Development and in-vivo characterization of supramolecular hydrogels for intrarenal drug delivery.

Intrarenal drug delivery from a hydrogel carrier implanted under the kidney capsule is an innovative way to induce kidney tissue regeneration and/or prevent kidney inflammation or fibrosis. We report here on the development of supramolecular hydrogels for this application. We have synthesized two types of supramolecular hydrogelators by connecting the hydrogen bonding moieties to poly(ethylene glycols) in two different ways in order to obtain hydrogels with different physico-chemical properties. Chain-extended hydrogelators containing hydrogen bonding units in the main chain, and bifunctional hydrogelators end-functionalized with hydrogen bonding moieties, were made. The influence of these hydrogels on the renal cortex when implanted under the kidney capsule was studied. The overall tissue response to these hydrogels was found to be mild, and minimal damage to the cortex was observed, using the infiltration of macrophages, formation of myofibroblasts, and the deposition of collagen III as relevant read-out parameters. Differences in tissue response to these hydrogels could be related to the different physico-chemical properties of the three hydrogels. The strong, flexible and slow eroding chain-extended hydrogels are proposed to be suitable for long-term intrarenal delivery of organic drugs, while the weaker, soft and fast eroding bifunctional hydrogel is eminently suitable for short-term, fast delivery of protein drugs to the kidney cortex. The favourable biological behaviour of the supramolecular hydrogels makes them exquisite candidates for subcapsular drug delivery, and paves the way to various opportunities for intrarenal therapy.

Bioengineering of living renal membranes consisting of hierarchical, bioactive supramolecular meshes and human tubular cells.

Maintenance of polarisation of epithelial cells and preservation of their specialized phenotype are great challenges for bioengineering of epithelial tissues. Mimicking the basement membrane and underlying extracellular matrix (ECM) with respect to its hierarchical fiber-like morphology and display of bioactive signals is prerequisite for optimal epithelial cell function in vitro. We report here on a bottom-up approach based on hydrogen-bonded supramolecular polymers and ECM-peptides to make an electro-spun, bioactive supramolecular mesh which can be applied as synthetic basement membrane. The supramolecular polymers used, self-assembled into nano-meter scale fibers, while at micro-meter scale fibers were formed by electro-spinning. We introduced bioactivity into these nano-fibers by intercalation of different ECM-peptides designed for stable binding. Living kidney membranes were shown to be bioengineered through culture of primary human renal tubular epithelial cells on these bioactive meshes. Even after a long-term culturing period of 19 days, we found that the cells on bioactive membranes formed tight monolayers, while cells on non-active membranes lost their monolayer integrity. Furthermore, the bioactive membranes helped to support and maintain renal epithelial phenotype and function. Thus, incorporation of ECM-peptides into electro-spun meshes via a hierarchical, supramolecular method is a promising approach to engineer bioactive synthetic membranes with an unprecedented structure. This approach may in future be applied to produce living bioactive membranes for a bio-artificial kidney.

The use of fibrous, supramolecular membranes and human tubular cells for renal epithelial tissue engineering: towards a suitable membrane for a bioartificial kidney.

A bioartificial kidney, which is composed of a membrane cartridge with renal epithelial cells, can substitute important kidney functions in patients with renal failure. A particular challenge is the maintenance of monolayer integrity and specialized renal epithelial cell functions ex vivo. We hypothesized that this can be improved by electro-spun, supramolecular polymer membranes which show clear benefits in ease of processability. We found that after 7 d, in comparison to conventional microporous membranes, renal tubular cells cultured on top of our fibrous supramolecular membranes formed polarized monolayers, which is prerequisite for a well-functioning bioartificial kidney. In future, these supramolecular membranes allow for incorporation of peptides that may increase cell function even further.

On the role and fate of LPS-dephosphorylating activity in the rat liver.

