Hydrogels for Urinary Tract Tissue Engineering

Several urinary tract disorders, such as hypospadias or bladder cancer, require reconstructive surgery to preserve the patient's quality of life and at times even save their life. The current available surgical treatments, involving grafts from other tissue origin, can, however, lead to long-term complications in up to 50% of these patients. New alternatives are therefore considered among which tissue-engineered grafts are thought to be the most promising approach. Tissue-engineered grafts have so far been shown to require the presence of cells, which involves different steps prior to implantation including cell isolation and expansion, seeding on a matrix, and further culture. These steps are time-consuming, costly, and raise safety concerns regarding the in vitro cultured cells. In this thesis, we sought to further improve some tissue-engineered grafts with approaches that would either reduce or replace the cell culture steps. One of these approaches relied on the plastic compression of collagen gels. Ready cell-seeded plastic compressed collagen gels can be rapidly formed within minutes and have much better mechanical properties than regular collagen gels that are known to be fragile. In order to have a stronger gel we adapted the plastic compression concept and developed high-density collagen gels tubes (hdCGTs) for urinary tract tissue-engineering. We demonstrated that they were suitable for smooth muscle cell (SMC) proliferation and that their mechanical response to dilation and extension were compatible with ureter and urethra physiologic values. Hence, these ready-seeded hdCGTS represent promising tissue-engineered constructs that can shorten the production time of cell-seeded grafts for urinary tract regeneration. We further tested our hdCGTs in a rabbit model to investigate their regenerative capacity in vivo. Autologous rabbit SMCs were isolated from a bladder biopsy to form cellular constructs, while acellular constructs were used as control. Both types of constructs were sealed with fibrin glue at the site of a newly created urethral defect. Rabbits were evaluated by retrograde urethrography after 1 or 3 months. Despite a high rate of fistula and a relative narrowing of graft calibers, all rabbits survived and showed micturition within 1-3 days following surgery. SMC-seeded grafts showed, however, a better outcome at 3 months in accordance to literature. Since plastic compressed collagen gels are still too weak to be sutured, we decided to strengthen them by combining them with a polymer mesh. We investigated flat collagen-poly(lactic acid-co-ε-caprolactone) (PLAC) hybrid scaffolds seeded with human bladder cells for their behaviour in the subcutaneous space of nude mice. Host cell infiltration, scaffold degradation, and the presence of the seeded bladder cells were analyzed at different time points on a total period of 6 months. The hybrids showed a lower inflammatory reaction in vivo than PLAC meshes alone, and first signs of polymer degradation were visible at six months. The collagen-PLAC hybrids have potential for urinary tract tissue regeneration as they show efficient cell seeding and proliferation as well as proper mechanical properties for surgical handling. Another approach towards improving tissue-engineered grafts was to use off-the-shelf smart biomatrices to replace the cell culture steps. This involved the development of cell-controlled release of insulin-like growth factor-1 (IGF1) in an acellular collagen matrix. IGF1 induces SMC migration, proliferation, and differentiation, and can hence promote the invasion and population of the acellular matrix by cells in the surrounding tissue once implanted in vivo. In this approach, we designed and produced a recombinant collagen-binding IGF1. The IGF1 domain would then be released after cleavage from an affinity binding domain to collagen under the action of cell-secreted matrix metallo-proteases (MMP). Although our recombinant IGF1 showed the expected bioactivity on SMCs and sensitivity to MMP-2, its affinity for type I collagen (Col-I) could not be demonstrated. We further investigated covalent binding alternatives involving transglutaminase (TG) crosslinking or IGF binding protein (IGFBP)-mediated binding to collagen. TG crosslinking did not allow for sufficient amount of a TG-IGF, a recombinant form of IGF1 presenting a substrate sequence for plasma TG, to be bound to Col-I. The entrapment of IGFBP5 within plastic compressed collagen gels however suggests that collagen compression and collagen-binding means could be combined in order to allow for a more controlled-release profile of IGF1 from collagen gels. Lastly, we sought to develop a new bioengineered solution for bladder sphincter disorders, such as urinary incontinence or vesico-ureteral reflux. These disorders are treated with open surgeries susceptible of complications and extended hospital stay. Endoscopic treatment by injection of bulking agents is thus usually preferred, although they often necessitate additional interventions for a sustained effect. With the idea to suppress this need for additional intervention and thus to limit discomfort for patients as well as costs, we sought for a permanent bulking agent. We therefore developed an injectable poly(acrylonitrile) hydrogel paste injected into the submucosal space of pig bladders. The implants were harvested at days 7, 14, 21, 28, 84, and 168 and analyzed morphologically and by histology. The persistence of the implants was demonstrated, indicating that this injectable bulking agent could potentially be used as biomaterial for the treatment of urinary incontinence and vesico-ureteral reflux.

