Cellular therapy and tissue engineering for cartilage repair.

Articular cartilage (AC) has limited capacity for repair. The first attempt to repair cartilage using tissue engineering was reported in 1977. Since then, cell-based interventions have entered clinical practice in orthopaedics, and several tissue engineering approaches to repair cartilage are in the translational pipeline towards clinical application. Classically, these involve a scaffold, substrate or matrix to provide structure, and cells such as chondrocytes or mesenchymal stromal cells to generate the tissue. We discuss the advantages and drawbacks of the use of various cell types, natural and synthetic scaffolds, multiphasic or gradient-based scaffolds, and self-organizing or self-assembling scaffold-free systems, for the engineering of cartilage constructs. Several challenges persist including achieving zonal tissue organization and integration with the surrounding tissue upon implantation. Approaches to improve cartilage thickness, organization and mechanical properties include mechanical stimulation, culture under hypoxic conditions, and stimulation with growth factors or other macromolecules. In addition, advanced technologies such as bioreactors, biosensors and 3D bioprinting are actively being explored. Understanding the underlying mechanisms of action of cell therapy and tissue engineering approaches will help improve and refine therapy development. Finally, we discuss recent studies of the intrinsic cellular and molecular mechanisms of cartilage repair that have identified novel signals and targets and are inspiring the development of molecular therapies to enhance the recruitment and cartilage reparative activity of joint-resident stem and progenitor cells. A one-fits-all solution is unrealistic, and identifying patients who will respond to a specific targeted treatment will be critical.

YAP/TAZ regulates the expression of proteoglycan 4 and tenascin C in superficial-zone chondrocytes.

The roles of cell division control protein 42 homologue (CDC42) and actin polymerisation in regulating the phenotype of superficial-zone chondrocytes (SZCs) have been demonstrated in vitro; however, the signalling pathway(s) downstream have yet to be fully elucidated. The study hypothesis was that Yes-associated protein (YAP) and transcriptional co-activator with PDZ-binding motif (TAZ) act downstream to regulate proteoglycan 4 (PRG4) and tenascin C (TNC). Bovine SZCs grown in monolayer were treated with ML141 (CDC42 inhibitor) or the actin depolymerising agents, latrunculin B and cytochalasin D, to determine the effect on YAP/TAZ. Verteporfin (YAP/TAZ inhibitor) and YAP/TAZ siRNA-mediated knockdown were used to determine their role in regulating PRG4 and TNC. ML141 treatment reduced total YAP/TAZ protein, nuclear TAZ levels and the YAP/TAZ target gene, connective tissue growth factor (CTGF) mRNA levels. Latrunculin B decreased nuclear TAZ, while cytochalasin D treatment trended towards increased nuclear TAZ (p = 0.06), correlating with decreased and increased CTGF mRNA levels, respectively. Verteporfin treatment decreased PRG4 and TNC expression, with no effect on actin polymerisation. siRNA-mediated knockdown of YAP/TAZ revealed that PRG4 was regulated by YAP/TAZ while TNC was regulated by TAZ only. As cytochalasin D can activate myocardin-related transcription factor-A (MRTF-A), siRNA-mediated knockdown was performed to determine the role of MRTF-A in regulating YAP/TAZ. Although nuclear TAZ decreased, no significant changes in total protein levels were observed. Findings suggested that CDC42 and actin polymerisation regulated SZCs through multiple actin-regulated pathways. Understanding the regulation of these chondroprotective molecules may have important implications for prevention/treatment of osteoarthritis.

Processing and properties of Na-doped porous calcium polyphosphates - Mechanical properties and in vitro degradation characteristics.

Porous calcium polyphosphate (CPP) is being investigated for use as a biodegradable bone substitute and for repair of osteochondral defects. The necessary requirements for these applications, particularly in load-bearing sites, include sufficient strength to withstand functional forces prior to bone ingrowth and substitution of the initial porous CPP template with new bone and cartilage (for osteochondral implants) in a timely and efficacious manner. The present study explored the effects of Na+ doping and processing to form porous structures of both higher strength and faster degradation than previously reported for 'pure' (non-doped) CPP structures of similar geometry. Compressive and tensile strengths were determined before and after 30-day in vitro degradation (PBS, pH 7.1 at 37 °C) and degradation rates assessed. Scanning electron microscopy (SEM), x-ray diffraction (XRD) and solid state nuclear magnetic resonance (31P SS NMR) were used to evaluate 'pure' and Na-doped CPP samples before and after degradation. The results indicated that the different processing protocols required to prepare samples of similar volume % porosity (a 2-step procedure with a Step-1 sintering temperatures equal to 575 °C being used with the Na-doped samples versus a 585 °C Step-1 treatment for 'pure' CPP) resulted in an approximate 1.5- to 2-fold increase in strength (tensile & compressive respectively) and 2-fold increase in degradation rate of Na-doped CPP compared with 'pure' CPP. This difference was attributed to the different Step-1 sintering temperatures used for sample processing.

