We studied the unzipping of single molecules of double-stranded DNA by pulling one of their two strands through a narrow protein pore. Polymerase chain reaction analysis yielded the first direct proof of DNA unzipping in such a system. The time to unzip each molecule was inferred from the ionic current signature of DNA traversal. The distribution of times to unzip under various experimental conditions fit a simple kinetic model. Using this model, we estimated the enthalpy barriers to unzipping and the effective charge of a nucleotide in the pore, which was considerably smaller than previously assumed.
The dominant molecular species contributing to the 785 nm excited SERS spectra of bacteria are the metabolites of purine degradation: adenine, hypoxanthine, xanthine, guanine, uric acid and AMP. These molecules result from the starvation response of the bacterial cells in pure water washes following enrichment from nutrient rich environments. Vibrational shifts due to isotopic labeling, bacterial SERS spectral fitting, SERS and mass spectrometry analysis of bacterial supernatant, SERS spectra of defined bacterial mutants, and the enzymatic substrate dependence of SERS spectra are used to identify these molecular components. The absence or presence of different degradation/salvage enzymes in the known purine metabolism pathways of these organisms plays a central role in determining the bacterial specificity of these purine-base SERS signatures. These results provide the biochemical basis for the development of SERS as a rapid bacterial diagnostic and illustrate how SERS can be applied more generally for metabolic profiling as a probe of cellular activity.
In this paper, we present a fully integrated lab-on-a-chip and associated instrument for the detection of bacteria from liquid samples. The system conducts bacterial lysis, nucleic acid isolation and concentration, polymerase chain reaction (PCR), and end-point fluorescent detection. To enable truly low-cost manufacture of the single-use disposable chip, we designed the plastic chip in a planar format without any active components to be amenable to injection molding and utilized a novel porous polymer monolith (PPM) embedded with silica that has been shown to lyse bacteria and isolate the nucleic acids from clinical samples (M. D. Kulinski, M. Mahalanabis, S. Gillers, J. Y. Zhang, S. Singh and C. M. Klapperich, Biomed. Microdevices, 2009, 11, 671-678).(1) The chip is made of Zeonex(R), a thermoplastic with a high melting temperature to allow PCR, good UV transmissibility for UV-curing of the PPM, and low auto-fluorescence for fluorescence detection of the amplicon. We have built a prototype instrument to automate control of the fluids, temperature cycling, and optical detection with the capability of accommodating various chip designs. To enable fluid control without including valves or pumps on the chip, we utilized a remote valve switching technique. To allow fluid flow rate changes on the valveless chip, we incorporated speed changing fluid reservoirs. The PCR thermal cycling was achieved with a ceramic heater and air cooling, while end-point fluorescence detection was accomplished with an optical spectrometer; all integrated in the instrument. The chip seamlessly and automatically is mated to the instrument through an interface block that presses against the chip. The interface block aligns and ensures good contact of the chip to the temperature controlled region and the optics. The integrated functionality of the chip was demonstrated using Bacillus subtilis as a model bacterial target. A Taqman assay was employed on-chip to detect the isolated bacterial DNA.
Traditional methods for identifying pathogens in bacteremic patients are slow (24–48+ h). This can lead to physicians making treatment decisions based on an incomplete diagnosis and potentially increasing the patient’s mortality risk. To decrease time to diagnosis, we have developed a novel technology that can recover viable bacteria directly from whole blood and identify them in less than 7 h. Our technology combines a sample preparation process with surface-enhanced Raman spectroscopy (SERS). The sample preparation process enriches viable microorganisms from 10 mL of whole blood into a 200 μL aliquot. After a short incubation period, SERS is used to identify the microorganisms. We further demonstrated that SERS can be used as a broad detection method, as it identified a model set of 17 clinical blood culture isolates and microbial reference strains with 100% identification agreement. By applying the integrated technology of sample preparation and SERS to spiked whole blood samples, we were able to correctly identify both Staphylococcus aureus and Escherichia coli 97% of the time with 97% specificity and 88% sensitivity.
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