A comparative study of materials assembled from recombinant K31 and K81 and extracted human hair keratins.

Natural biopolymers have found success in tissue engineering and regenerative medicine applications. Their intrinsic biocompatibility and biological activity make them well suited for biomaterials development. Specifically, keratin-based biomaterials have demonstrated utility in regenerative medicine applications including bone regeneration, wound healing, and nerve regeneration. However, studies of structure-function relationships in keratin biomaterials have been hindered by the lack of homogeneous preparations of materials extracted and isolated from natural sources such as wool and hair fibers. Here we present a side-by-side comparison of natural and recombinant human hair keratin proteins K31 and K81. When combined, the recombinant proteins (i.e. rhK31 and rhK81) assemble into characteristic intermediate filament-like fibers. Coatings made from natural and recombinant dimers were compared side-by-side and investigated for coating characteristics and cell adhesion. In comparison to control substrates, the recombinant keratin materials show a higher propensity for inducing involucrin and hence, maturation in terms of potential skin cell differentiation.

A porcine xenograft-derived bone scaffold is a biocompatible bone graft substitute: An assessment of cytocompatibility and the alpha-Gal epitope.

BACKGROUND: Xenografts are an attractive alternative to traditional bone grafts because of the large supply from donors with predictable morphology and biology as well as minimal risk of human disease transmission. Clinical series involving xenograft bone transplantation, most commonly from bovine sources, have reported poor results with frequent graft rejection and failure to integrate with host tissue. Failures have been attributed to residual alpha-Gal epitope in the xenograft which humans produce natural antibody against. To the authors' knowledge, there is currently no xenograft-derived bone graft substitute that has been adopted by orthopedic surgeons for routine clinical use. METHODS: In the current study, a bone scaffold intended to serve as a bone graft substitute was derived from porcine cancellous bone using a tissue decellularization and chemical oxidation protocol. In vitro cytocompatibility, pathogen clearance, and alpha-Gal quantification tests were used to assess the safety of the bone scaffold intended for human use. RESULTS: In vitro studies showed the scaffold was free of processing chemicals and biocompatible with mouse and human cell lines. When bacterial and viral pathogens were purposefully added to porcine donor tissue, processing successfully removed these pathogens to comply with sterility assurance levels established by allograft tissue providers. Critically, 98.5% of the alpha-Gal epitope was removed from donor tissue after decellularization as shown by ELISA inhibition assay and immunohistochemical staining. CONCLUSIONS: The current investigation supports the biologic safety of bone scaffolds derived from porcine donors using a decellularization protocol that meets current sterility assurance standards. The majority of the highly immunogenic xenograft carbohydrate was removed from donor tissue, and these findings support further in vivo investigation of xenograft-derived bone tissue for orthopedic clinical application.

Development and characterization of a biomimetic coating for percutaneous devices.

Percutaneous osseointegrated prosthetics (POP), which consist of a metallic post attached to the bone that extends outward through the skin to connect to an external prosthesis, have become a clinically relevant option to replace the typical socket-residual limb connection. POP devices offer several advantages such as mechanical off-loading of soft tissues, direct force transfer to the musculoskeletal system, greater proprioception, and overall improvement in limb kinesis compared to a socket system. However, POP devices create several challenges including epidermal downgrowth, increased infection risk, and mechanical tearing at the skin-implant interface. To address these issues, biomimetic surfaces and coatings have been developed in an attempt to create an infection-free and cohesive interface between POP devices and skin. The fingernail is a prime example of a natural system with a skin interface that is both mechanically and biologically stable. Exploiting keratins' previously demonstrated tissue compatibility and creating a biomimetic coating for POP devices that can imitate the human fingernail, and demonstrating its ability to promote a stable interface with skin tissue is the goal of this work. Silane coupling aided in producing a coating on titanium substrates consisting of human keratin proteins. Several combinations of silane and keratin derivatives were investigated, and in general showed a nano-scale coating thickness that supported skin cell (i.e. fibroblast and keratinocyte) adhesion. Initial enzyme-mediated degradation resistance was also demonstrated, but the coatings appeared to degrade at long time periods. Importantly, keratinocytes showed a stable phenotype with no indication of wound healing-like activity. These data provide justification to further explore keratin biomaterials for POP coatings that may stabilize the implant-skin interface.

