Self-Assembled Hydrogel Membranes with Structurally Tunable Mechanical and Biological Properties.

Using supramolecular self-assembled nanocomposite materials made from protein and polysaccharide components is becoming more popular because of their unique properties, such as biodegradability, hierarchical structures, and tunable multifunctionality. However, the fabrication of these materials in a reproducible way remains a challenge. This study presents a new evaporation-induced self-assembly method producing layered hydrogel membranes (LHMs) using tropocollagen grafted by partially deacetylated chitin nanocrystals (CO-g-ChNCs). ChNCs help stabilize tropocollagen's helical conformation and fibrillar structure by forming a hierarchical microstructure through chemical and physical interactions. The LHMs show improved mechanical properties, cytocompatibility, and the ability to control drug release using octenidine dihydrochloride (OCT) as a drug model. Because of the high synergetic performance between CO and ChNCs, the modulus, strength, and toughness increased significantly compared to native CO. The biocompatibility of LHM was tested using the normal human dermal fibroblast (NHDF) and the human osteosarcoma cell line (Saos-2). Cytocompatibility and cell adhesion improved with the introduction of ChNCs. The extracted ChNCs are used as a reinforcing nanofiller to enhance the performance properties of tropocollagen hydrogel membranes and provide new insights into the design of novel LHMs that could be used for various medical applications, such as control of drug release in the skin and bone tissue regeneration.

Effect of changes in tropocollagen residue sequence and hydroxyapatite mineral texture on the strength of ideal nanoscale tropocollagen-hydroxyapatite biomaterials.

Changes in mineral texture (e.g. hydroxyapatite (HAP) or aragonite) and polypeptide (e.g. tropocollagen (TC)) residue sequence are characteristic features of a disease known as osteogenesis imperfecta (OI). In OI, different possibilities of changes in polypeptide residue sequence as well as changes in polypeptide helix replacement (e.g. 3 alpha1 chains instead of 2 alpha1 and 1 alpha2 chain in OI murine) exist. The cross section of the HAP crystals could be needle like or plate like. Such texture and residue sequence related changes can significantly affect the material strength at the nanoscale. In this work, a mechanistic understanding of such factors in determining strength of nanoscale TC-HAP biomaterials is presented using three dimensional molecular dynamics (MD) simulations. Analyses point out that the peak interfacial strength for failure is the highest for supercells with plate shaped HAP crystals. TC molecules with higher number of side chain functional groups impart higher strength to the TC-HAP biomaterials at the nanoscale. Overall, HAP crystal shape variation, the direction of applied loading with respect to the relative TC-HAP orientation, and the number of side chain functional groups in TC molecules are the factor that affect TC-HAP biomaterial strength in a significant manner.

Deformation rate controls elasticity and unfolding pathway of single tropocollagen molecules.

Collagen is an important structural protein in vertebrates and is responsible for the integrity of many tissues like bone, teeth, cartilage and tendon. The mechanical properties of these tissues are primarily determined by their hierarchical arrangement and the role of the collagen matrix in their structures. Here we report a series of Steered Molecular Dynamics (SMD) simulations in explicit solvent, used to elucidate the influence of the pulling rate on the Young's modulus of individual tropocollagen molecules. We stretch a collagen peptide model sequence [(Gly-Pro-Hyp)(10)](3) with pulling rates ranging from 0.01 to 100 m/s, reaching much smaller deformation rates than reported in earlier SMD studies. Our results clearly demonstrate a strong influence of the loading velocity on the observed mechanical properties. Most notably, we find that Young's modulus converges to a constant value of approximately 4 GPa tangent modulus at 8% tensile strain when the initially crimped molecule is straightened out, for pulling rates below 0.5 m/s. This enables us for the first time to predict the elastic properties of a single tropocollagen molecule at physiologically and experimentally relevant pulling rates, directly from atomistic-level calculations. At deformation rates larger than 0.5 m/s, Young's modulus increases continuously and approaches values in excess of 15 GPa for deformation rates larger than 100 m/s. The analyses of the molecular deformation mechanisms show that the tropocollagen molecule unfolds in distinctly different ways, depending on the loading rate, which explains the observation of different values of Young's modulus at different loading rates. For low pulling rates, the triple helix first uncoils completely at 10%-20% strain, then undergoes some recoiling in the opposite direction, and finally straightens for strains larger than 30%. At intermediate rates, the molecule uncoils linearly with increasing strain up to 35% strain. Finally, at higher velocities the triple helix does not uncoil during stretching.

Nanomechanical sequencing of collagen: tropocollagen features heterogeneous elastic properties at the nanoscale.

