipients, improving flowability, compressibility, and blend uniformity without altering chemical composition. The process integrates smoothly with existing tableting lines and supports Quality‑by‑Design principles for robust scale‑up.

Industry Pain Point: Wet coating adds cost, complexity, and drying steps while risking variability.
NJIT Solution: Dry‑coated excipients provide superior performance with simpler, greener manufacturing.

Key...</description><pubDate>Fri, 13 Feb 2026 08:41:16 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60345</guid></item><item><title>Electroactive, Electrospun Polymer Scaffolds for Regenerative Medicine</title><caseId>08-018</caseId><link>http://njit.technologypublisher.com/technology/60344</link><description><![CDATA[Technology Overview: This technology creates electrospun, electroactive polymer scaffolds that provide biophysical cues to cells, mimicking native extracellular matrix while enabling electrostimulation. The fibrous architecture supports cell adhesion and alignment, and the electroactivity can modulate cell behavior to accelerate healing and tissue formation.

Industry Pain Point: Passive scaffolds lack instructive electrical cues needed for functional regeneration.
NJIT Solution: Electroactive, ECM‑like fibers deliver mechanical support and bioelectric stimulation.

Key Features &amp; Advantag...]]></description><pubDate>Fri, 13 Feb 2026 08:34:42 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60344</guid></item><item><title>Additive Biomanufacturing Platform for Cell Laden Hydrogels and Living Constructs</title><caseId>M18-038-03</caseId><link>http://njit.technologypublisher.com/technology/60342</link><description>Additive Biomanufacturing Platform for Cell‑Laden Hydrogels and Living Constructs (Additive Manufacturing of Cell‑Laden Functional Hydrogel and Live Cell Constructs, Tech ID: 18‑038)

Technology Overview: This technology enables additive manufacturing of hydrogels containing living cells, allowing precise spatial control over biological and structural features of 3D tissue constructs. The platform supports high cell viability while enabling fabrication of complex geometries with embedded functionality. It advances scalable biomanufacturing of tissues for regenerative medicine, drug screening, ...</description><pubDate>Fri, 13 Feb 2026 08:30:32 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60342</guid></item><item><title>Dual Material 3D Printing Platform for Perfusable Tissue Scaffolds</title><caseId>M18-038-02</caseId><link>http://njit.technologypublisher.com/technology/60341</link><description><![CDATA[Dual‑Material 3D Printing Platform for Perfusable Tissue Scaffolds (Dual Printing Additive Manufacturing of 3D Scaffolds with Channel Diameters Ranging from 100&ndash;500 Microns, Tech ID: 18‑038)

Technology Overview: This technology enables dual‑material additive manufacturing of 3D scaffolds with precisely controlled channel diameters suitable for tissue perfusion and vascularization. The system prints structural and sacrificial materials in a coordinated manner, enabling formation of interconnected microchannels within biocompatible scaffolds. This capability is critical for developing fun...]]></description><pubDate>Fri, 13 Feb 2026 08:27:23 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60341</guid></item><item><title>Additive Manufacturing of Embedded Channel Networks for Advanced Functional Structures</title><caseId>18-038</caseId><link>http://njit.technologypublisher.com/technology/60339</link><description>Technology Overview: This technology enables additive manufacturing of structures with embedded internal channel networks that are not achievable through conventional fabrication methods. The approach supports precise control over channel geometry, spacing, and orientation within three‑dimensional printed parts. These embedded channels enable functions such as fluid transport, thermal management, drug delivery, or embedded sensing, making the technology highly versatile across engineering and biomedical applications.