A Decellularized Porcine Xenograft-Derived Bone Scaffold for Clinical Use as a Bone Graft Substitute: A Critical Evaluation of Processing and Structure.

BACKGROUND: Bone grafts are used in approximately one half of all musculoskeletal surgeries. Autograft bone is the historic gold standard but is limited in supply and its harvest imparts significant morbidity to the patient. Alternative sources of bone graft include allografts, synthetics and, less commonly, xenografts which are taken from animal species. Xenografts are available in unlimited supply from healthy animal donors with controlled biology, avoiding the risk of human disease transmission, and may satisfy current demand for bone graft products. METHODS: In the current study, cancellous bone was harvested from porcine femurs and subjected to a novel decellularization protocol to derive a bone scaffold. RESULTS: The scaffold was devoid of donor cellular material on histology and DNA sampling (p < 0.01). Microarchitectural properties important for osteoconductive potential were preserved after decellularization as shown by high resolution imaging modalities. Proteomics data demonstrated similar profiles when comparing the porcine bone scaffold against commercially available human demineralized bone matrix approved for clinical use. CONCLUSION: We are unaware of any porcine-derived bone graft products currently used in orthopaedic surgery practice. Results from the current study suggest that porcine-derived bone scaffolds warrant further consideration to serve as a potential bone graft substitute.

Homo- and heteropolymer self-assembly of recombinant trichocytic keratins.

In the past two decades, keratin biomaterials have shown impressive results as scaffolds for tissue engineering, wound healing, and nerve regeneration. In addition to its intrinsic biocompatibility, keratin interacts with specific cell receptors eliciting beneficial biochemical cues. However, during extraction from natural sources, such as hair and wool fibers, natural keratins are subject to extensive processing conditions that lead to formation of unwanted by-products. Additionally, natural keratins suffer from limited sequence tunability. Recombinant keratin proteins can overcome these drawbacks while maintaining the desired chemical and physical characteristics of natural keratins. Herein, we present the bacterial expression, purification, and solution characterization of human hair keratins K31 and K81. The obligate heterodimerization of the K31/K81 pair that results in formation of intermediate filaments is maintained in the recombinant proteins. Surprisingly, we have for the first time observed new zero- and one-dimensional nanostructures from homooligomerization of K81 and K31, respectively. Further analysis of the self-assembly mechanism highlights the importance of disulfide crosslinking in keratin self-assembly.

The Development of a Xenograft-Derived Scaffold for Tendon and Ligament Reconstruction Using a Decellularization and Oxidation Protocol.

PURPOSE: To evaluate the biological, immunological, and biomechanical properties of a scaffold derived by architectural modification of a fresh-frozen porcine patella tendon using a decellularization protocol that combines physical, chemical, and enzymatic modalities. METHODS: Porcine patellar tendons were processed using a decellularization and oxidation protocol that combines physical, chemical, and enzymatic modalities. Scaffolds (n = 88) were compared with native tendons (n = 70) using histologic, structural (scanning electron microscopy, porosimetry, and tensile testing), biochemical (mass spectrometry, peracetic acid reduction, DNA quantification, alpha-galactosidase [α-gal] content), as well as in vitro immunologic (cytocompatibility, cytokine induction) and in vivo immunologic nonhuman primate analyses. RESULTS: A decrease in cellularity based on histology and a significant decrease in DNA content were observed in the scaffolds compared with the native tendon (P < .001). Porosity and pore size were increased significantly (P < .001). Scaffolds were cytocompatible in vitro. There was no difference between native tendons and scaffolds when comparing ultimate tensile load, stiffness, and elastic modulus. The α-gal xenoantigen level was significantly lower in the decellularized scaffold group compared with fresh-frozen, nondecellularized tissue (P < .001). The in vivo immunological response to implanted scaffolds measured by tumor necrosis factor-α and interleukin-6 levels was significantly (P < .001) reduced compared with untreated controls in vitro. These results were confirmed by an attenuated response to scaffolds in vivo after implantation in a nonhuman primate model. CONCLUSIONS: Porcine tendon was processed via a method of decellularization and oxidation to produce a scaffold that possessed significantly less inflammatory potential than a native tendon, was biocompatible in vitro, of increased porosity, and with significantly reduced amounts of α-gal epitope while retaining tensile properties. CLINICAL RELEVANCE: Porcine-derived scaffolds may provide a readily available source of material for musculoskeletal reconstruction and repair while eliminating concerns regarding disease transmission and the morbidity of autologous harvest.

