Combining surface-enhanced Raman spectroscopy (SERS) and paper spray mass spectrometry (PS-MS) for illicit drug detection.

There is an ongoing effort in the US illicit drug market to make new psychoactive compounds more potent and addictive. Due to continuous chemical modifications, many fentanyl analogs are developed and mixed with more traditional illicit drugs, such as cocaine and heroin. Detecting fentanyl and fentanyl analogs in these illicit drug mixtures has become more crucial because of the increased potency and associated health risks. Most confirmatory procedures require time-consuming and expensive, highly sophisticated laboratory equipment and experimental procedures, which can delay critical information that might save a victim or find a suspect. In this study, we propose miniaturizing and accelerating this process by combining surface-enhanced Raman spectroscopy (SERS) analysis and paper spray mass spectrometry (PS-MS). For this aim, dual-purposed paper substrates were developed through soaking in Au/Ag nanostars suspensions. These novel, in-house prepared paper SERS substrates showed stability for up to four weeks with and without the presence of drug compounds. Fentanyl analogs with similar SERS spectra were differentiated by coupling with PS-MS. The limit of detection (LOD) for fentanyl on the paper substrates is 34 µg/mL and 0.32 µg/mL for SERS and PS-MS, respectively. Fentanyl and fentanyl analogs show selective SERS enhancement that helped to detect trace amounts of these opioids in heroin and cocaine street samples. In short, we propose the combination of SERS/PS-MS by using modified paper substrates to develop cost-effective, sensitive, rapid, portable, reliable, and reproducible methods to detect illicit drugs, especially trace amounts of fentanyl and fentanyl analogs in illicit drug mixtures. The combination of these two category A techniques allows for the identification of illicit drugs according to the SWGDRUG guidelines.

Two-dimensional tools for analyzing polymer microstructure; coupling non-aqueous ion-exchange chromatography to size-exclusion chromatography.

Traditional liquid-chromatographic techniques, such as size-exclusion chromatography, (critical) interaction chromatography, and hydrodynamic chromatography, can all reveal certain aspects of polymers and the underlying distributions. The distribution of incorporated acid groups present in polyacrylates can be determined by non-aqueous ion-exchange chromatography, independent of other distributions present. The microstructural details on how this number of acid groups is incorporated in the polymer remains unknown. A low-molar mass polymer molecule with high acid content and a high-molar mass polymer with a low acid content may have the exact same number of acid groups. To take a next step towards understanding the polymer microstructure of water-borne resins, the distribution of incorporated acid groups over the molar-mass distribution has been investigated. For this purpose, an on-line coupling of non-aqueous ion-exchange chromatography (NAIEX) to size-exclusion chromatography (SEC) was established. Practical considerations regarding the system setup with respect to chromatography modes and column- and valve switching dimensionality are discussed. The orthogonality of NAIEX and SEC is demonstrated. Both liquid chromatography modes may be calibrated using polymer standards, yielding a calibrated separation plane. Cross-sectional data on either the molar mass distribution or the acid group distribution at a certain point of the separation plane is obtained. The value of the designed setup was demonstrated by the detailed characterization of the combined acid-group and molar-mass distribution in polymers with a low acid content, in the order of a few mass-%. Several stages of the emulsion polymerization process could be identified using the combined power of NAIEX and SEC.