Collagen For Tissue Engineering Research Articles

Tissue-engineered collagen matrix loaded with rat adipose-derived stem cells/human amniotic mesenchymal stem cells for rotator cuff tendon-bone repair

The rotator cuff tendon-bone interface tissue exhibits high heterogeneity in its composition and structure, with collagen being its primary component. Here, we prepared tissue-engineered decellularized live hyaline cartilage grafts (dLHCG), this dLHCG scaffold's bioactive ECM mainly consists of collagen II, proteoglycans, and fibronectin, presenting a cartilage-like lacuna microstructure. The dLHCG scaffold loaded human amniotic mesenchymal stem cells (hAMSCs) and adipose stem cells (ADSCs) were implanted into the interface. The dLHCG scaffold could maintain the pluripotency of stem cells, supporting the proliferation, osteogenic differentiation, and tenogenic differentiation of the MSCs. The collagen II, through the integrin α2β1-FAK-JNK signaling axis, promotes Runx-2 activation, playing a better regulatory role in the early osteogenic differentiation of MSCs, enhancing bone defect repair through an endochondral ossification process. The in vivo rat model demonstrated that 12 weeks post-operation, the MSC-loaded dLHCG scaffold group exhibited continuous aligned collagen fibers at the tendon-bone interface, with significantly enhanced biomechanical function compared to the control group. The dLHCG scaffold create an efficient interface, which promoting the restoration of the soft-hard gradient structure tissue at the junction between the scaffold and the host tissue, thereby providing a rational and promising strategy for the rapid healing of the rotator cuff injury.

Issues in the design of tissue-engineered collagen constructs and some approaches to their solution: A review

This review article analyzes modern literature sources on the design of bioinks and tissue-engineered constructs on the basis of soluble forms of collagen, including gelatin. The choice of soluble forms of collagen as a biopolymer basis for bioinks and this type of constructs is determined by their unique biocompatibility, bioresorbability, as well as the presence of adhesive sites (motifs) for binding cells with their subsequent proliferation and organ or tissue maturation. However, the poor mechanical properties of products derived from soluble collagens, rapid biodegradation, tendency to lose the solubility of highly viscous solutions when stored or with pH increase limit their application in tissue engineering. The use of more stable low-viscosity collagen solutions does not enable the creation of dimensionally stable tissue-engineered constructs. It is shown that the introduction of various water-soluble biocompatible polymeric additives into hydrogels on the basis of soluble collagens allows the above-mentioned problems to be solved, as well as providing a means to customize the required characteristics of bioinks and tissue-engineered constructs. The additives that improve their characteristics include biopolymers: silk sericin and fibroin, as well as alginates and fibrinogen, which can form cross-links in the presence of Ca2+. This type of crosslinking is shown to further improve the performance of these constructs. All of these biopolymers are commercially available. The article comparatively analyzes approaches to stabilizing the shape, improving the mechanical properties, and adjusting the bioresorption time of 3D printed tissue-engineered constructs during organ or tissue maturation.

Treatment of chronic and complex meniscal tears with arthroscopic meniscus repair augmented with collagen matrix wrapping: failure rate and functional outcomes

PurposeMeniscal wrapping is a fully arthroscopic technique that involves enhanced meniscal repair with a tissue-engineered collagen matrix wrapping. This study aims to investigate the feasibility of using the meniscal wrapping technique for the treatment of chronic or complex meniscal tears. The primary objective is to assess its failure rate. The secondary objectives are to analyse complication rate, functional outcomes and overall patient satisfaction.MethodsThis retrospective case series study included patients who sustained chronic and complex tears undergoing meniscal wrapping with autologous liquid bone marrow injection. Failure rate was considered if the patient underwent partial or complete meniscectomy or knee replacement during the follow-up, while other unexpected knee reoperations were considered as complications. Clinical outcomes were evaluated through the IKDC score, Tegner Activity Score and Short Assessment of Patient Satisfaction.ResultsTwenty-one patients were included (15 non-acute bucket-handle tears, three non-acute horizontal tears and three non-acute complex injuries). The failure rate was 9.5% at 33 months. The rate of other unplanned reoperations was 14.3%, but none of these complications were apparently directly related to the wrapping technique. The average postoperative IKDC was 73.3/100. No statistically significant difference was encountered between preinjury and postoperative Tegner Activity Score. The mean overall patient satisfaction was 88.3/100.ConclusionsMeniscal wrapping can be safely used as an adjunctive technique to meniscal repair in such difficult-to-treat cases to preserve the meniscus. The technique achieves a low failure rate and promising results of knee function, and patient satisfaction.

