Bone marrow-derived mesenchymal stromal stem cells (BMSCs) are a promising cell source for treating articular cartilage defects. Quality of cartilaginous repair tissue following BMSC transplantation has been shown to correlate with functional outcome. Therefore, tissue-engineering variables, such as cell expansion environment and seeding density of scaffolds, are currently under investigation. The objectives of this study were to demonstrate chondrogenic differentiation of BMSCs seeded within a collagen I scaffold following isolation and expansion in two-dimensional (2D) and three-dimensional (3D) environments, and assess the impact of seeding density on in vitro chondrogenesis. It was hypothesised that both expansion protocols would produce BMSCs capable of hyaline-like chondrogenesis with an optimal seeding density of 10 million cells/cm3. Ovine BMSCs were isolated in a 2D environment by plastic adherence, expanded to passage two in flasks containing expansion medium, and seeded within collagen I scaffolds (6 mm diameter, 3.5 mm thickness and 0.115 ± 0.020 mm pore size; Integra LifeSciences Corp.) at densities of 50, 10, 5, 1, and 0.5 million BMSCs/cm3. For 3D isolation and expansion, bone marrow aspirates containing known quantities of mononucleated cells (BMNCs) were seeded on scaffolds at 50, 10, 5, 1, and 0.5 million BMNCs/cm3 and cultured in expansion medium for an equivalent duration to 2D expansion. All cell-scaffold constructs were differentiated in vitro in chondrogenic medium containing transforming growth factor-beta three for 21 days and assessed with RT-qPCR, safranin O staining, histological scoring using the Bern Score, collagen immunofluorescence, and glycosaminoglycan (GAG) quantification. Two dimensional-expanded BMSCs seeded at all densities were capable of proteoglycan production and displayed increased expressions of aggrecan and collagen II mRNA relative to pre-differentiation controls. Collagen II deposition was apparent in scaffolds seeded at 0.5–10 million BMSCs/cm3. Chondrogenesis of 2D-expanded BMSCs was most pronounced in scaffolds seeded at 5–10 million BMSCs/cm3 based on aggrecan and collagen II mRNA, safranin O staining, Bern Score, total GAG, and GAG/DNA. For 3D-expanded BMSC-seeded scaffolds, increased aggrecan and collagen II mRNA expressions relative to controls were noted with all densities. Proteoglycan deposition was present in scaffolds seeded at 0.5–50 million BMNCs/cm3, while collagen II deposition occurred in scaffolds seeded at 10–50 million BMNCs/cm3. The highest levels of aggrecan and collagen II mRNA, Bern Score, total GAG, and GAG/DNA occurred with seeding at 50 million BMNCs/cm3. Within a collagen I scaffold, 2D- and 3D-expanded BMSCs are capable of hyaline-like chondrogenesis with optimal cell seeding densities of 5–10 million BMSCs/cm3 and 50 million BMNCs/cm3, respectively. Accordingly, these densities could be considered when seeding collagen I scaffolds in BMSC transplantation protocols

Treatment of segmental bone loss remains a major challenge in orthopaedic surgery. This study evaluated the healing potential of a series of highly porous tissue engineering scaffolds with the current clinical gold standard. We compare healing of collagen-glycosaminoglycan (CG) and collagen micro-hydroxyapatite (CHA) scaffolds, with and without recombinant bone morphogenetic protein-2 (BMP2), with autogenous bone graft (ABG) in the healing of a 15mm rabbit radius defect, which were filled with either CG scaffold, CHA scaffold, CG-BMP2, CHA-BMP2 or ABG. Serial radiographs and micro-computed tomography (µCT) at six week radiographs demonstrated complete defect bridging with callus using CHA and CG-BMP2 while the CHA-BMP2 was already in an advanced state of healing with cortical remodeling. By sixteen weeks CHA, CG-BMP2 and ABG all had advanced healing with cortical remodeling while CHA-BMP2 had complete anatomic healing. Quantitative histomorphometry values demonstrated similarly high healing levels of healing in CHA, CG-BMP2 and ABG with highest overall values in the CHA-BMP2 group. Thus, treatment of a critical sized, weight bearing, rabbit radius defect with a CHA scaffold can result in full cortical bridging with medullary cavity development. In addition, a CHA-BMP2 combination can result in fully mature, anatomic healing. The use of an off-the-shelf CHA scaffold for direct surgical placement into a defect site may be an effective bone graft substitute in the treatment of skeletal defects. The ease of manufacture, storage and peri-operative preparation may offer an alternative to traditional strategies, as well as to more recent BMP2 devices. This study provides clear evidence that CHA scaffolds can perform as well as autogenous bone grafts and supports their use as a viable alternative. Where the use of BMP2 may be desirable, these materials provide an ideal delivery mechanism and using a very low (near physiological) dose, healing superior to autogenous graft may be achieved.