Industry Pain Point: Traditional manufacturing methods cannot reliably produ...</description><pubDate>Fri, 13 Feb 2026 08:17:16 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/60339</guid></item><item><title>Applications of Paper Spray-Based Mass Spectrometry Techniques for Rapid and Sensitive Detection of Per- and Polyfluoroalkyl Substances (PFAS)</title><caseId>24-016</caseId><link>http://njit.technologypublisher.com/technology/56268</link><description><![CDATA[Traditional PFAS analysis by mass spectrometry (MS) is time-consuming, as laborious sample preparation (e.g., extraction and desalting) is necessary. This invention reports fast detection of PFAS by paper spray (PS)-based MS techniques, which employs a triangular-shaped filter paper for sample loading and ionization (&le; 3 min per sample). PS-MS can be used for direct PFAS analysis of drinking water, tap water, and wastewater. Interestingly, food package paper materials (also other samples such as vegetables/fruits) can be directly cut into triangular shaped pieces and examined with PS-MS for...]]></description><pubDate>Tue, 18 Feb 2025 06:54:47 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/56268</guid></item><item><title>Long‑Acting Injectable Anesthetic Formulations for Severe and Pathological Pain</title><caseId>18-039</caseId><link>http://njit.technologypublisher.com/technology/30321</link><description>Injectable Formulations of Anesthetics for any Pathological Pain

Technology Overview: This NJIT technology provides injectable anesthetic formulations engineered for extended analgesia in severe or pathological pain conditions. By optimizing drug composition and release kinetics, the formulation maintains therapeutic levels over clinically meaningful durations while minimizing systemic exposure. The platform is compatible with established administration techniques and can be tailored for perioperative, neuropathic, or cancer‑related pain management.

Industry Pain Point: Short‑acting anesthet...</description><pubDate>Wed, 12 Dec 2018 11:40:30 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/30321</guid></item><item><title>Label‑Free Dielectric Spectroscopy Platform for High‑Throughput Ion Channel Drug Screening</title><caseId>08-009</caseId><link>http://njit.technologypublisher.com/technology/28768</link><description><![CDATA[Dielectric Spectroscopy Assays for Screening of Ion Channel Ligands

Technology Overview: This technology provides a label‑free dielectric spectroscopy&ndash;based assay platform for screening ligands that interact with ion channels, a critical class of pharmaceutical targets. The system measures changes in dielectric properties induced by ligand‑channel interactions, enabling real‑time detection without fluorescent labels or radioactive markers. By eliminating complex labeling steps, the platform simplifies assay workflows while preserving sensitivity. It is well suited for high‑throughput dr...]]></description><pubDate>Wed, 19 Sep 2018 08:59:04 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/28768</guid></item><item><title>Injectable Self Assembling Antibacterial Peptide Hydrogel for Infection Control</title><caseId>18-030</caseId><link>http://njit.technologypublisher.com/technology/28459</link><description>Technology Overview: This NJIT technology is an injectable peptide‑based hydrogel that self‑assembles in situ to form an antibacterial matrix. The hydrogel is composed of engineered peptides that exhibit intrinsic antimicrobial activity while maintaining biocompatibility. Upon injection, the material forms a localized scaffold capable of preventing bacterial colonization and supporting tissue healing. This approach offers a potential alternative to systemic antibiotics, reducing the risk of resistance and systemic side effects.

Industry Pain Point: Post‑surgical and wound infections remain ch...</description><pubDate>Mon, 13 Aug 2018 08:35:57 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/28459</guid></item><item><title>Integrated Toothbrush Suction System for Safer Oral Care</title><caseId>18-027</caseId><link>http://njit.technologypublisher.com/technology/28415</link><description>Toothbrush Suction Apparatus and Method

Technology Overview: This NJIT technology integrates active suction into a toothbrush to remove fluids, debris, and toothpaste during brushing. Designed for patients with limited swallowing ability or high aspiration risk, the system improves safety and hygiene during oral care. The device can be configured for clinical, home‑health, or assisted‑living settings, supporting better compliance and infection control.

Industry Pain Point: Conventional oral care poses aspiration risk for vulnerable populations.
NJIT Solution: Built‑in suction during brushing...</description><pubDate>Tue, 07 Aug 2018 07:13:15 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/28415</guid></item><item><title>Ultra‑Sensitive MEMS Fiber‑Optic Microphone for Harsh and Remote Environments</title><caseId>06-052</caseId><link>http://njit.technologypublisher.com/technology/28364</link><description><![CDATA[MEMS Fiber Optic Microphone