Engineering of hyaline cartilage with a calcified zone using bone marrow stromal cells.

OBJECTIVE: In healthy joints, a zone of calcified cartilage (ZCC) provides the mechanical integration between articular cartilage and subchondral bone. Recapitulation of this architectural feature should serve to resist the constant shear force from the movement of the joint and prevent the delamination of tissue-engineered cartilage. Previous approaches to create the ZCC at the cartilage-substrate interface have relied on strategic use of exogenous scaffolds and adhesives, which are susceptible to failure by degradation and wear. In contrast, we report a successful scaffold-free engineering of ZCC to integrate tissue-engineered cartilage and a porous biodegradable bone substitute, using sheep bone marrow stromal cells (BMSCs) as the cell source for both cartilaginous zones. DESIGN: BMSCs were predifferentiated to chondrocytes, harvested and then grown on a porous calcium polyphosphate substrate in the presence of triiodothyronine (T3). T3 was withdrawn, and additional predifferentiated chondrocytes were placed on top of the construct and grown for 21 days. RESULTS: This protocol yielded two distinct zones: hyaline cartilage that accumulated proteoglycans and collagen type II, and calcified cartilage adjacent to the substrate that additionally accumulated mineral and collagen type X. Constructs with the calcified interface had comparable compressive strength to native sheep osteochondral tissue and higher interfacial shear strength compared to control without a calcified zone. CONCLUSION: This protocol improves on the existing scaffold-free approaches to cartilage tissue engineering by incorporating a calcified zone. Since this protocol employs no xenogeneic material, it will be appropriate for use in preclinical large-animal studies.

A systematic review of active treatment options in patients with desmoid tumours.

INTRODUCTION: We conducted a systematic review to determine the optimal treatment options in patients with desmoid tumours who have declined observational management. METHODS: A search was conducted of the medline and embase databases (1990 to September 2012), the Cochrane Library, and relevant guideline Web sites and conference materials. RESULTS: One systematic review and forty-six studies met the preplanned study selection criteria; data from twenty-eight articles were extracted and analyzed. For local control, three studies reported a statistically significant difference in favour of surgery plus radiotherapy (rt) compared with surgery alone, and one study did not; two studies reported the lack of a statistical difference between surgery plus rt and rt alone in maintaining local control. Multivariate risk factors for local recurrence included positive surgical margins and young patient age. Single-agent imatinib led to a progression-free survival rate of 55% at 2 years and 58% at 3 years. Methotrexate plus vinblastine led to a progression-free survival rate of 67% at 10 years. Significant toxicities were reported for all treatment modalities, including surgical morbidity, and rt- and chemotherapy-related toxicities. CONCLUSIONS: In patients who have declined observational management, the local control rate was higher with surgery plus rt than with surgery alone. However, the additional rt-related complications should be considered in treatment decision-making. Surgery, rt, and systemic therapy are all reasonable treatment options for patients with desmoid tumours.

Treatment and follow-up strategies in desmoid tumours: a practice guideline.

OBJECTIVES: We set out to determine the optimal treatment options-surgery, radiation therapy (rt), systemic therapy, or any combinations thereof-for patients with desmoid tumours once the decision to undergo active treatment has been made (that is, monitoring and observation have been determined to be inadequate).provide clinical-expert consensus opinions on follow-up strategies in patients with desmoid tumours after primary interventional management. METHODS: This guideline was developed by Cancer Care Ontario's Program in Evidence-Based Care and the Sarcoma Disease Site Group. The medline, embase, and Cochrane Library databases, main guideline Web sites, and abstracts of relevant annual meetings (1990 to September 2012) were searched. Internal and external reviews were conducted, with final approval by the Program in Evidence-Based Care and the Sarcoma Disease Site Group. RECOMMENDATIONS TREATMENTS: Surgery with or without rt can be a reasonable treatment option for patients with desmoid tumours whose surgical morbidity is deemed to be low.The decision about whether rt should be offered in conjunction with surgery should be made by clinicians and patients after weighing the potential benefit of improved local control against the potential harms and toxicity associated with rt.Depending on individual patient preferences, systemic therapy alone or rt alone might also be reasonable treatment options, regardless of whether the desmoid umours are deemed to be resectable. RECOMMENDATIONS FOLLOW-UP STRATEGIES: Undergo evaluation for rehabilitation (occupational therapy or physical therapy, or both).Continue with rehabilitation until maximal function is achieved.Undergo history and physical examinations with appropriate imaging every 3-6 months for 2-3 years, and then annually.

