Latest AIM Projects


Correction Of Eye Diseases With Optical Metasurfaces

This technology utilizes patterned optical nanostructures, known as metasurfaces, integrated onto glasses or contact lenses to manipulate light in novel ways, significantly improving peripheral vision and offering a potential cure for certain types of blindness. This innovation aims to address the limitations of current eyewear solutions for patients with diseases like glaucoma or hemianopia, by providing a continuous field of view and enabling vision correction in all directions with a compact, ultrathin design.


Sorbent Mediated Electrocatalytic Reduction of CO2 to Methane

This technology leverages a novel approach by using sorbent materials to capture CO2 from dilute streams and directly convert it into methane, bypassing the need for energy-intensive regeneration processes. Utilizing an N- heterocyclic carbene sorbent and an iron tetraphenyl porphyrin chloride electrocatalyst, it achieves high Faradaic efficiency in methane production while regenerating the sorbent for reuse.


Systems And Methods For Delivering Pulsed Electric Fields To Skin Tissue


DNA-Linked Enzyme-Coupled Assays


Fabrication of enhanced supercapacitors using atomic layer deposition of metal oxide on nanostructures


Isolation Of Cardiac Stem/Progenitor Cells Expressing Islet-1


Microscopy System

This technology introduces an innovative microscopy system that integrates multimodal optical coherence microscopy (OCM) with a confocal fluorescence microscope (CFM) to enhance the diagnosis of Dry Eye Disease (DED). By capturing and combining depth-sectioned cross-sectional images with contrast images of fluorescent molecule-labeled cells, it offers a superior visualization of the eye surface, enabling precise detection and diagnosis of DED and other corneal conditions.


Map4k3 Small Molecule Drug Inhibitors

This technology encompasses the discovery and development of small molecule inhibitors that target the regulatory kinase MAP4K3, identified through a rigorous in silico and in vitro screening process. These inhibitors are poised for therapeutic applications, particularly in treating various neurological diseases and cancers, by modulating the MAP4K3 pathway which is critical for cellular metabolic processes and has been implicated in disease pathogenesis.


Cas1, A Non-sequence Specific Dnase

Like eukaryotic cells, prokaryotes must defend against parasitic infection. Well-characterized mechanisms of innate immunity in bacteria include mechanisms that block phage adsorption or DNA injection, abortive infection (Abi) and restriction/modification systems (RMS).  More recent evidence suggests that prokaryotes have evolved an adaptive immune system that might be functionally analogous to RNA interference in eukaryotes. Initial evidence for this immune system emerged from in silico analysis of a distinctive repetitive DNA feature that is common in prokaryotic genomes.  These repetitive elements, called CRISPRs (Clustered Regularly lnter spaced Short Palindromic Repeats), consist of a short repeat (24-48nt) sequence followed by a 'unique' spacer sequence of approximately the same length.  

 

CRISPRs are transcribed and processed into small CRISPR-derived RNAs (crRNA) that are proposed to serve as sequence-specific guides for the targeted interference of viral and plasmid replication. A variable cassette of up to 45 protein families representing at least seven distinct immune system subtypes mediates this nucleic acid-based immune system. CRISPR-associated gene 1 (cas1) encodes the only universally conserved protein component of CRISPR immune systems, yet its function is unknown.  

 

UC Berkeley researchers discovered the structural basis for the endonuclease activity of Cas1 protein. The crystal structure of the Cas1 protein reveals a novel fold organized into an N-terminal p-strand domain and a C-terminal α­ helical domain. The structure and DNA specific nuclease activity of Cas1 provides a foundation for understanding the potential role for this protein in the recognition, cleavage and/or integration of foreign nucleic acids into CRISPRs.


Simultaneous Ranging and Remote Chemical Sensing Utilizing Optical Dispersion or Absorption Spectroscopy

Simultaneous Ranging and Remote Chemical Sensing Utilizing Optical Dispersion or Absorption Spectroscopy

(Princeton Docket # 14-3039)

Inventors: Gerard Wysocki, Andreas Hangauer

Princeton researchers have developed a novel methodology that enables simultaneous ranging and spectroscopic chemical detection, combining capabilities that are not achievable with current state-of-the-art continuous wave laser-based spectrometers. This system employs a continuous-wave laser modulated by a time-varying radio frequency signal to produce spectral sidebands that encode chemical spectral information and range data. The modulated light passes through an optical path—potentially encountering multiple reflections or scattering—and is then detected and down-converted into a complex baseband signal. The resulting signal is demodulated to extract instantaneous frequency shifts that correspond directly to changes in optical path lengths. Integrated with real-time signal processing techniques such as phase correction and harmonic analysis, the technology delivers both accurate chemical concentration data and precise range measurements using only a single laser source and detector for multiple cascaded sensing paths. This approach is differentiated by its ability to combine remote chemical sensing with simultaneous optical path length determination in a continuous-wave system, bypassing the typical limitations found in pulsed methods like Raman LIDAR. By leveraging chirped radio frequency modulation and specialized signal processing, the system simplifies calibration and enables multi-path analysis, offering high chemical sensitivity and extensive range capabilities that are particularly valuable for applications such as gas plume monitoring and complex optical environments.

A continuous-wave laser system uses RF modulation to produce sidebands that encode spectroscopic and range information via frequency chirp. It demodulates a complex baseband signal, applying phase corrections, harmonic analysis, and path separation filtering to extract precise chemical concentrations and optical path lengths. This technique supports single or cascaded sensor layouts, offering simultaneous high-sensitivity remote chemical sensing with robust multipath resolution even under low light-return conditions.

 

APPLICATIONS

ADVANTAGES

  • Remote and open-path chemical sensing
  • Closed-path sensing applications that utilize multi-mode/scattering-based gas cells for which the pathlength is not known a-priori (e.g., integrating spheres)
  • Potential usage in multi-path chemical sensing for tomographic chemical detection with a single laser-based instrument
  • Enhancement of conventional spectrometers (e.g., based on CLaDS, FM spectroscopy, or WMS)
  • Usage in optical gas cells, where the invention can address the enduring problem of slowly drifting effective optical pathlength simultaneous with spectroscopic detection
  • Multiple cascaded sensors (measurement cells) in one optical train
  • Enables simultaneous chemical sensing and distance measurement in one system.
  • Increased system reliability through active monitoring of the optical pathlength
  • Supports robust multipath and cascaded sensor configurations for advanced applications.
  • Provides high sensitivity and accurate remote sensing even over long optical paths.
  • Improves calibration and monitoring by extracting precise optical path length information.
  • Simplifies sensor infrastructure by using a single laser and detector for multi-path analysis.

 

Stage of Development

Experimental verification has been completed in the following publication, where the observed behavior was as theoretically predicted:

Chirped laser dispersion spectroscopy for spectroscopic chemical sensing with simultaneous range detection

 

Contact
Renee Sanchez

New Ventures & Licensing Associate • (609) 258-6762 • renee.sanchez@Princeton.edu