Technology Overview: This is a micro‑electromechanical system (MEMS)&ndash;based fiber‑optic microphone designed for high‑sensitivity acoustic sensing in environments where conventional electronic microphones fail. The system converts sound‑induced vibrations into optical signals transmitted through fiber, enabling operation in electromagnetically noisy, high‑temperature, or corrosive environments. Its compact MEMS architecture allows for precise detection of acoustic pressure with minimal signal distortion and immunity to electromagnetic interference. The fiber‑op...]]></description><pubDate>Tue, 31 Jul 2018 08:31:41 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/28364</guid></item><item><title>Electrode‑Array Dielectrophoretic Assembly</title><caseId>07-029</caseId><link>http://njit.technologypublisher.com/technology/28179</link><description><![CDATA[Microfluidic Device for the Assembly &amp; Transport of Microparticles

Technology Overview: A microfluidic device with independently addressable, interdigitated electrode arrays that uses high‑gradient AC electric fields to assemble microparticles at predefined locations and then transport them collectively by sequentially energizing adjacent arrays&mdash;enabling precise, large‑scale assembly for photonic, sensing, and biofabrication applications.

Industry Pain Point: Traditional self‑assembly lacks positional precision and on‑chip transport control, limiting yield for structured micro‑mate...]]></description><pubDate>Fri, 20 Jul 2018 07:15:17 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/28179</guid></item><item><title>Automated Addressable Microfluidic Platform for Live‑Culture Manipulation</title><caseId>18-006</caseId><link>http://njit.technologypublisher.com/technology/28097</link><description>Automated Addressable Microfluidic Technology for Minimally Disruptive Manipulation of Cells and Fluids within Living Cultures

Technology Overview: This technology introduces an automated, addressable microfluidic system that enables precise manipulation of fluids and cells within living cultures. Individual regions of a culture can be selectively addressed without disrupting surrounding tissue, enabling localized stimulation, sampling, or treatment. The platform supports long‑term culture maintenance and real‑time control, making it highly valuable for advanced biological studies.

Industry ...</description><pubDate>Thu, 12 Jul 2018 11:39:27 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/28097</guid></item><item><title>Micro‑Jet Assisted Nanopowder Fluidization</title><caseId>06-057</caseId><link>http://njit.technologypublisher.com/technology/27971</link><description><![CDATA[Fluidized Mixing &amp; Blending of Nanopowders with Secondary Gas Flow

Technology Overview: A fluidized‑bed method and apparatus that uses a standard upflow fluidizing gas plus a secondary, typically downward micro‑jet to introduce turbulence and shear, aerate agglomerates, and break up nano‑scale clusters&mdash;achieving full‑bed fluidization and enhanced mixing/blending even for cohesive nanopowders. ,

Industry Pain Point: Nanoparticles fluidize as fragile agglomerates and can channel or defluidize without assistance; reliable dispersal and mixing at scale is difficult with conventional ga...]]></description><pubDate>Fri, 22 Jun 2018 08:58:45 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27971</guid></item><item><title>Low‑Residue Molded Energetic Components</title><caseId>12-032</caseId><link>http://njit.technologypublisher.com/technology/27969</link><description>Foamed Celluloid Process Using Expandable Beads

Technology Overview: A scalable molding process for foamed celluloid that uses physical‑blowing‑agent (PBA) presoaking of small, uniform celluloid pieces followed by thermal foaming in a mold to achieve target densities and geometries. For very low‑density parts, the process introduces a pre‑expansion step prior to final molding, enabling lightweight, moldable components suitable for energetic applications where combustible, low‑residue structures are desired. ,

Industry Pain Point: Conventional felt‑fiber or non‑porous celluloid parts can be l...</description><pubDate>Fri, 22 Jun 2018 08:30:37 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27969</guid></item><item><title>Sustainable High‑Performance Polyesters from Asymmetrical Bio‑Based Monomers</title><caseId>09-040</caseId><link>http://njit.technologypublisher.com/technology/27965</link><description>New Polyester Ethers and Polyesters Derived from Asymmetrical Bisanhydrohexitol‑Based Monomers

Technology Overview: This technology introduces novel polyester ethers and polyesters synthesized from asymmetrical bisanhydrohexitol‑based monomers, enabling materials with tailored thermal, mechanical, and processing properties. Derived from renewable feedstocks, these polymers offer a sustainable alternative to conventional petrochemical plastics while delivering performance suitable for engineering applications.

