Bimolecular based heparin and self-assembling hydrogel for tissue engineering applications.

One major goal of tissue engineering is to develop new biomaterials that are similar structurally and functionally to the extracellular matrix (ECM) to mimic natural cell environments. Recently, different types of biomaterials have been developed for tissue engineering applications. Among them, self-assembling peptides are attractive candidates to create artificial cellular niches, because their nanoscale network and biomechanical properties are similar to those of the natural ECM. Here, we describe the development of a new biomaterial for tissue engineering composed by a simple combination of the self-assembling peptide RAD16-I and heparin sodium salt. As a consequence of the presence of heparin moieties the material acquired enhances the capacity of specific binding and release of growth factors (GFs) with heparin binding affinity such as VEGF165. Promising results were obtained in the vascular tissue engineering area, where the new composite material supported the development of tubular-like structures within a three dimensional (3D) culture model. Moreover, the new scaffold enhances the cell survival and chondrogenic commitment of adipose-derived stem cells (ADSC). Interestingly, the expression of specific markers of mature cartilage tissue including collagen type II was confirmed by western blot and real-time PCR. Furthermore, positive staining for proteoglycans (PGs) indicated the synthesis of cartilage tissue ECM components. Finally, the constructs did not mineralize and exhibited mechanical properties of a tissue undergoing chondrogenesis. Altogether, these results suggest that the new composite is a promising "easy to prepare" material for different reparative and regenerative applications.

Engineered 3D bioimplants using elastomeric scaffold, self-assembling peptide hydrogel, and adipose tissue-derived progenitor cells for cardiac regeneration.

Contractile restoration of myocardial scars remains a challenge with important clinical implications. Here, a combination of porous elastomeric membrane, peptide hydrogel, and subcutaneous adipose tissue-derived progenitor cells (subATDPCs) was designed and evaluated as a bioimplant for cardiac regeneration in a mouse model of myocardial infarction. SubATDPCs were doubly transduced with lentiviral vectors to express bioluminescent-fluorescent reporters driven by constitutively active, cardiac tissue-specific promoters. Cells were seeded into an engineered bioimplant consisting of a scaffold (polycaprolactone methacryloyloxyethyl ester) filled with a peptide hydrogel (PuraMatrix™), and transplanted to cover injured myocardium. Bioluminescence and fluorescence quantifications showed de novo and progressive increases in promoter expression in bioactive implant-treated animals. The bioactive implant was well adapted to the heart, and fully functional vessels traversed the myocardium-bioactive implant interface. Treatment translated into a detectable positive effect on cardiac function, as revealed by echocardiography. Thus, this novel implant is a promising construct for supporting myocardial regeneration.

Matrix dimensions, stiffness, and structural properties modulate spontaneous chondrogenic commitment of mouse embryonic fibroblasts.

Experimental models for cartilage and bone development have been studied in order to understand the biomechanical and biological parameters that regulate skeletal tissue formation. We have previously described that when mouse embryonic fibroblasts (MEFs) were cultured in a three-dimensional (3D)-soft self-assembling peptide nanofiber, the system engaged in a spontaneous process of cartilage-like formation evidenced by the expression of Sox9, Collagen type II, and proteoglycans. In the present work, we studied the influence that matrix mechanical properties have in modulating lineage commitment in an in vitro model of chondrogenesis. This effect was observed only when MEFs were cultured at low elastic modulus values (∼ 0.1 kPa). Interestingly, under these conditions, the system expressed the chondrogenic inductor BMP4 and its antagonist Noggin. On the other hand, at higher elastic modulus values (∼ 5 kPa), the system expressed Noggin but not BMP4, and did not engage in chondrogenesis, which suggest that the balance between bone morphogenetic protein/Noggin could be implicated in the chondrogenic process. Finally, no evidence of hypertrophy was detected under the conditions tested (by assessing expression of Collagen type X and Runx2) unless we challenged the system by co-culturing it with endothelial cells. Importantly, under these new conditions, the system underwent spontaneous matrix calcium mineralization. These results suggest that the 3D-system described here is sensitive to respond to environmental changes such as biomechanical and biological cues.