Adherent cells are known to respond to physical characteristics of their surrounding microenvironment, adapting their cytoskeleton and initiating signaling cascades specific to the type of cue encountered. Scaffolds mimicking native biophysical cues have proven to differentiate stem cells towards tissue-specific lineages and to maintain the phenotype of somatic cells for longer periods of culture time. Although the characteristic anisotropy of tendon tissue is commonly replicated in scaffolds, relevant physical cues such as tendon rigidity or mechanical loading are often neglected. The objective of this study is to use tendons' main extracellular matrix component, collagen type I, to create scaffolds with an anisotropic surface topography and controlled rigidity, in an effort to engineer functional tendon tissue equivalents, with native organization and strength.

Porcine collagen type I in solution was treated with one of the following cross-linkers: glutaraldehyde, genipin or 4-arm polyethylene glycol (4SP). The resulting mixture was poured on micro-grooved (2×2×2 μm) or planar polydimethylsiloxane (PDMS) molds and dried in a laminar flow hood to obtain 5 mg/ml collagen films. Surface topography and elastic modulus of the final scaffolds were analyzed using SEM/AFM and rheometry, respectively. Human tendon cells were isolated from adult tendon tissue and cultured on micro-grooved/planar scaffolds for 4, 7 and 10 days. Cell morphology, collagen III and tenascin C expression were analyzed by immunocytochemistry.

Among the different cross-linkers used, only the treatment with 4SP resulted in scaffolds with a recognizable micro-grooved surface topography. Precise control over the micro-grooved topography and the rigidity of the scaffolds was achieved by cross-linking the collagen with varying concentrations of 4SP at low pH and temperature. The elastic modulus of the scaffolds cross-linked with the highest concentration of 4SP matched the physiological values reported in developing tendons (∼15 kPa). Around eighty percent of the human tendon cells cultured on the cross-linked collagen films aligned in the direction of the anisotropy for 10 days in culture. At 4 days, tenoyctes cultured on micro-grooved substrates presented a significant higher nuclei aspect ratio than tenocytes cultured on planar substrates for all the 4SP concentrations. Synthesis, deposition and alignment of collagen III and tenascin C, two important tenogenic markers, were up regulated selectively in the rigid micro-grooved scaffolds after 7 days in culture. These results highlight the synergistic effect of matrix rigidity and cell alignment on tenogenic cell lineage commitment.

Collectively, this study provides new insights into how collagen can be modulated to create scaffolds with precise imprinted topographies and controlled rigidities. Gene expression analysis and a replicate study with hBMSCs will be carried out to support the first results and to further identify the optimal biophysical conditions for tenogenic cell lineage commitment. This potentially leads to the design of smart implants that not only restore immediate tendon functionality but also provide microscopic cues that drive cellular synthesis of organized tissue-specific matrix.

Restoration a joint's articular surface following degenerative or traumatic pathology to the osteochondral unit pose a significant challenge. Recent advances have shown the utility of collagen-based scaffolds in the regeneration of osteochondral tissue. To provide these collagen scaffolds with the appropriate superstructure novel techniques in 3D printing have been investigated. This study investigates the use of polyɛ-caprolactone (PCL) collagen scaffolds in a porcine cadaveric model to establish the stability of the biomaterial once implanted. This study was performed in a porcine cadaveric knee model. 8mm defects were created in the medial femoral trochlea and repaired with a PCL collagen scaffold. Scaffolds were secured by one of three designs; Press Fit (PF), Press Fit with Rings (PFR), Press Fit with Fibrin Glue (PFFG). Mobilisation was simulated by mounting the pig legs on a continuous passive motion (CPM) machine for either 50 or 500 cycles. Biomechanical tensile testing was performed to examine the force required to displace the scaffold. 18 legs were used (6 PF, 6 PFR, 6 PFFG). Fixation remained intact in 17 of the cohort (94%). None of the PF or PFFG scaffolds displaced after CPM cycling. Mean peak forces required to displace the scaffold were highest in the PFFG group (3.173 Newtons, Standard deviation = 1.392N). The lowest peak forces were observed in the PFR group (0.871N, SD = 0.412N), while mean peak force observed in the PF group was 2.436N (SD = 0.768). There was a significant difference between PFFG and PFR (p = 0.005). There was no statistical significance in the relationship between the other groups. PCL reinforcement of collagen scaffolds provide an innovative solution for improving stiffness of the construct, allowing easier handling for the surgeon. Increasing the stiffness of the scaffold also allows press fit solutions for reliable fixation. Press fit PCL collagen scaffolds with and without fibrin glue provide dependable stability. Tensile testing provides an objective analysis of scaffold fixation. Further investigation of PCL collagen scaffolds in a live animal model to establish quality of osteochondral tissue regeneration are required