Review on the fish collagen-based scaffolds in wound healing and tissue engineering

Collagen from marine organisms is an emerging source in tissue engineering, an alternative to bovine and porcine collagen. Despite the positive results on wound healing from fish collagen scaffolds, the comprehension and advancements in its properties are limited. Given this context, this study aimed to carry out a systematic review to examine the effects of collagen scaffolds on different models of experimental skin wounds, the advantages and its limitations. The search was conducted according to the orientations of Preferred Reporting Items for Systematic review and Meta-Analysis (PRISMA) and the MeSH (Medical Subject Healings) terms used were “Fish Collagen” AND “Wound Healing” AND “Scaffold”. 36 articles in total were sorted out from the databases of Google Scholar and PubMed. After the analysis, the current review covers 10 articles from the beginning of 2017 to March 2023. The results are mainly focused on the different methods of collagen extraction, preparation of scaffolds and its treatment on the animal model along with its effects. To infer, this current review states that, despite the positive effects of collagen on tissue repair and regeneration, no product is available for medical purposes. Thus, this review also demonstrates the huge potential for collagen in tissue engineering.

Impact of SiO2 nanoparticles on the structure and property of type I collagen in three different forms

Silica-based nanoparticles have found application in the development of biocomposites involving reconstituted collagen in tissue engineering and wound healing, and leather modification, specifically targeting collagen fibers. However, a comprehensive investigation into the interaction between collagen-silica nanoparticles and different forms of collagen using biophysical methods remains unexplored. In this study, we examined the interaction between silica (SiO2) nanoparticles and collagen in its fiber, microfibril, and monomer forms through high-resolution scanning electron microscopy, circular dichroism, Fourier-transform infrared spectroscopy, fluorescence analysis, zeta potential measurements, and turbidity assays. Our results reveal that SiO2 nanoparticles exhibited a non-specific attraction towards collagen fibers without disrupting their structural integrity. Interestingly, SiO2 nanoparticles influenced the process of microfibrillation, resulting in heterogeneous fibril diameters while maintaining the natural D-periodicity. This finding is significant, as fibril size variations can impact the properties of collagen composites. Notably, the triple helical structure of collagen in its monomer form remained unaffected in the presence of SiO2 nanoparticles, indicating that the nanoparticles did not disrupt the electrostatic interactions that stabilize the triple helix. Additionally, the increased stability of SiO2 nanoparticles in the presence of collagen confirmed their interaction. These findings provide a promising avenue for the development of SiO2-based nanoparticles to enhance the stability of collagen fibers and control fiber sizes for biomaterial preparation. Moreover, this study advances the potential application of SiO2-based nanoparticles in leather tanning, an emerging field where nanoparticles can play a crucial role.

Profiling the impact of choline chloride on the self-assembly of collagen mimetic peptide (Pro-Hyp-Gly)10

The promising applications of collagen in tissue engineering, regenerative medicine and biomaterials have intrigued great interest in development of collagen mimetic peptides (CMPs). In past decades, the large-scale collagen structures via the self-assembly of small CMPs have been extensively explored. Moreover, CMPs entail novel strategies in order to play a critical role in the discovery of new generation biomaterials. In this regard, we herein have synthesized a CMP, (Pro-Hyp-Gly)10 i.e. POG10. CMP has been examined in the presence of varying concentration of choline chloride (ChCl) by using various biophysical techniques such as circular dichroism (CD), UV–vis spectroscopy, fluorescence spectroscopy, Fourier transform infrared spectroscopy (FTIR) spectroscopy, differential scanning calorimetry (DSC), transmission electron microscopy (TEM) and dynamic light scattering (DLS). For the first time, we have demonstrated the use of choline chloride (ChCl) to manipulate stability and aggregation of CMP triple helices in order to delineate the factors responsible for the stability of triple helices.