Evaluating the Past, Present, and Future of Regenerative Medicine: A Global View.

"Evaluating the Past and Present of Regenerative Medicine (RM)" was the first part of an Industry Symposium dedicated to the subject during the 2015 TERMIS World Congress in Boston. This working session presented a critical review of the current RM landscape in Europe and North America with possible projections for the future. Interestingly, the RM development cycle seems to obey the Gartner hype cycle, now at the enlightenment phase, after past exaggerated expectations and discouragements, as suggested by increasing numbers of clinical trials and recent market approvals of RM solutions in both Europe (Glybera and Holoclar® from Chiesi Pharma and Strimvelis® from GSK) and Japan (Remestemcel-L from Mesoblast®). The successful commercial translation of RM research is governed by five major drivers: (i) fully validated manufacturing capability for autologous or allogeneic products, (ii) reimbursement for targeted clinical indications with high and demonstrable medico-economic benefits versus standard of care, (iii) implication of regulatory bodies in the design and development plan of any RM solution, which should be well characterized, robust, with proven consistent efficacy and an acceptable and controlled positive benefit/risk ratio, (iv) collaborations facilitated by multicompetence hubs/consortia of excellence, (v) well-thought-out clinical development plans for reducing the risk of failure. Benefiting from past and present experience, the RM burgeoning industry is expected to accelerate the market release of cost-effective RM products with real curative potential for specific clinical indications with high unmet needs. This should be achieved by wisely leveraging all possible synergies of the different stakeholders, for example, patients, clinicians, reimbursement and health technology assessment (HTA) agencies, regulatory authorities, public/private investors, academia, and companies.

Binding Interactions of Keratin-Based Hair Fiber Extract to Gold, Keratin, and BMP-2.

Hair-derived keratin biomaterials composed mostly of reduced keratin proteins (kerateines) have demonstrated their utility as carriers of biologics and drugs for tissue engineering. Electrostatic forces between negatively-charged keratins and biologic macromolecules allow for effective drug retention; attraction to positively-charged growth factors like bone morphogenetic protein 2 (BMP-2) has been used as a strategy for osteoinduction. In this study, the intermolecular surface and bulk interaction properties of kerateines were investigated. Thiol-rich kerateines were chemisorbed onto gold substrates to form an irreversible 2-nm rigid layer for surface plasmon resonance analysis. Kerateine-to-kerateine cohesion was observed in pH-neutral water with an equilibrium dissociation constant (KD) of 1.8 × 10(-4) M, indicating that non-coulombic attractive forces (i.e. hydrophobic and van der Waals) were at work. The association of BMP-2 to kerateine was found to be greater (KD = 1.1 × 10(-7) M), within the range of specific binding. Addition of salts (phosphate-buffered saline; PBS) shortened the Debye length or the electrostatic field influence which weakened the kerateine-BMP-2 binding (KD = 3.2 × 10(-5) M). BMP-2 in bulk kerateine gels provided a limited release in PBS (~ 10% dissociation in 4 weeks), suggesting that electrostatic intermolecular attraction was significant to retain BMP-2 within the keratin matrix. Complete dissociation between kerateine and BMP-2 occurred when the PBS pH was lowered (to 4.5), below the keratin isoelectric point of 5.3. This phenomenon can be attributed to the protonation of keratin at a lower pH, leading to positive-positive repulsion. Therefore, the dynamics of kerateine-BMP-2 binding is highly dependent on pH and salt concentration, as well as on BMP-2 solubility at different pH and molarity. The study findings may contribute to our understanding of the release kinetics of drugs from keratin biomaterials and allow for the development of better, more clinically relevant BMP-2-conjugated systems for bone repair and regeneration.