Purpose. Traumatic articular cartilage (AC) defects are common in young adults and frequently progresses to osteoarthritis. Matrix-Induced Autologous Chondrocyte Implantation (MACI) is a recent advancement in cartilage resurfacing techniques and is a variant of ACI, which is considered by some surgeons to be the gold standard in AC regeneration. MACI involves embedding cultured chondrocytes into a scaffold that is then surgically implanted into an AC defect. Unfortunately, chondrocytes cultured in a normoxic environment (conventional technique) tend to de-differentiate resulting in decreased collagen II and increased collagen I producing in a fibrocartilagous repair tissue that is biomechanically inferior to AC and incapable of withstanding physiologic loads over prolonged periods. The optimum conditions for maintenance of chondrocyte phenotype remain elusive. Normal oxygen tension within AC is <7%. We hypothesized that hypoxic conditions would induce gene expression and matrix production that more closely characterizes normal articular chondrocytes than that achieved under normoxic conditions when chondrocytes are cultured in a collagen scaffold. Method. Chondrocytes were isolated from Outerbridge grade 0 and 1 AC from four patients undergoing total knee arthroplasty and embedded within 216 bovine collagen I scaffolds. Scaffolds were incubated in hypoxic (3% O2) or normoxic (21% O2) conditions for 1hr, 21hr and 14 days. Gene expression was determined using Q-rt-PCR for col I/II/X, COMP, SOX9, aggrecan and B actin. Matrix production was determined using glycosaminoglycan (GAG) content relative to cell count determined by DNA quantification. Cell viability and location within the matrix was determined by Live/Dead assay and confocal microscopy. Statistical analysis was performed using a two-tailed T-test. Results. Chondrocytes cultured under hypoxic conditions showed an upregulation of all matrix related genes compared to normoxic conditions noted most markedly in col II, COMP and SOX9 expression. There were similar numbers of chondrocytes between hypoxic and normoxic groups (P=0.68) but the chondrocytes in the hypoxic group produced more GAG per cell (P= 0.052). Viable cells were seen throughout the matrix in both groups. Conclusion. Important matrix related genes (col II, COMP, SOX9) were most significantly upregulated in hypoxic conditions compared to normoxic conditions. This was supported by an increase in GAG production per cell in hypoxic conditions. The results indicate that hypoxia induces an upregulation in the production of extracellular matrix components typical of AC with only modest increases in col I (possibly related to the col I based scaffold used in this experiment). These results indicate that hypoxic conditions are important for the maintenance of chondrocyte phenotype even when the cells are cultured in a 3D environment. In conclusion, hypoxic culture conditions should be used to help maintain chondrocyte phenotype even when culturing these cells in a 3D scaffold