142 Epidermal equivalents on nonwoven collagen scaffolds

The use of natural polymers such as collagen for tissue engineering has many advantages providing cells with an environment of natural topography and rich of bioactive cues. Nevertheless, as compared to synthetic polymers, electrospinning of such materials is still a methodological challenge. Two nonwoven scaffolds were fabricated by collagen dispersion in hexafluoroisopropanol (HFIP) (microfibrous) and in acetic acid (nanofibrous) and stabilized by genipin. The helical structure of collagen was retained in acetic acid, but not in HFIP. Epidermal equivalents were prepared using human primary keratinocytes on both types of materials. There were up to seven layers of live cells with well-defined granular layer in the stratified epithelium obtained on nanofibrous scaffolds. The stratum corneum (SC) was well pronounced and desquamation was evident. The patterns of involucrin expression were similar, but not identical to the normal epidermis: it demarcated all suprabasal layers, not the uppermost ones as it was shown for filaggrin. The basement membrane (BM) component laminin 5 was deposited on the surface of the fibers, but a compact BM structure was not formed. CK5 expression was not limited to the basal layer, but observed in all living layers of the equivalent. The stratified epithelium formed on the microfiber materials also had a well-distinguishable granular layer and SC. But SC was thinner as compared to nanofiber samples. The expression pattern of involucrin was much closer to normal than on nanofiber scaffold while filaggrin and CK5 showed localization similar to nanofiber scaffolds. The laminin 5 positivity was insignificant. Thus, we have managed to obtain nonwoven collagen matrices of two different types (nanofibrous and microfibrous) which both support the formation of stratified epithelium. Of note, the use of nanofibrous material yields epidermal equivalents with more prominent basal layer and synthesis of BM components, while equivalents on microfibrous material gave more “normal” patterns of involucrin and filaggrin expression.

A Tissue-Engineered Tracheobronchial In Vitro Co-Culture Model for Determining Epithelial Toxicological and Inflammatory Responses.

Translation of novel inhalable therapies for respiratory diseases is hampered due to the lack of in vitro cell models that reflect the complexity of native tissue, resulting in many novel drugs and formulations failing to progress beyond preclinical assessments. The development of physiologically-representative tracheobronchial tissue analogues has the potential to improve the translation of new treatments by more accurately reflecting in vivo respiratory pharmacological and toxicological responses. Herein, advanced tissue-engineered collagen hyaluronic acid bilayered scaffolds (CHyA-B) previously developed within our group were used to evaluate bacterial and drug-induced toxicity and inflammation for the first time. Calu-3 bronchial epithelial cells and Wi38 lung fibroblasts were grown on either CHyA-B scaffolds (3D) or Transwell® inserts (2D) under air liquid interface (ALI) conditions. Toxicological and inflammatory responses from epithelial monocultures and co-cultures grown in 2D or 3D were compared, using lipopolysaccharide (LPS) and bleomycin challenges to induce bacterial and drug responses in vitro. The 3D in vitro model exhibited significant epithelial barrier formation that was maintained upon introduction of co-culture conditions. Barrier integrity showed differential recovery in CHyA-B and Transwell® epithelial cultures. Basolateral secretion of pro-inflammatory cytokines to bacterial challenge was found to be higher from cells grown in 3D compared to 2D. In addition, higher cytotoxicity and increased basolateral levels of cytokines were detected when epithelial cultures grown in 3D were challenged with bleomycin. CHyA-B scaffolds support the growth and differentiation of bronchial epithelial cells in a 3D co-culture model with different transepithelial resistance in comparison to the same co-cultures grown on Transwell® inserts. Epithelial cultures in an extracellular matrix like environment show distinct responses in cytokine release and metabolic activity compared to 2D polarised models, which better mimic in vivo response to toxic and inflammatory stimuli offering an innovative in vitro platform for respiratory drug development.

Nano- and Microfibrous Materials Based on Collagen for Tissue Engineering: Synthesis, Structure, and Properties

The creation of three-dimensional structures possessing biomimetic properties is of considerable interest for regenerative medicine. Nonwoven materials with a diameter of fibers from 100 nm to 3 µm have been obtained by electrospinning from dispersions of collagen in hexafluoroisopropanol and acetic acid (AA). A study by the circular dichroism method indicates the predominant preservation of a collagen triple helix in produced materials. To preserve the fibrous structure in aqueous media, collagen is cross-linked by genipin in isopropanol and PBS (phosphate buffered saline, pH 7.4). The mechanical and biological properties of cross-linked materials have been studied—it is shown that the mechanical behavior of collagen materials in the physiological range of loads corresponds to the mechanical behavior of the native aorta. Cross-linked fibrous materials do not possess cytotoxicity, and they contribute to the adhesion and proliferation of cells.