Gut-derived lipopolysaccharide (LPS) plays a role in the pathogenesis of liver diseases like fibrosis. The enzyme alkaline phosphatase (AP) is present in, among others, the intestinal wall and liver and has been previously shown to dephosphorylate LPS. Therefore, we investigated the effect of LPS on hepatic AP expression and the effect of AP on LPS-induced hepatocyte responses. LPS-dephosphorylating activity was expressed at the hepatocyte canalicular membrane in normal and fibrotic animals. In addition to this, fibrotic animals also displayed high LPS-dephosphorylating activity around bile ducts. The enzyme was shown to dephosphorylate LPS from several bacterial species. LPS itself rapidly enhanced the intrahepatic mRNA levels for this enzyme within 2 h by a factor of seven. Furthermore, in vitro and in vivo studies showed that exogenous intestinal AP quickly bound to the asialoglycoprotein receptor on hepatocytes. This intestinal isoform significantly attenuated LPS-induced hepatic tumor necrosis factor-alpha and nitric oxide (nitrite and nitrate) responses in vitro. The enzyme also reduced LPS-induced hepatic glycogenolysis in vivo. This study shows that LPS enhances AP expression in hepatocytes and that intestinal AP is rapidly taken up by these same cells, leading to an attenuation of LPS-induced responses in vivo. Gut-derived LPS-dephosphorylating activity or enzyme upregulation within hepatocytes by LPS may therefore be a protective mechanism within the liver.

Protection against an Escherichia coli-induced sepsis by alkaline phosphatase in mice.

Alkaline phosphatase (AP) is a phosphate transferase present in bacteria and eukaryotes. In previous studies, we have shown that AP is able to dephosphorylate lipopolysaccharide (LPS) at physiological pH levels. Because LPS is the causative agent of gram-negative sepsis, we hypothesize that AP might be used as a medication during early stages of LPS-induced septic shock. We have demonstrated protective effects of AP when this enzyme was administered simultaneously with LPS. However, a major question of anti-LPS therapies is whether they are also effective after systemic infiltration of whole bacteria and if they also act in later stages of the disease. To test this, we explored the protective effects of AP from human placenta (plAP) in a bacterial challenge model in Balb/c mice. AP was intravenously administered 20 min after a bacterial intraperitoneal inoculation of 2 to 5 x 10 CFU of Escherichia coli suspended in a 100-microL volume of saline. It was shown that AP attenuated the systemic host response upon E. coli. Body temperature was normalized as compared with untreated septic mice. Also, serum nitric oxide levels 24 h after the injection of bacteria were reduced almost to control levels in mice that received AP. Moreover, survival after 24 h was significantly higher in the AP-treated group compared with the nontreated control group.

Removal of phosphate from lipid A as a strategy to detoxify lipopolysaccharide.

Lipopolysaccharide (LPS) may cause sepsis when it enters the blood circulation. The toxic moiety of LPS is the well-preserved lipid A part. Lipid A contains two phosphate groups attached to diglucosamine, which are crucial for the many biological activities of LPS. In previous studies we found that alkaline phosphatase (AP) was able to dephosphorylate LPS. To test whether LPS-dephosphorylation can be used for intervention during sepsis, we investigated the effects of Salmonella minnesota Re 595 LPS and its dephosphorylated counterpart monophosphoryl lipid A (MPLA) on macrophage activation in vivo and in vitro. Exposure of RAW264.7 cells to LPS induced high levels of tumor necrosis factor (TNFalpha) and nitric oxide (NO), whereas MPLA elicited no response. LPS in vivo induced a significant rise in TNFalpha levels in mice and an enhanced inflammatory cell influx in the lung, whereas MPLA did not. Having shown the relevance of this particular phosphate group of LPS, we subsequently explored the LPS-dephosphorylating ability of AP in different tissues, and the effect of AP administration in mice challenged with LPS. Histochemical data show that AP dephosphorylated native LPS in all tissues examined, whereas MPLA was not dephosphorylated. When mice received AP immediately after the LPS challenge, the survival rate was 100%, over 57% in the control group. We conclude that the enzymatic removal of phosphate groups from LPS by AP represents a crucial detoxification reaction, which may provide a new strategy to treat LPS-induced diseases like sepsis.