Poly (ethylene glycol) hydrogel scaffolds with multiscale porosity for culture of human adipose-derived stem cells.

Three-dimensional (3 D) hydrogel scaffolds are an attractive option for tissue regeneration applications because they allow for cell migration, fluid exchange, and can be synthesized to closely mimic the physical properties of the extracellular matrix environment. The material properties of hydrogels play a vital role in cellular migration and differentiation. In light of this, in-depth understanding of material properties is required before such scaffolds can be used to study their influence on cells. Herein, various blends and thicknesses of poly (ethylene glycol) dimethacrylate (PEGDMA) hydrogels were synthesized, flash frozen, and dried by lyophilization to create scaffolds with multiscale porosity. Environmental scanning electron microscopy (ESEM) images demonstrated that lyophilization induced microporous voids in the PEGDMA hydrogels while swelling studies show the hydrogels retain their innate swelling properties. Change in pore size was observed between drying methods, polymer blend, and thickness when imaged in the hydrated state. Human adipose-derived stem cells (hASCs) were seeded on lyophilized and non-lyophilized hydrogels to determine if the scaffolds would support cell attachment and proliferation of a clinically relevant cell type. Cell attachment and morphology of the hASCs were evaluated using fluorescence imaging. Qualitative observations in cell attachment and morphology of hASCs on the surface of the different hydrogel spatial configurations indicate these multiscale porosity hydrogels create a suitable scaffold for hASC culture. These findings offer another factor of tunability in creating biomimetic hydrogels for various tissue engineering applications including tissue repair, regeneration, wound healing, and controlled release of growth factors.

Effects of post-processing methods on chitosan-genipin hydrogel properties.

Biopolymer based hydrogel materials are attractive options for a variety of medical applications, including drug delivery and tissue regeneration because of their innate biomimetic material properties. While biopolymers are typically selected for a specific application based off of their chemical properties; the overall material structure of the resulting hydrogel ultimately relates to its ability to function for its intended application. In view of this, it is imperative that the impact of commonly used drying procedures on hydrogel physical properties is well understood. Herein, the effects of post-synthesis drying techniques: air-drying and lyophilization, on genipin crosslinked chitosan hydrogel physical structure were studied. Chitosan-genipin hydrogels synthesized out of either 15 kDa MW or 50-190 kDa MW chitosan were either air-dried (AD), flash-frozen (FF) and then lyophilized, or step-down frozen (SD) and then lyophilized. Environmental scanning electron microscopy (ESEM) was employed to evaluate the resulting hydrogels physical structure as a function of chitosan molecular weight and drying condition. ESEM images revealed the presence of larger microscale pores within the SD samples compared to FF samples, but both treatments yielded the induction of micropore with sizes ranging between 9-400 µm in diameter into the hydrogels. Traditional hydrogel swelling studies were performed to assess the resulting hydrogels swelling profile as a function of chitosan molecular weight and drying treatment. Lyophilized hydrogels showed a five-fold increase in swelling ratio compared to AD hydrogels indicating a change in morphology due to the drying process. The results demonstrate that regardless of polymer molecular weight, post-processing technique had a strong correlation with hydrogel porosity.

Development of Responsive Chitosan-Genipin Hydrogels for the Treatment of Wounds.

Chronic wounds are characterized by an increased bacterial presence, alkaline pH, and excessive wound drainage. Hydrogel biomaterials composed of the carbohydrate polymer chitosan are advantageous for wound healing applications because of their innate antimicrobial and hemostatic properties. Here, genipin-cross-linked-chitosan hydrogels were synthesized and characterized, and their in vitro and in vivo performances were evaluated as a viable wound dressing. Characterization studies demonstrate that the developed chitosan-genipin hydrogels were able to neutralize an environmental pH, while averaging ∼230% aqueous solution uptake, demonstrating their use as a perfusive wound dressing. Bacterial activity studies demonstrate the hydrogels' ability to hinder Escherichia coli growth by ∼70%, while remaining biocompatible in vitro to fibroblast and keratinocyte cells. Furthermore, chitosan-genipin hydrogels promote an enhanced immune response and cellular proliferation in induced pressure wounds in mice. All together, these results reflect the potential of the developed hydrogels to be used as a proactive wound dressing.