PC206 Transdifferentiation and Remodeling of a Tissue-Engineered Collagen Scaffold in the Ovine Carotid Model: An Experimental Pilot Study

Patch angioplasty is commonly performed after carotid endarterectomy. Although patch angioplasty is known for reduction in perioperative and long-term stroke rates as well as restenosis compared to primary closure, the ultimate patch in terms of performance and tissue remodeling is yet to be identified. This study evaluated the performance and remodeling potential of a novel tissue-engineered collagen scaffold (VascuCel) in an ovine carotid model. Cross-bred sheep (n = 6; body weight, 35-55 kg) were randomized into two groups (n = 3 animals per group). Implants were explanted at two different time points. In group 1, implants (n = 3) were explanted at 30 days and in group 2, implants (n = 3) explanted at 180 days. Computed tomography angiograms were performed at the end of each time point. Explants were assessed by means of macroscopic appearance, tensile characteristics, and histology (hematoxylin and eosin, trichrome, Von Kossa, and picrosirius red). All animals survived the entire study period without any vascular adverse events. Macroscopically, both early and late explants demonstrated smooth, intimal surfaces with well-incorporated native tissue on the edges of the scaffold (Fig 1). No signs of thromboembolic-related deposits were visible on the intimal surface (n = 12 grafts). Tensile strength of explants demonstrated acceptable vascular strength (full thickness = 8.14 ± 1.68 MPa; neointima = 2.9 ± 0.41 MPa). Histology in early explants showed a partially endothelialized neointima on the luminal side and presence of granulation tissue on the outside and the scaffold between these two layers. Computed tomography angiographic assessment of animals in the late follow-up group demonstrated normal blood flow in all implanted carotids without any signs of vessel wall thickening (stenosis). Histology of late explants demonstrated unique transdifferentiation of the scaffold into three distinctive layers, which consisted of a completely endothelialized neointima with smooth muscle cells, the scaffold saturated with host fibroblasts resembling the media, and an external layer consisting of loose collagen fibers resembling the adventitia (Fig 2). Normal flow dynamics, optimal tensile properties, and effective incorporation of the VascuCel patch by surrounding host tissue suggest ultimate function and reliability of the VascuCel patch in the carotid position. Superior transdifferentiation and remodeling demonstrated enhanced biocompatibility which resulted in site-specific transformation of the VascuCel patch into the ideal repaired vascular construct.Fig 2View Large Image Figure ViewerDownload Hi-res image Download (PPT)

Protein engineering and other bio-synthetic routes for bio-based materials: current uses and potential applications.