Bio-engineered collagen-fibrin scaffolds for enhancing urological tissue regeneration

Elif Vardar

Urological tissue engineering offers alternative solutions for congenital and acquired diseases of the urinary tract, which may require reconstructive surgery. It evolves to overcome complications, which might be encountered after surgery. Therefore, tissue-engineered scaffolds hold great promise for addressing these complications. Collagen type I is the most abundant structural extracellular matrix protein in the human body. Fibrin involves in the clotting of blood within healing wounds, and has inherited integrin and growth factor binding sites. Bioreactors transmit tissue specific environmental cues to the engineered scaffolds. Moreover, the addition of bioactive molecules in combination with controlled delivery enhances the generation of functional tissues. In the first part of the thesis, a new flow bioreactor system, mimicking physiological flow conditions in the human ureter, was developed and optimized. Human urinary tract smooth muscle (hSMC) cells were integrated within compressed tubular collagen scaffolds, prior to seeding human urinary tract urothelial cell (hUC) on the luminal surface of the scaffolds. The ureter flow mimicking conditions supported an evident cell proliferation and differentiation for both cell types. Superior extracellular matrix (ECM) protein deposition on collagen tubes was observed under dynamic conditions. Hence, our flow bioreactor design allowed producing ECM-like and large-scale collagen tubes to address ureter tissue repairs. In the second part of the thesis, a recombinant human insulin-like growth factor 1 (IGF-1) variant was produced and was used to functionalize a multilayered scaffold consisting of fibrin layer, sandwiched between two collagen gels. The IGF-1 variant was covalently conjugated to fibrin and had a matrix metalloproteinase-cleavage tag to obtain cell-mediated delivery of the protein. The purified IGF-1 variant showed similar bioactivity compared to commercially available IGF-1. Finally, in vivo evaluation of these multilayered collagen-fibrin scaffolds was performed in a nude rat model to investigate their regenerative capacity. Four weeks post implantation results showed that the IGF-1 variant induced a dose-dependent host smooth muscle cell invasion to the implant area. Thus, this bioactive collagen-fibrin scaffold may offer an advanced approach to accelerate bladder regeneration. In the third part of thesis, a collagen-fibrin bead gel system was developed and characterized to evaluate its potential use as an injectable bulking material. A microfluidics-based fabrication method was employed to obtain the fibrin beads. This method enabled us to obtain fibrin beads with precisely controlled sizes and as well as conjugate recombinant proteins without affecting its biological activity. In vitro, fibrin beads had a positive effect on hSMC proliferation, viability, and migration. To ensure its injectability, fibrin beads were then embedded into collagen gel. After further testing in an in vivo model, this bioactive collagen-fibrin bead gel system might have a have great potential in long-term functional urinary muscle tissue restoration. Overall, this work highlights that collagen-fibrin hybrid materials can be designed as multifunctional scaffolds in different forms and shapes.

