Optimization of Surface-Enhanced Raman Spectroscopy Conditions for Implementation into a Microfluidic Device for Drug Detection.

A microfluidic device is being developed by University of California-Santa Barbara as part of a joint effort with the United States Army to develop a portable, rapid drug detection device. Surface-enhanced Raman spectroscopy (SERS) is used to provide a sensitive, selective detection technique within the microfluidic platform employing metallic nanoparticles as the SERS medium. Using several illicit drugs as analytes, the work presented here describes the efforts of the Edgewood Chemical Biological Center to optimize the microfluidic platform by investigating the role of nanoparticle material, nanoparticle size, excitation wavelength, and capping agents on the performance, and drug concentration detection limits achievable with Ag and Au nanoparticles that will ultimately be incorporated into the final design. This study is particularly important as it lays out a systematic comparison of limits of detection and potential interferences from working with several nanoparticle capping agents-such as tannate, citrate, and borate-which does not seem to have been done previously as the majority of studies only concentrate on citrate as the capping agent. Morphine, cocaine, and methamphetamine were chosen as test analytes for this study and were observed to have limits of detection (LOD) in the range of (1.5-4.7) × 10-8 M (4.5-13 ng/mL), with the borate capping agent having the best performance.

Quantitative Raman Cross-Sections and Band Assignments for Fentanyl and Fentanyl Analogs.

Raman cross sections and spectra were measured for five synthetic opioid fentanyl analogs: fentanyl citrate, sufentanil citrate, alfentanil HCl, carfentanil oxalate, and remifentanil HCl. The measurements were performed with excitation wavelengths in the visible (532 nm) and near infrared (785 nm). In addition, density functional theory (DFT) calculations were employed to generate simulated spectra of the compounds and aid in identification of the observed spectral modes. These cross-section measurements and calculations were also used to assess results from a series of measurements of fentanyls cut with other powdered materials. These measurements are valuable for assessment of field-deployable Raman chemical sensors for detection of fentanyl and fentanyl analogs, including when mixed with other materials.

PREPS and L-particles: a new approach to virus-like particle vaccines.

Conventional virus-like particles are usually composed of a single structural protein which spontaneously assembles into particles. L-particles, a little-known type of virus-like particle, are produced as part of the natural infectious process of many, if not all, alpha-herpesviruses. L-particles lack the nucleocapsid present in the infectious virion but contain all of the virus envelope and tegument proteins. L-particles contain no virus DNA and are noninfectious, though they are biologically competent, since they are capable of delivering viral envelope and tegument proteins to cells. When cells are infected with herpes simplex virus Type 1 under conditions where viral DNA synthesis is blocked, previral DNA replication enveloped particles are produced. These are similar to L-particles, but differ slightly in protein composition. This article reviews the available data regarding these vaccine candidates and explores the wide-ranging potential applications, including vaccine candidates against infectious diseases and cancer, as well as a protein delivery vector.