Since the pioneer work of Stanley Cohen, Herbert Boyer and their collaborators almost 40 years ago (Cohen et al., 1973), genetic engineering had advanced greatly. The tools and resources available to the genetic engineer open new opportunities in genome engineering (Carr and Church, 2009) and synthetic biology (Lu et al., 2009). But still much needs to be done to build and control biological systems. In the current Research Topic, we focus on the synthesis of bio-based materials employing the basic principles of genetic engineering. The rationale of utilizing biosynthesis as a route for material production relies on the capability of the biological machinery to produce macromolecules of well-defined sequence, stereochemistry, and size. The specific location of the chemical groups in a given bio-macromolecule is critical to its structure and ultimately its biological function. Protein engineering has emerged as a strong tool to produce proteins in large scale with high fidelity. In the context of the current Research Topic we refer to such protein products as bio/macromolecules, nanostructures, biologicals or precursors produced in a bio-based environment. The topic is designed to present several approaches to biosynthesis, not limited to the production of a target protein in a bacterial host. At first, I would like to direct the readers to an opinion article that presents a broad perspective of the field of bio-based and bio-inspired materials (Nick McElhinny and Becker, 2014). Following their theme, most of the articles in the current Research Topic fit in the category of Using Biology as a Material. For example, several original research papers report the utilization of genetically-engineered proteins to obtain materials for various applications such as: tunable hydrogels (Tang and Olsen, 2014), hydrogels for mechanically active tissues (Li and Kiick, 2014), bacterial collagen for tissue engineering (An et al., 2014), and microfibers for nerve guide conduits (Kakinoki et al., 2014). Plant viruses (Pongkwan et al., 2014) and antimicrobial peptides (Rodriguez et al., 2014) are the starting bio-based materials to incorporate new functionalities by well-known chemical methods. In the field of biocatalysis, immobilized enzymes are used for industry-scale production of bioproducts (Lopez et al., 2014) and bacterial homologs of human cholinesterase (Legler et al., 2014) are engineered in the laboratory setting with the aim of using them as a therapeutic enzyme. From the materials science perspective, one can easily envision using a biological organism guided by well-established biotechnology techniques to generate a single product. However, the biological environment still has more to offer. An example is described in the review article where Clostridium thermocellum is presented as a strong candidate in bioprocessing applications. The system attributes are due to its unique, multivariate enzyme cellulosome complex and its role during biomass degradation (Akinosho et al., 2014). Studies of complex cellular processes without disturbing natural biological events (Chambers, 2014) are needed to expand our knowledge and ultimately to facilitate the engineering of biological systems for our benefit. Lastly, a new paradigm is presented in which bio-building blocks and non-standard amino acids are utilized in a cell-free environment (Hong et al., 2014). While others incorporate artificial amino acids into protein products using cell-based biosynthesis strategies, having a cell-free environment offers alternatives to new applications where a cell-free environment is more desirable. We can imagine using a cell-free environment for the biosynthesis of more complex systems where biomacromolecules are produced in a concerted way to control synthesis and/or assembly. There is no doubt that bio-based products provide a rich tool-box with a great potential for a wide variety of applications as presented in the current Research Topic. Taking a multidisciplinary approach, combining knowledge from biology, chemistry, and materials science to produce complex materials is crucial to succeed in this field. Still challenges exist for the utilization of bio-based materials in main stream industrial production. Public acceptance and cost effectiveness will be key elements in engaging the industry into adapting these new biosynthetic strategies as alternatives to classical chemical synthetic routes. For example, one general public concern on using plants to produce materials is the limitation in arable land and fresh water which are needed to fulfill future demands on food for a constantly increasing population (Ronald, 2011). Furthermore, genetic engineering can be of a great concern if the engineered systems are delivered to the environment causing a spread of un-desirable traits or antibiotic resistant bacterial strains. In spite of such concerns, major advances in the production of biopolymers at the industrial scale are already implemented by major bioplastics producers (Smith, 2012). Proper engineer controls must be implemented to avoid biological contamination similarly as chemicals production is tightly regulated. As the field advances and we increase our understanding of biological synthetic platforms and our ability to engineer those systems improves, we should be able to generate materials previously not imaginable.

Effectiveness of xenogenous-based bovine-derived platelet gel embedded within a three-dimensional collagen implant on the healing and regeneration of the Achilles tendon defect in rabbits

Background and objective: Tissue engineering is an option in reconstructing large tendon defects and managing their healing and regeneration. We designed and produced a novel xenogeneic-based bovine platelet, embedded it within a tissue-engineered collagen implant (CI) and applied it in an experimentally induced large tendon defect model in rabbits to test whether bovine platelets could stimulate tendon healing and regeneration in vivo.Methods: One hundred twenty rabbits were randomly divided into two experimental and pilot groups. In all the animals, the left Achilles tendon was surgically excised and the tendon edges were aligned by Kessler suture. Each group was then divided into three groups of control (no implant), treated with CI and treated with collagen-platelet implant. The pilot groups were euthanized at 10, 15, 30 and 40 days post-injury (DPI), and their gross and histologic characteristics were evaluated to study host–graft interaction mechanism. To study the tendon healing and its outcome, the experimental animals were tested during the experiment using hematologic, ultrasonographic and various methods of clinical examinations and then euthanized at 60 DPI and their tendons were evaluated by gross pathologic, histopathologic, scanning electron microscopic, biophysical and biochemical methods.Results: Bovine platelets embedded within a CI increased inflammation at short term while it increased the rate of implant absorption and matrix replacement compared with the controls and CI alone. Treatment also significantly increased diameter, density, amount, alignment and differentiation of the collagen fibrils and fibers and approximated the water uptake and delivery behavior of the healing tendons to normal contralaterals (p < 0.05). Treatment also improved echogenicity and homogenicity of the tendons and reduced peritendinous adhesion, muscle fibrosis and atrophy, and therefore, it improved the clinical scores and physical activity related to the injured limb when compared with the controls (p < 0.05).Conclusion: The bovine platelet gel embedded within the tissue-engineered CI was effective in healing, modeling and remodeling of the Achilles tendon in rabbit. This strategy may be a valuable option in the clinical setting.

