Unraveling the potential and pore-size dependent capacitance of slit-shaped graphitic carbon pores in aqueous electrolytes.

Understanding and leveraging physicochemical processes at the pore scale are believed to be essential to future performance improvements of supercapacitors and capacitive desalination (CD) cells. Here, we report on a combination of electrochemical experiments and fully atomistic simulations to study the effect of pore size and surface charge density on the capacitance of graphitic nanoporous carbon electrodes. Specifically, we used cyclic voltammetry (CV) and electrochemical impedance spectroscopy (EIS) to study the effect of potential and pore size on the capacitance of nanoporous carbon foams. Molecular dynamics simulations were performed to study the pore-size dependent accumulation of aqueous electrolytes in slit-shaped graphitic carbon pores of different widths (0.65 to 1.6 nm). Experimentally, we observe a pronounced increase of the capacitance of sub-nm pores as the applied potential window gets wider, from a few F g(-1) for narrow potential ranges (-0.3 to 0.3 V vs. Ag/AgCl) to ~40 F g(-1) for wider potential windows (-0.9 V to 0.9 V vs. Ag/AgCl). By contrast, the capacitance of wider pores does not depend significantly on the applied potential window. Molecular dynamics simulations confirm that the penetration of ions into pores becomes more difficult with decreasing pore width and increasing strength of the hydration shell. Consistent with our experimental results, we observe a pore- and ion-size dependent threshold-like charging behavior when the pore width becomes comparable to the size of the hydrated ion (0.65 nm pores for Na(+) and 0.79 nm pores for Cl(-) ions). The observed pore-size and potential dependent accumulation of ions in slit-shaped carbon pores can be explained by the hydration structure of the ions entering the charged pores. The results are discussed in view of their effect on energy-storage and desalination efficiency.

Differential expression of collagen type IV alpha-chains in the tubulointerstitial compartment in experimental chronic serum sickness nephritis.

The expression of collagen type IV chains in the renal tubulointerstitium was investigated during the development of chronic serum sickness (CSS) in rats, a model for immune complex-mediated renal disease. Immunohistochemical studies showed increased expression of alpha4(IV) collagen early during disease development, followed by an increase in alpha1(IV) through alpha3(IV) collagen subchain expression, especially in the tubular basement membrane. Dot-blot and in situ hybridization analysis showed a transient increase in steady-state mRNA levels for all collagen IV subchains during the development of CSS, which was most abundant for alpha1(IV), alpha2(IV), and alpha4(IV). Statistical correlations were found between the mRNA levels of alpha1(IV) and alpha2(IV) collagen and between alpha3(IV) and alpha4(IV), in line with the results of others which showed that these chains are co-distributed as heterotrimer collagen type IV molecules. However, additional correlations were found between the mRNA levels coding for alpha1(IV) and alpha3(IV) collagen, and between alpha1(IV) and alpha4(IV) mRNAs in the course of CSS. These abnormal correlations support the hypothesis that changes occur in the co-expression of the collagen IV subchains during the development of CSS. In addition, a strong correlation was found between the presence in the tubulointerstitium of alpha1(IV) and alpha2(IV) collagen chains, on the one hand, and the tubulointerstitial influx of R73+ and ED1+ cells, on the other, suggesting the involvement of inflammatory cells in the observed alterations in matrix production. Changes in the relative abundance of collagen IV chains in disease states may perturb the collagen IV network in the tubulointerstitial compartment and thereby play a role in the development of renal failure.

Differential expression of collagen IV isoforms in experimental glomerulosclerosis.

Expansion of the glomerular mesangial matrix (MM), thickening of the glomerular basement membrane (GBM), and eventually the development of glomerulosclerosis are often seen in immunologically mediated kidney diseases. In addition to quantitative changes in the extracellular matrix (ECM), qualitative changes in ECM molecules may contribute to alterations in the composition of the glomerular matrix. The expression of collagen IV, alpha 1-5(IV) mRNA, and polypeptides was therefore investigated during the development of chronic graft-versus-host disease (GvHD) in mice, a model for lupus nephritis, and in chronic serum sickness (CSS) in rats, a model for membranous nephropathy. Immunohistochemical studies showed increased mesangial expression of alpha 1 and alpha 2 early in the disease, but only late in the GBM. In contrast, alpha 3 and alpha 4 increased in the GBM during disease, but not in the MM. The mRNA levels for all collagen IV chains were increased in isolated glomeruli before morphological alterations were detectable. The mRNA increase was earlier and more profound for alpha 3, alpha 4 and alpha 5 than for alpha 1 and alpha 2. Expression of alpha 3(IV) was greatest in GvHD, whereas expression of alpha 4 was greatest in CSS. As determined by in situ hybridization (ISH), alpha 1 mRNA was observed dispersed in the glomerulus, but alpha 3, alpha 4, and alpha 5 mRNAs were mainly located in cells at the periphery of the glomerular tuft. The changes in the relative abundance of collagen IV mRNA in disease states may perturb the collagen IV network, altering glomerular structure and function, and may thereby play a central role in the development of glomerulonephritis and glomerulosclerosis.