PURPOSE. Recently, in tissue engineering several methods using stem cells have been developed to repair chondral and osteochondral defects. Most of these methods rely on the use of scaffolds. Studies in the literature have demonstrated, first in animals and then in humans, that the use of mesenchymal stem cells withdrawn by several methods from adipose tissue allows to regenerate hyaline articular cartilage. In fact, it has been cleared that adipose-derived cells have multipotentiality equivalent to bone marrow-derived stem cells and that they can very easily and very quickly be isolated in large amounts enabling their immediate use in operating room for one-step cartilage repair techniques. The purpose of this study is to evaluate the therapeutic effect of adipose-derived stem cells on cartilage repair and present our experience in the treatment of knee cartilage defects by the novel AMIC REPAIR TECHNIQUE AUGMENTED by immersing the collagen scaffold with mesenchymal stem cells withdrawn from adipose tissue of the abdomen. MATERIALS AND METHODS. Fat tissue processing involves mechanical forces and does not mandatorily require any enzymatic or chemical treatment in order to obtain the regenerative cells from the lipoaspirate. In our study, mesenchymal adipose stem cells were obtained by non-enzymatic filtration or microfragmentation of lipoaspirates of the abdomen adipose tissue that enabled the separation of the stromal vascular fraction and were used in one-step reconstruction of knee cartilage defects by means of this new AUGMENTED AMIC TECHNIQUE. The focal defects underwent bone marrow stimulation microfractures, followed by coverage with collagen double layer resorbable membrane (Chondro-gide. TM. -Geistlich Pharma AG, Wolhusen, Switzerland) soaked in the cells obtained from fat in 18 patients, aged between 31 and 58 years, at the level of the left knee in 10 cases and in the right in eight, with follow-up ranging between 12 and 36 months. RESULTS: Surgical procedures have been completed without technical problems neither intraoperative or early postoperative complications. The evaluation scores (IKDC, KOOS and VAS) showed a significant improvement, more than 30%, at the initial 6 months follow-up and furtherly improved in the subsequent follow-ups. Also the control MRIs showed a progressive filling and maturation of the repair tissue of the defects. CONCLUSIONS. Since we are reporting a short and medium-term experience, it is not, of course, possible to provide conclusive assessment considerations on this technique, as the experience has to mature along with the progression of follow-ups. The simplicity together with the absence of intraoperative difficulties or immediate complications and the experience gained by other authors, first in animals and then in early clinical cases, makes it, however, possible to say that this can be considered one of the techniques to which resort for one-step treatment of cartilage defects in the knee because it improves patient's conditions and has the potential to regenerate hyaline-like cartilage. Future follow-up works will confirm the results

Introduction. Massive rotator cuff repairs have up to 60% failure rate and repair of a chronic repair can have up to 40% failure rate. With this in mind, new methodologies are being to being developed to overcome this problem. The use of tendon augmentation grafts is one of them. Prior attempts have shown equivocal or poorer outcomes to control repairs. Aims and objectives: The specific aim of these expereiments was to test how well ovine tendon cells would take to a specific biological augmentation graft (Ligamimetic), and wheter tissue engineering techniques would enhance this. Method. Tendon cells harvested from ovine tendons will be cultured, exposed to the tendon augmentation graft, and analysed to see how well it takes to the tendon cells. We have conducted a 21 day experiment, sampling at days 7, 14, and 21. The experiment will look in sheep tendon cells:1. Platelet rich plasma: A comparison of the effects of platelet rich plasma to cell adherence, cell proliferation, and collagen production. Mesenchymal stem cell: A comparison of the effects of mesenchymal stem cells to the material on cell adherence, cell proliferation, and collagen production. Results. Our results show that the ovine tendon cells do take to the tendon augmentation graft, and are able to proliferate. We will present DAPI stainings, DNA and collagen turnover, with Westin blotting results. Results show that the addition of PRP had increased the cell adherence, cell proliferation, and collagen production. These effects were not seen with the mesenchymal stem cells. Conclusion. These experiments have shown our novel collagen scaffold augmentation graft has allowed cells to proliferate on it. Tissue engineered techniques also enhance cell proliferation, and has the potential to enhance cell repair

Aims

Bone demonstrates good healing capacity, with a variety of strategies being utilized to enhance this healing. One potential strategy that has been suggested is the use of stem cells to accelerate healing.

Nanotechnology is the study, production and controlled manipulation of materials with a grain size < 100 nm. At this level, the laws of classical mechanics fall away and those of quantum mechanics take over, resulting in unique behaviour of matter in terms of melting point, conductivity and reactivity. Additionally, and likely more significant, as grain size decreases, the ratio of surface area to volume drastically increases, allowing for greater interaction between implants and the surrounding cellular environment. This favourable increase in surface area plays an important role in mesenchymal cell differentiation and ultimately bone–implant interactions.

Basic science and translational research have revealed important potential applications for nanotechnology in orthopaedic surgery, particularly with regard to improving the interaction between implants and host bone. Nanophase materials more closely match the architecture of native trabecular bone, thereby greatly improving the osseo-integration of orthopaedic implants. Nanophase-coated prostheses can also reduce bacterial adhesion more than conventionally surfaced prostheses. Nanophase selenium has shown great promise when used for tumour reconstructions, as has nanophase silver in the management of traumatic wounds. Nanophase silver may significantly improve healing of peripheral nerve injuries, and nanophase gold has powerful anti-inflammatory effects on tendon inflammation.

Considerable advances must be made in our understanding of the potential health risks of production, implantation and wear patterns of nanophase devices before they are approved for clinical use. Their potential, however, is considerable, and is likely to benefit us all in the future.

Cite this article: Bone Joint J 2014; 96-B: 569–73.