Extraction and Characterization of Collagen from the Skin of &lt;I&gt;Arothron&lt;/I&gt; &lt;I&gt;stellatus&lt;/I&gt; Fish—A Novel Source of Collagen for Tissue Engineering

Extraction and Characterization of Collagen from the Skin of &lt;I&gt;Arothron&lt;/I&gt; &lt;I&gt;stellatus&lt;/I&gt; Fish—A Novel Source of Collagen for Tissue Engineering

Development of a Surgically Optimized Graft Insertion Suture Technique to Accommodate a Tissue-Engineered TendonIn Vivo

The traumatic rupture of tendons is a common clinical problem. Tendon repair is surgically challenging because the tendon often retracts, resulting in a gap between the torn end and its bony insertion. Tendon grafts are currently used to fill this deficit but are associated with potential complications relating to donor site morbidity and graft necrosis. We have developed a highly reproducible, rapid process technique to manufacture compressed cell-seeded type I collagen constructs to replace tendon grafts. However, the material properties of the engineered constructs are currently unsuitable to withstand complete load bearing in vivo. A modified suture technique has been developed to withstand physiological loading and off load the artificial construct while integration occurs. Lapine tendons were used ex vivo to test the strength of different suture techniques with different sizes of Prolene sutures and tissue-engineered collagen constructs in situ. The data were compared to standard modified Kessler suture using a standard tendon graft. Mechanical testing was carried out and a finite element analysis stress distribution model constructed using COMSOL 3.5 software. The break point for modified suture technique with a tissue-engineered scaffold was significantly higher (50.62 N) compared to a standard modified Kessler suture (12.49 N, p<0.05). Distributing suture tension further proximally and distally from the tendon ends increased the mechanical strength of the repairs. We now have ex vivo proof of concept that this suture technique is suitable for testing in vivo, and this will be the next stage of our research.

New perspectives in the treatment of cartilage damage. Poly(ethylene glycol) diacrylate (PEGDA) scaffold. A review.

This review was conducted as a complementary study to our review "Current concepts in the treatment of cartilage damage. A review", in this same Journal, on promising new strategies in the treatment of cartilage defects. The established treatments such as osteochondral implants, bone marrow stimulation techniques and chondrogeneic cell implantations, besides advantages, have drawbacks that have led to seek new strategies such as scaffold materials. Matrix-associated chondrocyte implantation, hyaluronan-based scaffolds, tissue-engineered collagen matrices seeded with autologous chondrocytes and encapsulation of autologous chondrocytes in poly(ethylene glycol) diacrylate (PEGDA) seem to be less invasive and have a good performance. In this review we describe benefits and disadvantages of the new procedures of cartilage regeneration by scaffolding materials such as PEGDA.

Strain Magnitude-Dependent Calcific Marker Expression in Valvular and Vascular Cells

Aortic valve disease and atherosclerosis tend to coexist in most patients with cardiovascular disease; however, the causes and mechanisms of disease development in heart valves are still not clearly understood. To understand the contributions of the magnitude of cyclic strain (5% hypotension, 10% physiological, and 15% hypertension) in calcification, we used a model system of tissue-engineered collagen gels containing human aortic smooth muscle cells and human aortic valvular interstitial cells, both isolated from noncalcific heart transplant tissue. The compacted collagen gels were cultured in osteogenic media for 3 weeks in a custom-designed bioreactor and all assessments were performed at the end of the culture period. The major finding of this study is that bone morphogenic protein (BMP)-2 and BMP-4 and transforming growth factor-β1 mRNA expression significantly changed in response to the magnitude of applied strain in valvular cells, while the lowest expression was observed for the representative physiological strain. On the other hand, mRNA expression in vascular cells did not vary in response to the magnitude of strain. Regarding BMP-2 and BMP-4 protein expression determined by immunostaining, trends were similar to mRNA expression in vascular and valvular cells, where only valvular cells showed a varied protein expression depending on the magnitude of the strain applied. Our results suggest that cellular differences exist between vascular and valvular cells in their response to altered levels of cyclic strain during calcification.

