Covalent linkage of sulfated hyaluronan to the collagen scaffold Mucograft® enhances scaffold stability and reduces proinflammatory macrophage activation in vivo.

Sulfated glycosaminoglycans (sGAG) show interaction with biological mediator proteins. Although collagen-based biomaterials are widely used in clinics, their combination with high-sulfated hyaluronan (sHA3) is unexplored. This study aims to functionalize a collagen-based scaffold (Mucograft®) with sHA3 via electrostatic (sHA3/PBS) or covalent binding to collagen fibrils (sHA3+EDC/NHS). Crosslinking without sHA3 was used as a control (EDC/NHS Ctrl). The properties of the sHA3-functionalized materials were characterized. In vitro growth factor and cytokine release after culturing with liquid platelet-rich fibrin was performed by means of ELISA. The cellular reaction to the biomaterials was analyzed in a subcutaneous rat model. The study revealed that covalent linking of sHA3 to collagen allowed only a marginal release of sHA3 over 28 days in contrast to electrostatically bound sHA3. sHA3+EDC/NHS scaffolds showed reduced vascular endothelial growth factor (VEGF), transforming growth factor beta 1 (TGF-ß1) and enhanced interleukin-8 (IL-8) and epithelial growth factor (EGF) release in vitro compared to the other scaffolds. Both sHA3/PBS and EDC/NHS Ctrl scaffolds showed a high proinflammatory reaction (M1: CD-68+/CCR7+) and induced multinucleated giant cell (MNGC) formation in vivo. Only sHA3+EDC/NHS scaffolds reduced the proinflammatory macrophage M1 response and did not induce MNGC formation during the 30 days. SHA3+EDC/NHS scaffolds had a stable structure in vivo and showed sufficient integration into the implantation region after 30 days, whereas EDC/NHS Ctrl scaffolds underwent marked disintegration and lost their initial structure. In summary, functionalized collagen (sHA3+EDC/NHS) modulates the inflammatory response and is a promising biomaterial as a stable scaffold for full-thickness skin regeneration in the future.

Exploring Viral Interference Using Peptides: Molecular Determinants of HIV-1 Inhibition by a Peptide Derived from Human Pegivirus-1 Envelope Protein E2.

Co-infection with the human pegivirus 1 (HPgV-1) often has a beneficial effect on disease progression in HIV-1-infected individuals. Several HPgV-1 proteins and peptides, including a 20-mer peptide (P6-2) derived from the N-terminal region of the HPgV-1 surface protein E2, have been associated with this phenomenon, which is referred to as viral interference. We identified the cysteine residues, the hydrophobic core tetrapeptide, as well as the C-terminal negative charge as key factors for the HIV-1 inhibitory activity of P6-2. Analysis of mutations in P6-2-resistant HIV-1 indicated a binding site for the peptide in the HIV-1 envelope glycoprotein gp120. In fact, P6-2 was shown to bind to soluble gp120, as well as to a peptide presenting the gp120 V3 loop. Furthermore, the HIV-1 inhibitory activity of P6-2 could be revoked by the V3 loop peptide, thus indicating a molecular mechanism that involves interaction of P6-2 with the gp120 V3 loop.

Hyaluronan/Collagen Hydrogels with Sulfated Glycosaminoglycans Maintain VEGF165 Activity and Fine-Tune Endothelial Cell Response.

In order to restore the regeneration capacity of large-size vascularized tissue defects, innovative biomaterial concepts are required. Vascular endothelial growth factor (VEGF165) is a key factor of angiogenesis interacting with sulfated glycosaminoglycans (sGAG) within the extracellular matrix. As this interplay mainly controls and directs the biological activity of VEGF165, we used chemically modified sGAG derivatives to evaluate the structural requirements of sGAG for controlling and tuning VEGF165 function and to translate these findings into the design of biomaterials. The in-depth analysis of this interaction by surface plasmon resonance and ELISA studies in combination with molecular modeling stressed the relevance of the substitution position, degree of sulfation, and carbohydrate backbone of GAG. Acrylated hyaluronan (HA-AC)/collagen (coll)-based hydrogels containing cross-linked acrylated, sulfated hyaluronan (sHA-AC) derivatives with different substitution patterns or an acrylated chondroitin sulfate (CS-AC) derivative function as multivalent carbohydrate-based scaffolds for VEGF165 delivery with multiple tuning capacities. Depending on the substitution pattern of sGAG, the release of biologically active VEGF165 was retarded in a defined manner compared to pure HA/coll gels, which further controlled the VEGF165-induced stimulation of endothelial cell proliferation and extended morphology of cells. This indicates that sGAG can act as modulators of protein interaction profiles of HA/coll hydrogels. In addition, sHA-AC-containing gels with and even without VEGF165 strongly stimulate endothelial cell proliferation compared to gels containing only CS-AC or HA-AC. Thus, HA/coll-based hydrogels containing cross-linked sHA-AC are biomimetic materials able to directly influence endothelial cells in vitro, which might translate into an improved healing of injured vascularized tissues.

Hyaluronan/Collagen Hydrogels with Sulfated Hyaluronan for Improved Repair of Vascularized Tissue Tune the Binding of Proteins and Promote Endothelial Cell Growth.

Innovative biomaterial-based concepts are required to improve wound healing of damaged vascularized tissues especially in elderly multimorbid patients. To develop functional hydrogels as 3D cellular microenvironments and as carrier or scavenging systems, e.g., for mediator proteins or proinflammatory factors, collagen fibrils are embedded into a network of photo-crosslinked acrylated hyaluronan (HA), chondroitin sulfate (CS), or sulfated HA (sHA). After lyophilization, the gels show a porous structure and an improved stability against degradation via hyaluronidase. Gels with CS and sHA bind significantly more lysozyme than HA/collagen gels and retard its release. The proliferation and metabolic activity of endothelial cells are significantly increased on sHA gels compared to CS- or only HA-containing hydrogels. These findings highlight the potential of HA/collagen hydrogels with sulfated glycosaminoglycans to tune the protein binding and release behavior and to directly modulate cellular response. This can be easily translated into biomimetic biomaterials with defined properties to stimulate wound healing.