Characterization of the annulus fibrosus-vertebral body interface: identification of new structural features.

Current surgical treatments for degenerative intervertebral disc disease do not restore full normal spinal movement. Tissue engineering a functional disc replacement may be one way to circumvent this limitation, but will require an integration of the different tissues making up the disc for this approach to be successful. Hence, an in-depth characterization of the native tissue interfaces, including annulus insertion into bone is necessary, as knowledge of this interface is limited. The objective of this study was to characterize the annulus fibrosus-vertebral bone (AF-VB) interface in immature (6-9 months old) and mature (18-24 months old) bovine discs, as well as to define these structures for normal adult human (22 and 45 years old) discs. Histological assessment showed that collagen fibers in the inner annulus, which are predominantly type II collagen, all appear to insert into the mineralized endplate zone. In contrast, some of the collagen fibers of the outer annulus, predominantly type I collagen, insert into this endplate, while other fibers curve laterally, at an ∼ 90° angle, to the outer aspect of the bone, and merge with the periosteum. This is seen in both human and bovine discs. Where the AF inserts into the calcified zone of the AF-VB interface, it passes through a chondroid region, rich in type II collagen and proteoglycans. Annulus cells (elongated cells that are not surrounded by proteoglycans) are present at this interface. This cartilage zone is evident in both human and bovine discs. Type X collagen and alkaline phosphatase are localized to the interface region. Age-associated differences in bovine spines are observed when examining the interface thickness and the matrix composition of the cartilaginous endplate, as well as the thickness of the mineralized endplate. These findings will assist with the design of the AF-VB interface in the tissue engineered disc.

AP-1 DNA binding activity regulates the cartilage tissue remodeling process following cyclic compression in vitro.

Generating bioengineered cartilage yields tissue with physical qualities inferior to that of native tissue. Application of cyclic compression (30 min, 1 kPa, 1 Hz) to cartilage cells (chondrocytes) seeded on calcium polyphosphate substrates significantly increases the accumulation of collagens and proteoglycans by 24 hours, thus improving the tissue generated. The mechanism for this increase is not fully known but seems to follow a remodeling pathway of sequential catabolic and anabolic changes. The initial catabolic event involves increased transcription of matrix metalloproteinase (MMP)-3 and MMP-13 two hours after the end of cyclic compression. As MMP-3 and MMP-13 promoters contain activating protein-1 (AP-1) DNA binding sites, we investigated the effect of inhibiting DNA binding through the use of modified decoy oligodeoxynucleotides (ODN). Mechanical stimulation in the presence of the ODN blocked AP-1 DNA binding as detected by electrophoretic mobility shift assay and prevented the increased transcription of MMP-3 and MMP-13. As well the increased accumulation of collagens and proteoglycans by 24 hours in mechanically stimulated samples was prevented. The data suggests that the mechano-induction of MMP-3 and MMP-13 may be regulated at the AP-1 DNA binding site and that upregulation of these metalloproteases is a necessary component of the matrix remodeling initiated by cyclic compression.

An in vitro tissue model to study the effect of age on nucleus pulposus cells.