Collagen is the most important structural protein in biology and is responsible for the strength and integrity of tissues such as bone, teeth, cartilage and tendon. Here we report a systematic computational sequencing of the effect of amino acid motif variations on the mechanical properties of single tropocollagen molecules, with a particular focus on elastic deformation at varying applied strains. By utilizing a bottom-up computational materiomics approach applied to four model sequence motifs found in human type I collagen, we show that variations in the amino acid motif severely influence the elastic behavior of tropocollagen molecules, leading to softening or stiffening behavior. We also show that interpeptide interactions via H-bonds vary strongly with the type of motif, which implies that it plays a distinct role in the molecule's stability. The most important implication of our results is that deformation in tropocollagen molecules is highly inhomogeneous, since softer regions deform more than stiffer regions, potentially leading to strain and stress concentrations within collagen fibrils. We confirm the hypothesis of inhomogeneous molecular deformation through direct simulation of stretching of a segment of tropocollagen from human type I collagen that features the physiological amino acid sequence. Our results show that the biomechanical properties of tropocollagen must be understood in the context of the specific amino acid sequence as well as the state of deformation, since the elastic properties depend strongly on the amount of deformation applied to a molecule.

Role of the nanoscale interfacial arrangement in mechanical strength of tropocollagen-hydroxyapatite-based hard biomaterials.

Nanoscale interfacial interactions between a polypeptide (e.g. tropocollagen (TC)) phase and a mineral (e.g. hydroxyapatite (HAP), aragonite) phase is a strong determinant of the strength of hard biological materials such as bone, dentin and nacre. This work presents a mechanistic understanding of such interfacial interactions by examining idealized TC and HAP interfacial systems. For this purpose, three-dimensional molecular dynamics analyses of tensile and compressive failure in two structurally distinct TC-HAP supercells with TC molecules arranged either along or perpendicular to a chosen HAP surface are performed. Analyses point out that the peak interfacial strength for failure results when the load is applied in the direction of TC molecules aligned along the HAP surface such that the contact area between the TC and HAP phases is at a maximum. Such an alignment also leads to the localization of peak stress over a larger length scale resulting in higher fracture strength. The addition of water is found to invariably cause an increase in the mechanical strength. Overall, analyses point out that the relative alignment of TC molecules with respect to the HAP mineral surface such that the contact area is maximal, the optimal direction of applied loading with respect to the TC-HAP orientation and the increase in strength in a hydrated environment can be important factors that contribute to making nanoscale staggered arrangement a preferred structural configuration in biomaterials.

[Analysis of properties of collagen membranes before and after crosslinked].

OBJECTIVE: To compare the properties of collagen membranes before and after crosslinked and to establish the foundation of application of collagen membranes. METHODS: Fresh bovine tendons were separated and collagen was extracted by washing, smashing and acetic acid dissolving. The collagen protein was determined by ultraviolet spectrophotometer and its characteristics were analyzed by SDS-polyacrylamide gel electrophoresis (SDS-PAGE), wavelength scanning and amino acids detecting. Collagen membranes were produced by lyophilization. And then the biocharacteristics of the membranes before and after glutaraldehyde crosslinked were compared. BMSCs separated from volunteer's bone marrow were seeded on collagen membranes before and after crosslinked by 2 x 10(3) in 100 microL medium, seven days after culture, the absorption spectrum of BMSCs was examined, and BMSCs were observed by scanning electron microscope (SEM). RESULTS: The contents of collagen protein were 2 mg/mL. The maximum absorption wave length appeared at about 230 nm. SDS-PAGE suggested that molecular weight of main bands was more than 66.2 x 10(3), the same as collagen marker from calf skin. There were 21.47% glycine, 12.04% praline and 10.18% hydroxyproline. No tryptophan was found. Before crosslinked, collagen membranes were in shape of white sponges and with big holes and the range of pH value was from 4.5 to 5.0. SEM showed reticular conformation and pore structure of collagen membranes, but the bore diameter was bigger. Their water-absorbing capacity was 61 times as much as their weight. The mechanical strength was 210 g/cm3. The dissolution time of collagenase was 90 minutes. After crossl inked, collagen membranes became thin, colorless, semi-transparent and compact with better tenacity. Under SEM, compact collagen fiber appeared reticular. There was lower water-absorbing capacity and pH value ranged from 6.5 to 7.0. The mechanical strength was 3,400 g/cm3 and the dissolution time of collagenase became longer. BMSCs could grow better either on before-crosslinked collagen membranes or on after-crosslinked ones. CONCLUSION: As biomaterial scaffolds, after crosslinked collagen membranes were better than before-crosslinked ones.