In vitro response of macrophage polarization to a keratin biomaterial.

Macrophage response to biomaterials is emerging as a major focus in tissue repair and wound healing. Macrophages are able to differentiate into two distinct states, eliciting divergent effects. The M1 phenotype is considered pro-inflammatory and up-regulates activity related to tissue destruction, whereas the M2 phenotype is considered anti-inflammatory and supports tissue remodeling. Both are necessary but a fine balance must be maintained as dysregulation of naïve macrophages to M1 or M2 polarization has been implicated in several disease and injury models, and has been suggested as a potential cause for poor outcomes. Keratin biomaterials have been shown using different animal models to promote regeneration in several tissues. A potential common mechanism may be the general capability for keratin biomaterials to elicit beneficial inflammatory responses during the early stages of regeneration. In the present study, a keratin biomaterial was utilized in vitro to examine its effects on polarization toward one of these two macrophage phenotypes, and thus its role in inflammation. Exposure of a monocytic cell line to keratin biomaterial substrates was shown to bias macrophages toward an M2 phenotype, while a collagen control surface produced both M1 and M2 macrophages. Furthermore, keratin treatment was similar to the M2 positive control and was similarly effective at down-regulating the M1 response. Keratin biomaterial influenced greater production of anti-inflammatory cytokines and decreased amounts of pro-inflammatory cytokines. The use of a keratin biomaterial in regenerative medicine may therefore provide additional benefit by regulating a positive remodeling response.

The effect of gamma keratose on cell viability in vitro after thermal stress and the regulation of cell death pathway-specific gene expression.

When skin is thermally burned, transfer of heat energy into the skin results in the destruction of cells. Some of these cells are damaged but may be capable of self-repair and survival, thereby contributing to spontaneous healing of the wound. Keratin protein-based biomaterials have been suggested as potential treatments for burn injury. Isolation of cortical proteins from hair fibers results in an acid soluble fraction of keratin proteins referred to as "gamma" keratose. In the present study, treatment with this fraction dissolved in media was able to maintain cell viability after thermal stress in an in vitro model using primary mouse dermal fibroblasts. PCR array analysis demonstrated that gamma keratose treatment may assist in the survival and salvage of thermally stressed cells by maintaining their viability through regulation of cell death pathway-related genes. Gamma keratose may be a promising biomaterial for burn treatment that aids in spontaneous wound healing from viable tissue surrounding the burn.

Reduction of ectopic bone growth in critically-sized rat mandible defects by delivery of rhBMP-2 from kerateine biomaterials.

Absorbable collagen sponges (ACS) are used clinically as carriers of recombinant human bone morphogenetic protein 2 (rhBMP-2) to promote bone regeneration. ACS exhibit ectopic bone growth due to delivery of supraphysiological levels of rhBMP-2, which is particularly problematic in craniofacial bone injuries for both functional and esthetic reasons. We hypothesized that hydrogels from the reduced form of keratin proteins (kerateine) would serve as a suitable alternative to ACS carriers of rhBMP-2. The rationale for this hypothesis is that keratin biomaterials degrade slowly in vivo, have modifiable material properties, and have demonstrated capacity to deliver therapeutic agents. We investigated kerateine hydrogels and freeze-dried scaffolds as rhBMP-2 carriers in a critically-sized rat mandibular defect model. ACS, kerateine hydrogels, and kerateine scaffolds loaded with rhBMP-2 achieved bridging in animals by 8 weeks as indicated by micro-computed tomography. Kerateine scaffolds achieved statistically increased bone mineral density compared to ACS and kerateine hydrogels, with levels reaching those of native bone. Importantly, both kerateine hydrogels and kerateine scaffolds had significantly less ectopic bone growth than ACS sponges at both 8 and 16 weeks post-operatively. These studies demonstrate the suitability of keratins as rhBMP-2 carriers due to equal regenerative capacity with reduced ectopic growth compared to ACS.

Novel keratin (KeraStat™) and polyurethane (Nanosan(R)-Sorb) biomaterials are hemostatic in a porcine lethal extremity hemorrhage model.