Industry Pain Point: Bio‑based plastics often lack performance parity with petroleu...</description><pubDate>Fri, 22 Jun 2018 07:45:44 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27965</guid></item><item><title>Continuous Polymer Coating Platform for Uniform Functional Particles</title><caseId>14-005</caseId><link>http://njit.technologypublisher.com/technology/27964</link><description>System and Method for Continuous Polymer Coating of Particles

Technology Overview: This technology provides a continuous polymer coating process for producing uniformly coated particles across micro‑ and sub‑micron size ranges. The system enables controlled deposition of polymer layers onto core particles with high reproducibility and scalability. Unlike batch coating methods, this continuous approach improves throughput and consistency while allowing precise control over coating thickness and material properties. The platform is compatible with a wide range of polymers and core materials, ma...</description><pubDate>Fri, 22 Jun 2018 07:43:22 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27964</guid></item><item><title>Superdisintegrant‑Based Composite Particles for Rapid Drug Dispersion and Dissolution</title><caseId>12-045</caseId><link>http://njit.technologypublisher.com/technology/27963</link><description>Systems and Methods for Superdisintegrant‑Based Composite Particles for Dispersion and Dissolution of Agents

Technology Overview: This enables the formation of superdisintegrant‑based composite particles designed to dramatically improve dispersion and dissolution of poorly soluble active agents. Using engineered composite structures, the technology enhances water penetration and rapid particle breakup, overcoming a major bottleneck in oral drug formulation. The system is applicable to a wide range of pharmaceutical compounds and can be integrated into existing continuous or batch manufacturin...</description><pubDate>Fri, 22 Jun 2018 07:31:01 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27963</guid></item><item><title>Temperature‑Swing Absorption System for Efficient CO₂ Removal from Flue Gas</title><caseId>13-038</caseId><link>http://njit.technologypublisher.com/technology/27952</link><description>Systems and Methods for CO₂ Removal from Flue Gas by Temperature Swing Absorption

Technology Overview: This NJIT technology provides a temperature‑swing absorption (TSA) system for selectively capturing CO₂ from flue gas streams. The system uses thermally responsive absorbents integrated into membrane or packed structures to enable efficient CO₂ uptake and controlled release during regeneration. Compared to conventional amine scrubbing, this approach reduces energy demand, degradation, and operating costs.

Industry Pain Point: Conventional carbon capture technologies are energy‑intensive and...</description><pubDate>Thu, 21 Jun 2018 12:26:45 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27952</guid></item><item><title>Piezoelectric Collagen Scaffold for Stimulated Tissue Regeneration</title><caseId>16-014</caseId><link>http://njit.technologypublisher.com/technology/27921</link><description>System and Method for a Piezoelectric Collagen Scaffold

This NJIT technology introduces a piezoelectric collagen scaffold that converts mechanical loading into localized electrical stimulation, mimicking natural bioelectrical cues found in healing tissues. The scaffold is biocompatible and supports cell attachment while generating electrical signals in response to movement or stress. This bioelectrical stimulation promotes cellular activity and tissue regeneration without external power sources.

Industry Pain Point: Existing scaffolds lack active stimulation to accelerate and guide tissue re...</description><pubDate>Thu, 21 Jun 2018 08:06:42 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27921</guid></item><item><title>Regenerative Scaffold Platform for Accelerated Tissue Growth and Repair</title><caseId>12-012</caseId><link>http://njit.technologypublisher.com/technology/27890</link><description>New Polyester Ethers and Polyesters Derived from Asymmetrical Bisanhydrohexitol‑Based Monomers

Technology Overview: This technology introduces novel polyester ethers and polyesters synthesized from asymmetrical bisanhydrohexitol‑based monomers, enabling materials with tailored thermal, mechanical, and processing properties. Derived from renewable feedstocks, these polymers offer a sustainable alternative to conventional petrochemical plastics while delivering performance suitable for engineering applications.

