Quantitative characterization of nanoparticles in blood by transmission electron microscopy with a window-type microchip nanopipet.

Transmission electron microscopy (TEM) is a unique and powerful tool for observation of nanoparticles. However, due to the uneven spatial distribution of particles conventionally dried on copper grids, TEM is rarely employed to evaluate the spatial distribution of nanoparticles in aqueous solutions. Here, we present a microchip nanopipet with a narrow chamber width for sorting nanoparticles from blood and preventing the aggregation of the particles during the drying process, enabling quantitative analysis of their aggregation/agglomeration states and the particle concentration in aqueous solutions. This microchip is adaptable to all commercial TEM holders. Such a nanopipet proves to be a simple and convenient sampling device for TEM image-based quantitative characterization.

Identification of protein domains on major pilin MrkA that affects the mechanical properties of Klebsiella pneumoniae type 3 fimbriae.

The Klebsiella pneumoniae type 3 fimbriae are mainly composed of MrkA pilins that assemble into a helixlike filament. This study determined the biomechanical properties of the fimbriae and analyzed 11 site-directed MrkA mutants to identify domains that are critical for the properties. Escherichia coli strains expressing type 3 fimbriae with an Ala substitution at either F34, V45, C87, G189, T196, or Y197 resulted in a significant reduction in biofilm formation. The E. coli strain expressing MrkAG189A remained capable of producing a normal number of fimbriae. Although F34A, V45A, T196A, and Y197A substitutions expressed on E. coli strains produced sparse quantities of fimbriae, no fimbriae were observed on the cells expressing MrkAC87A. Further investigations of the mechanical properties of the MrkAG189A fimbriae with optical tweezers revealed that, unlike the wild-type fimbriae, the uncoiling force for MrkAG189A fimbriae was not constant. The MrkAG189A fimbriae also exhibited a lower enthalpy in the differential scanning calorimetry analysis. Together, these findings indicate that the mutant fimbriae are less stable than the wild-type. This study has demonstrated that the C-terminal ß strands of MrkA are required for the assembly and structural stability of fimbriae.

Electrical impedimetric biosensors for liver function detection.

In this study, electrical impedimetric biosensors composed of Au-electrodes were fabricated for the quantitative detection of human serum albumin (HSA), an essential biomarker of liver function. The Au-electrodes were fabricated via a single-step photolithography process, and can be easily integrated in biochips for assessing liver function in the future. The glass sensing surface between two adjacent Au-electrodes was modified with 3-aminopropyltriethoxysilane (APTES) to improve the biocompatibility for its subsequent binding to anti-human serum albumin (AHSA). The sensing surface without AHSA binding was blocked using skim milk powders, preventing possible non-specific bonding HSA conjugation. Biosensors were used to measure HSA concentration for liver function detection. The impedance between two adjacent Au-electrodes of the biosensors applied with various HSA concentrations was directly measured, and quantified using an electrochemical impedance spectroscopy system under AC conditions. The results of plotting both values in log scales indicated the impedance increased linearly with HSA conjugation increase. The limit of HSA detection was about 2'10(-4)mg/ml using the electrochemical impedimetric biosensor proposed in this work. This study demonstrates the feasibility of using electrochemical impedimetry as a bio-sensing mechanism to quantify human serum albumin concentration. The sensor proposed in this work also displays great potential for assessing liver function because of its simple detection mechanism, ease of biochip integration, and low cost.

Structural and mechanical properties of Klebsiella pneumoniae type 3 Fimbriae.

This study investigated the structural and mechanical properties of Klebsiella pneumoniae type 3 fimbriae, which constitute a known virulence factor for the bacterium. Transmission electron microscopy and optical tweezers were used to understand the ability of the bacterium to survive flushes. An individual K. pneumoniae type 3 fimbria exhibited a helix-like structure with a pitch of 4.1 nm and a three-phase force-extension curve. The fimbria was first nonlinearly stretched with increasing force. Then, it started to uncoil and extended several micrometers at a fixed force of 66 ± 4 pN (n = 22). Finally, the extension of the fimbria shifted to the third phase, with a characteristic force of 102 ± 9 pN (n = 14) at the inflection point. Compared with the P fimbriae and type 1 fimbriae of uropathogenic Escherichia coli, K. pneumoniae type 3 fimbriae have a larger pitch in the helix-like structure and stronger uncoiling and characteristic forces.

Novel microchip for in situ TEM imaging of living organisms and bio-reactions in aqueous conditions.

A novel and disposable microchip (K-kit) with SiO(2) nano-membranes was developed and used as a specimen kit for in situ imaging of living organisms in an aqueous condition using transmission electron microscopy (TEM) without equipment modification. This K-kit enabled the successful TEM observation of living Escherichia coli cells and the tellurite reduction process in Klebsiella pneumoniae. The K. pneumoniae and Saccharomyces cerevisiae can stay alive in K-kit after continuous TEM imaging for up to 14 s and 42 s, respectively. Besides, different tellurite reduction profiles in cells grown in aerobic and anaerobic environments can be clearly revealed. These results demonstrate that the K-kit developed in this paper can be useful for observing living organisms and monitoring biological processes in situ.