Traumatic injury is the leading cause of death in people aged 44 or less in the US. It is also estimated that 82% of deaths from battlefield hemorrhage may be survivable with better treatment options. In this study, two biomaterial hemostats having disparate mechanisms were evaluated in a large animal lethal hemorrhage model and compared to a commercial product and standard cotton gauze. We hypothesized that the biomaterial with a biologically active mechanism, as opposed to a mechanical mechanism, would be the most effective in this model. Using a published study protocol, the femoral artery in swine was punctured and treated. KeraStat™ (KeraNetics) and Nanosan®-Sorb (SNS Nano) hemostats were compared to a commercial chitosan dressing (second generation Hemcon®) and cotton gauze. Both KeraStat and Nanosan increased survival, significantly increased mean arterial pressure (MAP), and significantly decreased shock index compared to both controls. The Hemcon dressing was no different than gauze. Platelet adhesion assays suggested that the KeraStat mechanism of action involves ß1 integrin mediated platelet adhesion while Nanosan-Sorb operates similar to one reported mechanism for Hemcon, absorbing fluid and concentrating clotting components. The Nanosan also swelled considerably and created pressure within the wound site even after direct pressure was removed.

Effect of cyclic strain on tensile properties of a naturally derived, decellularized tendon scaffold seeded with allogeneic tenocytes and associated messenger RNA expression.

Naturally derived tendon scaffolds have the potential to improve the treatment of flexor tendon injuries. Seeded and unseeded tendon scaffolds were maintained in the presence or absence of physiologic strain for 7 days. After 7 days, the tensile properties and associated messenger RNA expression were compared. Seeded scaffolds maintained in the absence of strain had significantly lower tensile properties than unseeded tendons and fresh-frozen tendons. The loss of tensile properties was associated with elevated matrix metalloproteinase-2 and collagen III expression. Tensile properties of seeded scaffolds maintained in the presence of strain for 7 days after seeding did not differ from those of fresh-frozen tendons. This study demonstrates that the tensile properties of seeded, naturally derived tendon scaffolds will degrade rapidly in the absence of cyclic strain. Seeded scaffolds used for tendon reconstruction should be maintained under cyclic strain to maintain essential tensile properties.

The effect of human hair keratin hydrogel on early cellular response to sciatic nerve injury in a rat model.

Peripheral nerve injuries requiring surgery can be repaired by autograft, the clinical "gold standard", allograft, or nerve conduits. Most published clinical studies show the effectiveness of nerve conduits in small size defects in sensory nerves. Many preclinical studies suggest that peripheral nerve regeneration through conduits can be enhanced and repair lengths increased with the use of a biomaterial filler in the conduit lumen. We have previously shown that a luminal hydrogel filler derived from human hair keratin (HHK) can improve electrophysiological and histological outcomes in mouse, rabbit, and non-human primate nerve injury models, but insight into potential mechanisms has been lacking. Based on the premise that a keratin biomaterial (KOS) hydrogel provides an instantaneous structural matrix within the lumen, the current study compares the cellular behavior elicited by KOS hydrogel to Matrigel (MAT) and saline (SAL) conduit fillers in a 1 cm rat sciatic nerve injury model at early stages of regeneration. While there was little difference in initial cellular influx, the KOS group showed earlier migration of dedifferentiated Schwann cells (SC) from the proximal nerve end compared to the other groups. The KOS group also showed faster SC dedifferentiation and myelin debris clearance, and decreased macrophage infiltration during Wallerian degeneration of the distal nerve tissue.

Hemostatic properties and the role of cell receptor recognition in human hair keratin protein hydrogels.

Driven by new discoveries in stem-cell biology and regenerative medicine, there is broad interest in biomaterials that go beyond basic interactions with cells and tissues to actively direct and sustain cellular behavior. Keratin biomaterials have the potential to achieve these goals but have been inadequately described in terms of composition, structure, and cell-instructive characteristics. In this manuscript we describe and characterize a keratin-based biomaterial, demonstrate self-assembly of cross-linked hydrogels, investigate a cell-specific interaction that is dependent on the hydrogel structure and mediated by specific biomaterial-receptor interactions, and show one potential medical application that relies on receptor binding - the ability to achieve hemostasis in a lethal liver injury model. Keratin biomaterials represent a significant advance in biotechnology as they combine the compatibility of natural materials with the chemical flexibility of synthetic materials. These characteristics allow for a system that can be formulated into several varieties of cell-instructive biomaterials with potential uses in tissue engineering, regenerative medicine, drug and cell delivery, and trauma.