Industry Pain Point: Bio‑based plastics often lack performance parity with petroleu...</description><pubDate>Fri, 15 Jun 2018 12:26:33 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27890</guid></item><item><title>Implantable Optical Waveguide Conduits for Next‑Gen Neural Interfaces</title><caseId>15-023</caseId><link>http://njit.technologypublisher.com/technology/27883</link><description>Biocompatible and Implantable Optical Conduits

Technology Overview: This NJIT technology delivers biocompatible, implantable optical conduits that route light to and from deep or peripheral tissues for sensing, stimulation, and diagnostics. Engineered as flexible waveguide structures, the conduits maintain optical transmission while minimizing tissue irritation and fibrotic response. They can couple to external light sources or detectors to enable optogenetic stimulation, neural photometry, or in‑situ spectroscopy, providing a durable optical interface where electrical leads are impractical o...</description><pubDate>Fri, 15 Jun 2018 08:26:20 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27883</guid></item><item><title>Predictive PAL Tolerance via Fusional Vergence</title><caseId>11-054</caseId><link>http://njit.technologypublisher.com/technology/27880</link><description><![CDATA[Predictive PAL Tolerance via Fusional Vergence (Method for Determining Acceptance of Progressive Addition Lenses (PALs), Tech ID: 11‑054) 

Technology Overview: A clinical decision method that measures at least one fusional‑vergence parameter for a patient and compares it to a threshold to predict the probability of PAL acceptance before dispensing&mdash;reducing returns and improving patient outcomes. 

Industry Pain Point: PAL adoption can be hindered by non‑tolerance due to binocular vision characteristics; trial‑and‑error fittings create costly remakes and poor patient experience. 

NJIT S...]]></description><pubDate>Fri, 15 Jun 2018 08:23:16 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27880</guid></item><item><title>Packeted Energy Delivery Architecture for Intelligent Power Distribution</title><caseId>12-042</caseId><link>http://njit.technologypublisher.com/technology/27706</link><description>Packeted Energy Delivery System and Methods

Technology Overview: This introduces a packet‑based energy delivery system in which electrical energy is discretized and transmitted as controllable packets rather than continuous flow. Inspired by data packet switching in communication networks, the system enables precise routing, timing, and prioritization of energy delivery. This architecture improves efficiency, resiliency, and control in complex electrical systems, particularly in environments with variable loads, distributed generation, or storage integration.

Industry Pain Point: Traditional...</description><pubDate>Tue, 15 May 2018 11:00:22 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27706</guid></item><item><title>Carbon Nanotube–Assisted Membrane Technology for High‑Efficiency Chemical Extraction</title><caseId>08-029</caseId><link>http://njit.technologypublisher.com/technology/27704</link><description><![CDATA[Carbon Nanotube Mediated Membrane Extraction

Technology Overview: This technology introduces a carbon nanotube&ndash;mediated membrane extraction platform that enhances mass transfer during liquid‑phase separation processes. By incorporating carbon nanotubes into membrane structures, the system creates highly efficient transport pathways that improve permeability, selectivity, and extraction rates. The technology is applicable to a wide range of chemical and environmental separations, including trace contaminant removal and analytical sample preparation. Its design enables faster extraction w...]]></description><pubDate>Tue, 15 May 2018 10:57:25 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27704</guid></item><item><title>Adaptive‑Control Exoskeleton for Safer and More Intuitive Human Assistance</title><caseId>17-027</caseId><link>http://njit.technologypublisher.com/technology/27540</link><description>Exoskeleton with Admittance Control

Technology Overview: This technology is an exoskeleton system employing admittance control, allowing the device to dynamically respond to user‑applied forces. The control architecture enables smooth, intuitive assistance by adjusting movement based on real‑time interaction between the user and the device. This approach enhances safety, comfort, and adaptability compared to rigid or pre‑programmed exoskeletons, making the system suitable for rehabilitation and industrial assistance.

Industry Pain Point: Conventional exoskeletons can feel rigid or unintuitiv...</description><pubDate>Fri, 13 Apr 2018 06:52:51 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27540</guid></item><item><title>Directional‑Antenna Train Inauguration Protocol</title><caseId>15-006</caseId><link>http://njit.technologypublisher.com/technology/27468</link><description><![CDATA[Method and Device for Wireless Topology Discovery for Train Backbone Networks

Technology Overview: A wireless train‑backbone &ldquo;inauguration&rdquo; protocol that enables each backbone node (BN) to learn the ordered physical topology of a linear train network using directional antennas and hello/topology frames. The method includes pair‑consistency checks, local topology table updates, and topology convergence detection&mdash;adapting the wired IEC 61375 concept to wireless channels.