Differences in valvular and vascular cell responses to strain in osteogenic media

Calcification is the primary cause of failure of bioprosthetic and tissue-engineered vascular and valvular grafts. We used tissue-engineered collagen gels containing human aortic smooth muscle cells (HASMC) and human aortic valvular interstitial cells (HAVIC) as a model to investigate cell-mediated differences in early markers of calcification. The HASMCs and HAVICs were isolated from non-sclerotic human tissues. After 21 days of culture in either regular or osteogenic media with or without 10% cyclic strain at 1 Hz, the collagen gels were assessed for DNA content, collagen I, matrix metalloproteinase (MMP)-2 and glycosaminoglycan (GAG) content. The collagen gels containing HASMCs contained significantly greater amounts of collagen I and GAG compared to HAVICs. Although strain increased MMP-2 activity for both cell types, this trend was significant (p ≤ 0.05) only for HAVICs. Cultured gels were also assessed for osteogenic markers calcium content, alkaline phosphatase (ALP), and Runx2 and were present at greater amounts in gels containing HASMCs than HAVICs. Calcium content, Runx2 expression, and ALP activity were also modulated by mechanical strain. The results indicate that cell-mediated differences exist between the vascular and valvular calcification processes. Further investigation is necessary for improved understanding and to detect biomarkers for early detection or prevention of these diseases.

Comparison of morphology, orientation, and migration of tendon derived fibroblasts and bone marrow stromal cells on electrochemically aligned collagen constructs

There are approximately 33 million injuries involving musculoskeletal tissues (including tendons and ligaments) every year in the United States. In certain cases the tendons and ligaments are damaged irreversibly and require replacements that possess the natural functional properties of these tissues. As a biomaterial, collagen has been a key ingredient in tissue engineering scaffolds. The application range of collagen in tissue engineering would be greatly broadened if the assembly process could be better controlled to facilitate the synthesis of dense, oriented tissue-like constructs. An electrochemical method has recently been developed in our laboratory to form highly oriented and densely packed collagen bundles with mechanical strength approaching that of tendons. However, there is limited information whether this electrochemically aligned collagen bundle (ELAC) presents advantages over randomly oriented bundles in terms of cell response. Therefore, the current study aimed to assess the biocompatibility of the collagen bundles in vitro, and compare tendon-derived fibroblasts (TDFs) and bone marrow stromal cells (MSCs) in terms of their ability to populate and migrate on the single and braided ELAC bundles. The results indicated that the ELAC was not cytotoxic; both cell types were able to populate and migrate on the ELAC bundles more efficiently than that observed for random collagen bundles. The braided ELAC constructs were efficiently populated by both TDFs and MSCs in vitro. Therefore, both TDFs and MSCs can be used with the ELAC bundles for tissue engineering purposes.

Supramolecular hydrogels inspired by collagen for tissue engineering

Supramolecular hydrogels are promising biomaterials for cell culture in 2-D and 3-D environments. Inspired by the chemical structure of collagen, which bears the repeating tripeptide of glycine-Xaa-4R-hydroxyproline (GXO; Xaa is any one of the natural amino acids), we designed and synthesized a small library of supramolecular hydrogelators (a total of 6). We found that four of the hydrogels were suitable for NIH 3T3 cell culture in the 2-D environments. Gel 2, the best hydrogel, has properties that are similar to those of collagen for 3T3 cell culture. These findings not only provide more supramolecular hydrogel candidates for tissue engineering, but also offer a new strategy for designing biomaterials that mimic nature.

A new procedure for rapid, high yield purification of Type I collagen for tissue engineering

Collagen, which is one of the most abundant proteins in mammalian proteomes, is of significant medical and also biotechnological importance. In tissue engineering, collagen is used as natural matrix to facilitate growth of mammalian cells in 3D-structures. Here, large amounts of highly purified Type I collagen have been obtained from rat tail tendon by a two-step purification, suitable for industrial up-scaling, involving extraction with 9 M urea followed by Superose 12 chromatography. Mass spectrometry identified only collagen Type I peptides indicating that the extracted collagen was homogeneous. Furthermore, a substantial amount of post-translational modifications were identified, including the presence of hydroxylated proline at the X-position in the G-X-Y repeats, which give new insight into collagen structure in vivo. The purified collagen was renatured quantitatively to form triple-helices by dialysis against water, as judged by UV-circular dichroism. This urea-extracted collagen (UC) was tested for its suitability as a matrix for growth of mammalian cells in tissue engineering. Cultures of a fibroblast cell line grown on urea-extracted collagen showed a higher motility and reduced stress levels than those grown on acetic acid-extracted collagen as determined by morphological studies and transcriptional analysis of selected marker genes using real time-PCR. These results indicate the suitability of the urea-extracted collagen obtained for biotechnological applications and tissue engineering.