Bone regeneration with BMP-2 delivered from keratose scaffolds.

Infuse(®) is used clinically to promote bone repair. Its efficacy is dependent on a crosslinked collagen carrier/scaffold system that has come under scrutiny due to an inability to control BMP-2 release, which may result in unwanted outcomes such as heterotopic ossification. In this study, keratose biomaterial was evaluated as a new carrier/scaffold. Keratose was mixed with BMP-2, fabricated into a scaffold, and implanted into a critical-size rat femoral defect. This construct showed bridging as early as 4 weeks and induced trabecular morphology characteristic of a remodeling hard fracture callus at 16 weeks. Compared to the normal cortical bone, the regenerated tissue had greater volume and mineral content but less density and ultimate shear stress values. Moreover, µ-CT, biomechanics, FTIR-ATR spectroscopy, and polarized light microscopy data showed regeneration using keratose was similar to an Infuse control. However, unlike Infuse's collagen carrier system, in vitro analysis showed that BMP-2 release correlated with keratose scaffold degradation. Surprisingly, treatment with keratose only led to deposition of more bone outgrowth than the untreated negative control at the 8-week time point. The application of keratose also demonstrated a notable reduction of adipose tissues within the gap. While not able to induce osteogenesis on its own, keratose may be the first biomaterial capable of suppressing adipose tissue formation, thereby indirectly enhancing bone regeneration.

A novel process for optimizing musculoskeletal allograft tissue to improve safety, ultrastructural properties, and cell infiltration.

BACKGROUND: This study evaluated the properties of scaffold derived from freeze-dried human Achilles tendon allograft for use in anterior cruciate ligament (ACL) reconstruction. Our hypothesis was that such an allograft could be processed using a method to remove cellular and infectious material, producing a cytocompatible, architecturally modified scaffold possessing tensile properties suitable for ACL reconstruction. METHODS: Fifty-two allografts were provided by a tissue bank. Twenty-one were used as controls to assess cellularity, DNA content, microarchitecture, porosity, cytocompatibility, and tensile properties in vitro (n = 13) and in vivo (n = 8). Thirty-one were processed to produce scaffolds that were similarly assessed for these properties in vitro (n = 23) and in vivo (n = 8). The elimination of added enveloped and nonenveloped viruses was also determined in vitro after each processing step. RESULTS: A subjective decrease in cellularity and a significant decrease in DNA content were observed in the scaffolds compared with the allografts from which they had been derived. The porosity was increased significantly, and the scaffolds were cytocompatible in vitro. Processing resulted in significantly increased elongation of the scaffolds (138% of the elongation of the unprocessed allograft) during tensile testing. No other significant differences in tensile properties were observed in vitro or in vivo. The number of infiltrating host cells and the depth to which those cells infiltrated were significantly greater in the scaffolds. No enveloped viruses and only two of 10(8) nonenveloped viruses were detected in the scaffolds after processing, corresponding to a sterility assurance level of 0.2 × 10(-7). CONCLUSIONS: Allografts were processed using a method that removed cellular and infectious material to produce a decellularized, cytocompatible, architecturally modified scaffold with tensile properties that differed minimally from those of human allograft tissue both in vitro and in vivo. The scaffold production process also resulted in an increase in porosity that led to increased cell infiltration in vivo.

Isolation and culture of primary osteocytes from the long bones of skeletally mature and aged mice.

