Spatially focused deposition of capillary electrophoresis effluent onto surface-enhanced Raman-active substrates for off-column spectroscopy.

Surface-enhanced Raman scattering (SERS) is employed to obtain distinctive spectra of compounds that are efficiently separated by capillary electrophoresis (CE) and deposited onto planar SERS-active substrates. A simple method is described that explains how to prepare SERS-active substrates by depositing a silver-colloid solution onto frosted-glass microscope slides, using a high-efficiency nebulizer. Scanning electron micrographs reveal a layered coating of fairly uniform-sized, 100-nm silver nanoparticles with interstitial spaces ranging from a few to tens of nanometers. The on-column separation is monitored by laser-induced fluorescence, while electrofilament depositing the CE effluent onto a moving SERS-substrate. Subsequently, the SERS spectra and off-column electropherograms are obtained with a simple confocal Raman spectrometer. The test compounds used to demonstrate this technique include compounds of biological significance: benzyloxyresorufin, riboflavin, and resorufin. CE and Raman conditions are evaluated to determine their affects on the SERS signals. An average off-column efficiency of 100,000 plates/m and a signal reproducibility of 11% relative standard deviation were achieved. Characteristic spectra with major Raman bands exhibiting signal-to-noise ratios of greater than 3 were obtained for a 3.2-nL injection of 10(-6) M (706 fg) resorufin. Forming a self-assembled monolayer (SAM) on the substrate increases the sensitivity of the SERS technique and decreases the on-substrate broadening. Calibration plots for both plain- and SAM-SERS substrates are demonstrated.

Processes involved in the development of latent fingerprints using the cyanoacrylate fuming method.

Chemical processes involved in the development of latent fingerprints using the cyanoacrylate fuming method have been studied. Two major types of latent prints have been investigated-clean and oily prints. Scanning electron microscopy (SEM) has been used as a tool for determining the morphology of the polymer developed separately on clean and oily prints after cyanoacrylate fuming. A correlation between the chemical composition of an aged latent fingerprint, prior to development, and the quality of a developed fingerprint has been observed in the morphology. The moisture in the print prior to fuming has been found to be more important than the moisture in the air during fuming for the development of a useful latent print. In addition, the amount of time required to develop a high quality latent print has been found to be within 2 min. The cyanoacrylate polymerization process is extremely rapid. When heat is used to accelerate the fuming process, typically a period of 2 min is required to develop the print. The optimum development time depends upon the concentration of cyanoacrylate vapors within the enclosure.

Electrofilament deposition and off-column detection of analytes separated by capillary electrophoresis.

Capillary electrophoresis interfaced with electrospray is a convenient technique for continuously transferring column effluent from capillary-to-planar format. Conditions are optimized to produce a narrow (approximately 20 microm) liquid filament (electrofilament), which is capable of depositing spatially focused bands with track widths that are routinely 100 microm. A fiber optic-based, laser-induced fluorescence cell is employed to monitor the separation on-column while the separated bands are deposited onto a moving substrate. The photodetection of deposited bands is accomplished by using either a charge-coupled device camera or a photomultiplier tube. Deterioration of on-column separation performance is observed when the electrofilament voltage is applied. Elevating the inlet of the capillary column, to provide hydrodynamic flow, restores separation performance. Substrate temperature and translational rates are optimized with respect to both off-column separation efficiency and signal intensity. Off-column separation efficiencies of 65 000 plates per meter were achieved. A linear dynamic range of 10(3) and a limit of detection of 10(-8) M were obtained for kiton red deposited onto a reversed phase thin-layer chromatography plate. To demonstrate the applicability of this technique to more complex separation solutions, a dye mixture was successfully separated and deposited with sodium dodecyl sulfate in the running buffer.