Determination of colloidal and dissolved silver in water samples using colorimetric solid-phase extraction.

The increase in bacterial resistance to antibiotics has led to resurgence in the use of silver as a biocidal agent in applications ranging from washing machine additives to the drinking water treatment system on the International Space Station (ISS). However, growing concerns about the possible toxicity of colloidal silver to bacteria, aquatic organisms and humans have led to recently issued regulations by the US EPA and FDA regarding the usage of silver. As part of an ongoing project, we have developed a rapid, simple method for determining total silver, both ionic (silver(I)) and colloidal, in 0.1-1mg/L aqueous samples, which spans the ISS potable water target of 0.3-0.5mg/L (total silver) and meets the US EPA limit of 0.1mg/L in drinking water. The method is based on colorimetric solid-phase extraction (C-SPE) and involves the extraction of silver(I) from water samples by passage through a solid-phase membrane impregnated with the colorimetric reagent DMABR (5-[4-(dimethylamino)benzylidene]rhodanine). Silver(I) exhaustively reacts with impregnated DMABR to form a colored compound, which is quantified using a handheld diffuse reflectance spectrophotometer. Total silver is determined by first passing the sample through a cartridge containing Oxone, which exhaustively oxidizes colloidal silver to dissolved silver(I). The method, which takes less than 2 min to complete and requires only approximately 1 mL of sample, has been validated through a series of tests, including a comparison with the ICP-MS analysis of a water sample from ISS that contained both silver(I) and colloidal silver. Potential earth-bound applications are also briefly discussed.

Rotationally induced hydrodynamics: fundamentals and applications to high-speed bioassays.

Bioassays are indispensable tools in areas ranging from fundamental life science research to clinical practice. Improving assay speed and levels of detection will have a profound impact in all of these areas. We recently developed a rapid, sensitive format for immunosorbent assays that expedites antigen mass transport by rotating the capture substrate. This review outlines the theoretical foundation of rotationally induced hydrodynamics and its application in heterogeneous assays. We describe a general solution that solves the rates of immunoreactions on rotating capture substrates, taking into account both diffusion and the rate of reaction between antibody and antigen. The general solution applies to a wide range of rotation rates, including mass transport-limited to reaction rate-limited assays, and is validated experimentally. We discuss several applications that demonstrate how immunoassays can be tailored to increase speed as well as lower the limit of detection of viral particles, pathogens, toxins, and proteins.

A rapid, simple method for determining formaldehyde in drinking water using colorimetric-solid phase extraction.

Formaldehyde has been detected in drinking water supplies across the globe and on board NASA spacecraft. A rapid, simple, microgravity-compatible technique for measuring this contaminant in water supplies using colorimetric-solid phase extraction (C-SPE) is described. This method involves collecting a water sample into a syringe by passage through a cartridge that contains sodium hydroxide, to adjust pH, and Purpald, which is a well-established colorimetric reagent for aldehydes. After completing the reaction in the syringe by agitating for 2 min on a shaker at 400 rpm, the 1.0-mL alkaline sample is passed through an extraction disk that retains the purple product. The amount of concentrated product is then measured on-disk using diffuse reflectance spectroscopy, and compared to a calibration plot generated from Kubelka-Munk transformations of the reflectance data at 700 nm to determine the formaldehyde concentration. This method is capable of determining formaldehyde concentrations from 0.08 to 20 ppm with a total work-up time of less than 3 min using only 1-mL samples.