The purpose of this work was to establish a methodology to enable the isolation and study of osteocytes from skeletally mature young (4-month-old) and old (22-month-old) mice. The location of osteocytes deep within bone is ideal for their function as mechanosensors. However, this location makes the observation and study of osteocytes in vivo technically difficult. Osteocytes were isolated from murine long bones through a process of extended collagenase digestions combined with EDTA-based decalcification. A tissue homogenizer was used to reduce the remaining bone fragments to a suspension of bone particles, which were placed in culture to yield an outgrowth of osteocyte-like cells. All of the cells obtained from this outgrowth that displayed an osteocyte-like morphology stained positive for the osteocyte marker E11/GP38. The osteocyte phenotype was further confirmed by a lack of staining for alkaline phosphatase and the absence of collagen1a1 expression. The outgrowth of osteocytes also expressed additional osteocyte-specific genes such as Sost and Mepe. This technique facilitates the isolation of osteocytes from skeletally mature bone. This novel enabling methodology should prove useful in advancing our understanding of the roles mature osteocytes play in bone health and disease.

Mechanical and biological properties of keratose biomaterials.

The oxidized form of extractable human hair keratin proteins, commonly referred to as keratose, is gaining interest as a biomaterial for multiple tissue engineering studies including those directed toward peripheral nerve, spinal cord, skin, and bone regeneration. Unlike its disulfide cross-linked counterpart, kerateine, keratose does not possess a covalently cross-linked network structure and consequently displays substantially different characteristics. In order to understand its mode(s) of action and potential for clinical translatability, detailed characterization of the composition, physical properties, and biological responses of keratose biomaterials are needed. Keratose was obtained from end-cut human hair fibers by peracetic acid treatment, followed by base extraction, and subsequent dialysis. Analysis of lyophilized keratose powder determined that it contains 99% proteins by mass with amino acid content similar to human hair cortex. Metallic elements were also found in minute quantities. Protein oxidation led to disulfide bond cleavage and drastic reduction of free thiols due to conversion of sulfhydryl to sulfonic acid, chain fragmentation, and amino acid modifications. Mass spectrometry identified the major protein constituents as a heterogeneous mixture of 15 hair keratins (type I: K31-35 and K37-39, and type II: K81-86) with small amounts of epithelial keratins which exist in monomeric, dimeric, multimeric, and even degraded forms. Re-hydration with PBS enabled molecular assembly into an elastic solid-like hydrogel. Highly-porous scaffolds formed by lyophilization of the gel had the compression behavior of a cellular foam material and reverted back to gel upon wetting. Cytotoxicity assays showed that the EC50 for various cell lines were attained at 8-10 mg/mL keratose, indicating the non-toxic nature of the material. Implantation in mouse subcutaneous tissue pockets demonstrated that keratose resorption follows a rectangular hyperbolic regression with 92% degradation by an 8-week time point. Keratose was shown to integrate with the host tissue as evidenced by infiltration of leukocytes and fibroblasts, bulk material angiogenesis, and minimal fibrous encapsulation. Tissue response benchmarks were superior in keratose compared to the control PLGA 90:10 mesh. Finally, the degraded keratose was observed to remodel with the natural collagen extracellular matrix, verifying the benefit of using keratose as a temporary matrix for regenerative medicine applications.

Mechanisms of hepatocyte attachment to keratin biomaterials.

Keratin biomaterials support cellular adhesion, proliferation and migration, which have led to their exploitation in a variety of biomedical applications. The mechanism of cell adhesion to keratin biomaterials, however, is poorly understood. Therefore, the goal of this work was to investigate the mechanisms by which human hair keratin-based biomaterials facilitate cellular adhesion. Hepatocytes were used as a model cell type due to the abundance of published data on cell adhesion mechanisms and their relatively copious attachment to keratin substrates. The roles of ß(1)- and ß(2)-integrins and the hepatic asialoglycoprotein receptor (ASGPR) in hepatocyte adhesion to keratin substrates were studied using attachment assays with and without function blocking antibodies. Blocking of the hepatic integrin subunits did not decrease hepatocyte attachment to keratin. Furthermore, adhesion to keratin did not result in the formation of focal complexes or focal adhesions, nor did it produce an upregulation of phosphorylated-focal adhesion kinase. However, inhibition of hepatic ASGPR decreased the ability of hepatocytes to attach to keratin substrates, which is indicative of the role of this glycoprotein receptor in hepatocyte binding to keratin biomaterials.