EPFL2015

Tissue engineering of the bladder

Catharina Adelöw

Stem cell use in bladder tissue engineering is a recently addressed area of investigation that has generated excitement as a novel way to restore and regenerate lost or damaged urinary bladder tissue. The remodelling of smooth muscle plays a significant role in bladder repair and regeneration. De-differentiation of smooth muscle cells from a contractile phenotype to a synthetic proliferative phenotype is characterised by smooth muscle hypertrophy and fibrosis, and leads to a poorly compliant bladder. To elucidate the underlying mechanisms of such phenomena, recent efforts in bladder tissue engineering have focused on understanding smooth muscle biology and associated mechanisms of bladder diseases. In this thesis we have designed a synthetic poly (ethylene glycol) (PEG) hydrogel for stem cell and drug delivery aimed to enhance control smooth muscle cell phenotype and thus assist in bladder repair and regeneration. We began by developing a method for isolation of cells from the bladder wall. Traditionally urothelium and smooth muscle cells are separated by dissection, and primary cultures are initiated in distinctly different medium formulations to obtain homogenous cultures and limit contaminating cells. However, the bladder wall harbours, apart from urothelial and smooth muscle cells, fibroblasts that have similar nutritional requirements and are likely candidates to contaminate smooth muscle cell cultures. Isolation of these three cell types by conjugation to magnetic beads and repeated separations allowed us to obtain pure cell populations. Furthermore, this technique permitted us to freely choose any specific medium formulation we wished to utilise. We then turned our attentions to engineering a materials system, by chemically and physically tuning a PEG hydrogel in terms of ligand concentration and matrix stiffness, to provide a three-dimensional environment for optimal spreading of human smooth muscle cells and mesenchymal stem cells. Cell viability, proliferation and differentiation were assessed in optimised hydrogels. Compared to cultures on traditional two-dimensional plastic, mesenchymal stem cells cultured within our three-dimensional hydrogels acquired a smooth muscle cell-like phenotype and smooth muscle cells obtained a less de-differentiated phenotype. In addition, we demonstrated cell-demanded gel degradation and deposition of newly synthesised extracellular matrix proteins. In order to modulate cell phenotypes further, we hypothesised that cell differentiation could be directed by the adhesion ligands made available within the matrix. In this manner, cells that were exposed to a matrix presenting certain integrin-binding ligands would begin expressing the corresponding integrins in order to adhere to the matrix. Consequently, we explored the effect of various specific integrin-binding ligands on mesenchymal stem cell integrin expression and differentiation. Fibronectin (FN) fragments engineered to demonstrate specificity to different integrins, namely α5β1 (FNIII910) and αvβ3 (FNIII10), were conjugated to PEG functionalised with vinyl sulfone and compared to fibronectin wild type (FNIIIWT) fragment and the RGD peptide, which both provide binding sites for a range of integrins. We found that assembly of focal adhesions and formation of stress fibres were altered due to the specific fragments provided, and expression of integrin- and smooth muscle cell specific genes varied in mesenchymal stem cells cultured within hydrogels functionalised with different fragments. Moreover, these fibronectin fragments turned out to be especially helpful for improved attachment of urothelial cells on top of hydrogels. With this biomaterial system in hand, we sought to develop a co-culture model of the bladder wall that permitted mesenchymal stem cells and urothelial cells cultured within / on top of PEG hydrogels, and to explore the combinatorial effect of ligand binding and cell-cell interactions on mesenchymal stem cell fate. Interestingly, we found that co-culturing with urothelial cells influenced gene expression of mesenchymal stem cells differently, depending on the protein fragment to which they were adhering. Mesenchymal stem cells cultured within PEG-FNIIIWT hydrogels were shown to up-regulate smooth muscle cell specific genes, while down-regulation was demonstrated in PEG-RGD, PEG-FNIII910 and PEG-FNIII10 hydrogels. Again, mesenchymal stem cells cultured within PEG-FNIIIWT hydrogels were shown to up-regulate integrin expressions α5, αv, β1 and β3, while down-regulation of the same genes was demonstrated for cells cultured within PEG-FNIII9*10 hydrogels, and a more complex pattern of integrin regulation was found for cells cultured within PEG-RGD and PEG-FNIII10 hydrogels. Finally, we investigated a novel approach to growth factor delivery in a controlled release manner, by providing cell- and growth factor binding protein fragments. In this system we show that transforming growth factor beta 1 (TGF-β1) release from PEG hydrogels influence smooth muscle cell specific gene expressions differently depending on the integrin- and growth factor binding proteins available within the hydrogel. Delivery of TGF-β1 within PEG-FNIIIWT hydrogels was shown to up-regulate smooth muscle specific genes in mesenchymal stem cells, while the other conditions displayed more complex patterns of gene expression. Further experiments are required to characterise the conjugation of PEGprotein-growth factor, and the release profiles for the growth factor in the different conditions. In conclusion, this thesis investigates the effect of various chemical and physical signals on mesenchymal stem cell-to-smooth muscle cell differentiation in an in vitro model to further understand cell-cell and cell-extracellular matrix interactions and create improved artificial microenvironments for directing and / or maintaining cell differentiation. The PEG hydrogel that we designed permits the co-culture of cells as well as the incorporation of peptides and proteins such as cell adhesion- and growth factor binding ligands, and growth factors for directing the differentiation of human mesenchymal stem cells into smooth muscle cells. Here, we explore these features and their effects on cell differentiation in vitro. Hence, our PEG hydrogel system can serve both as an in vitro model for studying basic cell biology, and as a cell delivery vehicle for improved bladder tissue regeneration.

EPFL2009

Tissue engineering of the bladder

Catharina Adelöw

EPFL2009

Bio-engineered collagen-fibrin scaffolds for enhancing urological tissue regeneration

Elif Vardar

EPFL2015