Industry Pain Point: Existing standards assume wired links between adjacent BNs; shifting to wireless face...]]></description><pubDate>Mon, 02 Apr 2018 11:52:59 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27468</guid></item><item><title>Continuous Anti‑Solvent Crystallization Platform for Uniform Polymer‑Coated Nanoparticles</title><caseId>14-036</caseId><link>http://njit.technologypublisher.com/technology/27366</link><description>Porous Hollow Fiber Anti‑Solvent Crystallization‑Based Continuous Method of Polymer Coating on Submicron and Nanoparticles

Technology Overview: This technology enables continuous polymer coating of submicron and nanoparticles using a porous hollow‑fiber anti‑solvent crystallization process. The system allows precise control of coating formation through regulated mass transfer across hollow fiber membranes, producing uniform and reproducible polymer layers. Compared to batch methods, this approach improves scalability, consistency, and process efficiency. It is particularly well suited for pha...</description><pubDate>Wed, 14 Mar 2018 10:45:59 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27366</guid></item><item><title>High‑Specificity Point‑of‑Care Micro Biochip for Improved Diagnostic Accuracy</title><caseId>17-032</caseId><link>http://njit.technologypublisher.com/technology/27365</link><description>Enhanced Sensitivity and Specificity for Point‑of‑Care (POC) Micro Biochip

Technology Overview: This technology delivers an enhanced POC micro biochip designed to improve both sensitivity and specificity in diagnostic testing. Through optimized fluidic pathways and assay architecture, the chip minimizes non‑specific binding while maximizing detection of target biomarkers. The platform supports rapid, reliable diagnostics in decentralized settings and is adaptable to multiple disease states and biomolecular targets.

Industry Pain Point: Many POC diagnostics trade accuracy for speed, limiting ...</description><pubDate>Wed, 14 Mar 2018 10:18:16 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27365</guid></item><item><title>Clock‑Free Low‑Power Sensor Communications</title><caseId>15-040</caseId><link>http://njit.technologypublisher.com/technology/27363</link><description><![CDATA[Clock‑Free Low‑Power Sensor Communications (Asynchronous Wireless Sensing, Tech ID: 15‑040) 

Technology Overview: This NJIT invention provides a complete asynchronous sensing and wireless communication architecture for ultra‑low‑power sensor nodes. It combines asynchronous digital signaling with UWB impulse radios and a hybrid FSK/OOK modulation approach to eliminate transmitter clock synchronization&mdash;reducing complexity and power while remaining robust to insertion/deletion timing errors via tailored FEC schemes. , 

Industry Pain Point: Battery‑constrained IoT devices and medical/indus...]]></description><pubDate>Wed, 14 Mar 2018 08:08:15 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27363</guid></item><item><title>Bandwidth‑Optimized Distributed Storage Security</title><caseId>15-038</caseId><link>http://njit.technologypublisher.com/technology/27361</link><description>Communication‑Efficient Secret Sharing

Technology Overview: This innovation introduces secret‑sharing codes that minimize decoding bandwidth (communication cost) when reconstructing data from distributed storage. Instead of downloading from only the minimum threshold of nodes, the scheme strategically contacts more nodes but downloads less from each, reducing total communication while preserving threshold security and reliability guarantees.

Industry Pain Point: Conventional secret‑sharing and many erasure‑coded storage systems incur high network overhead during recovery or audit, inflating ...</description><pubDate>Wed, 14 Mar 2018 07:52:25 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27361</guid></item><item><title>Photoluminescent Hydrogel Platform for Bioimaging and Therapeutic Applications</title><caseId>17-010</caseId><link>http://njit.technologypublisher.com/technology/27099</link><description>Photoluminescent Hydrogel

Technology Overview: This NJIT technology is a photoluminescent hydrogel that combines soft, biocompatible polymer networks with intrinsic light‑emitting properties. The hydrogel can be engineered to emit fluorescence under specific excitation wavelengths while maintaining favorable mechanical and biological characteristics. Its formulation supports tunable optical intensity, degradability, and mechanical strength, enabling integration into biomedical devices, biosensors, or tissue‑engineering systems. Unlike conventional fluorescent probes, the luminescent functiona...</description><pubDate>Fri, 09 Feb 2018 11:37:23 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27099</guid></item><item><title>Dominant‑Resource‑Aware VM Mapping</title><caseId>16-021</caseId><link>http://njit.technologypublisher.com/technology/27092</link><description><![CDATA[Virtual Machine Placement in a Heterogeneous Data Center

Technology Overview: A resource‑management method for mapping unassigned VMs onto heterogeneous physical machines (PMs) by iteratively activating only the needed PM subset and assigning VMs such that each VM&rsquo;s multi‑dimensional resource demands (CPU, memory, etc.) fit the remaining PM capacities. The approach targets lower power use and higher utilization while respecting heterogeneity.

Industry Pain Point: Many VMP strategies either over‑activate servers or ignore heterogeneity, causing energy waste, hotspots, and SLA risk in la...]]></description><pubDate>Thu, 08 Feb 2018 11:32:14 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27092</guid></item><item><title>Carbon Nanotube–Enabled Biofuel Cell for High‑Efficiency Biopower Generation</title><caseId>06-039</caseId><link>http://njit.technologypublisher.com/technology/27090</link><description>Integrated Biofuel Cell with Aligned Nanotube Electrodes and Method of Use Thereof

Technology Overview: This is an integrated biofuel cell that leverages aligned carbon nanotube (CNT) electrodes to significantly enhance electrochemical performance. The aligned CNT architecture provides high surface area, excellent electrical conductivity, and improved electron transfer between enzymes and electrodes. This results in increased power density and stability compared to conventional biofuel cells. The system is designed for miniaturization and integration into portable or implantable devices, wher...</description><pubDate>Thu, 08 Feb 2018 10:53:53 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27090</guid></item><item><title>Integrated Microfluidic Platform for Biomarker Detection and Serum Self‑Separation</title><caseId>17-020</caseId><link>http://njit.technologypublisher.com/technology/27086</link><description>Biomarker Detection and Self‑Separation of Serum during Capillary Flow

Technology Overview: This technology enables simultaneous biomarker detection and passive serum separation within a microfluidic device using capillary flow. The system eliminates external centrifugation or preprocessing steps by leveraging microchannel geometry and surface chemistry to separate serum directly from whole blood. Integrated detection elements enable rapid, point‑of‑care biomarker analysis from small sample volumes, improving usability in clinical and field settings.

Industry Pain Point: Standard blood testi...</description><pubDate>Thu, 08 Feb 2018 09:21:29 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27086</guid></item><item><title>Non‑Invasive Glucose Monitoring Using Near‑Infrared Spectroscopy</title><caseId>12-034</caseId><link>http://njit.technologypublisher.com/technology/27033</link><description>System and Method for Non‑Invasive Glucose Monitoring Using Near Infrared Spectroscopy

Technology Overview: This technology provides a non‑invasive glucose monitoring system based on near‑infrared (NIR) spectroscopy, eliminating the need for fingersticks or implanted sensors. The system analyzes optical absorption and scattering characteristics of biological tissue to correlate spectral signatures with blood glucose levels. Advanced signal processing enables continuous or on‑demand measurements while minimizing interference from physiological variability. The approach is designed to improve p...</description><pubDate>Wed, 31 Jan 2018 08:25:30 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/27033</guid></item><item><title>Miniature Fiber‑Optic Optical Coherence Elastography Probe for Tissue Mechanics</title><caseId>16-027</caseId><link>http://njit.technologypublisher.com/technology/26985</link><description>Miniature Quantitative Optical Coherence Elastography Using a Fiber‑Optic Probe with a Fabry‑Perot Cavity

Technology Overview: This technology enables quantitative optical coherence elastography (OCE) in a miniaturized, fiber‑optic probe format. By integrating a Fabry‑Perot cavity, the system measures tissue displacement and mechanical properties with high spatial resolution. The compact footprint allows deployment in minimally invasive or point‑of‑care settings, supporting real‑time biomechanical assessment of soft tissues.

Industry Pain Point: Existing elastography methods lack resolution ...</description><pubDate>Tue, 30 Jan 2018 07:04:45 GMT</pubDate><author>techtransfer@njit.edu</author><guid>http://njit.technologypublisher.com/technology/26985</guid></item></channel></rss>