Differentiation between age (physiological) and disease-induced changes in the nucleus pulposus will facilitate our understanding of the mechanism(s) leading to the development of degenerative disc disease. The aim of this study was to develop an in vitro model that would allow the study of age-induced alterations of cell function in nucleus pulposus. Nucleus pulposus (NP) cells were isolated from intervertebral discs obtained from either calves (<9 months) or cows (>18 months). The cells were placed in culture and grown for 19 days. Although nucleus pulposus tissue was formed by the cells of the two different ages the more mature (older) cells formed less tissue as determined histologically by light microscopy. This was confirmed biochemically as the wet weight and proteoglycan content of the tissue formed by the older cells were significantly less than that of the younger tissue. The older cells accumulated less proteoglycans as determined by quantifying radioisotope incorporation. The older cells showed lower constitutive gene expression of collagen type II and aggrecan whereas collagen type I and link protein levels were similar to those of the younger cells. Metalloprotease (MMP) 13 gene and protein expression increased with age. There was no change in the levels of gene expression of MMP 2 and TIMP 1, 2, or 3 with age. Cells obtained from NP tissue harvested from younger or mature animals showed both genotypic and phenotypic differences in vitro that resulted in the inability of the older cells to reconstitute their extracellular matrix to the same extent as the younger cells. This suggests that this in vitro NP tissue model will be suitable to determine the mechanism(s) regulating age-induced changes.

Membrane type-1 matrix metalloproteinase is induced following cyclic compression of in vitro grown bovine chondrocytes.

OBJECTIVE: To determine if membrane type-1 matrix metalloproteinase (MT1-MMP) will respond to cyclic compression of chondrocytes grown in vitro and the regulatory mechanisms underlying this response. METHODS: Cyclic compression (30min, 1kPa, 1Hz) was applied to bovine chondrocytes (6-9-month-old animals) grown on top of a biodegradable substrate within 3 days of initiating culture. Luciferase assays using bovine articular chondrocytes were undertaken to demonstrate the mechanosensitivity of MT1-MMP. Semi-quantitative reverse-transcription polymerase chain reaction (RT-PCR) and western blot analysis were used to establish the time course of gene and protein upregulation in response to cyclic compression. The regulation of MT1-MMP was assessed by electrophoretic mobility shift assays, RT-PCR and western blot analysis. As well, an MT1-MMP decoy oligonucleotide and an extracellular signal-regulated kinase 1/2 (ERK1/2) pharmacological inhibitor were utilized to further characterize MT1-MMP regulation. RESULTS: After cyclic compression, MT1-MMP showed a rapid and transient increase in gene expression. Elevated protein levels were detected within 2h of stimulation which returned to baseline by 6h. During cyclic compression, phosphorylation of the mitogen activated protein kinase ERK1/2 increased significantly. This was followed by increased gene and protein expression of the transcription factor; early growth factor-1 (Egr-1) and Egr-1 binding to the MT1-MMP promoter. Blocking Egr-1 DNA binding with a decoy MT1-MMP oligonucleotide, downregulated MT1-MMP gene expression. The ERK1/2 inhibitor U0126 also reduced Egr-1 DNA binding activity to MT1-MMP promoter sequences and subsequent transcription of MT1-MMP. CONCLUSIONS: These data suggest that cyclic compression of chondrocytes in vitro upregulates MT1-MMP via ERK1/2 dependent activation of Egr-1 binding. Delineation of the regulatory pathways activated by mechanical stimulation will further our understating of the mechanisms influencing tissue remodeling.

Formation of biphasic constructs containing cartilage with a calcified zone interface.

The zone of calcified cartilage is the mineralized region of articular cartilage that anchors the hyaline cartilage to the subchondral bone and serves to disperse mechanical forces across this interface. In an attempt to mimic this zonal organization, we have developed the methodology to form biphasic constructs composed of cartilaginous tissue anchored to the top surface of a bone substitute (porous calcium polyphosphate, CPP) with a calcified interface. To accomplish this, chondrocytes were selectively isolated from the deep zone of bovine articular cartilage, placed on top of the CPP substrate, and grown in the presence of beta-glycerophosphate (10 mM, beta-GP). By 8 weeks, cartilage tissue had formed with two zones: a calcified region adjacent to the CPP substrate and a hyaline-like zone above. Little or no mineralization occurred in the absence of beta-GP. The mineral that formed in vitro was identified as hydroxyapatite, similar in composition and crystal size to that found in vivo. The tissue stiffness was seven times greater, and the interfacial shear properties at the cartilage-CPP interface were at least two times greater in the presence of this mineralized zone within the in vitro-formed cartilage than in tissue lacking a mineral zone. In conclusion, developing a biphasic construct with a calcified zone at the tissue-biomaterial interface resulted in significantly better cartilage load-bearing (compressive) properties and interfacial shear strength, emphasizing the importance of the presence of a mineralized zone in bioengineered cartilage. Because failure due to shear occurred at the cartilage-CPP interface instead of the tidemark, as occurs with osteochondral tissue, further study is required to optimize this system so that it more closely mimics the native tissue.

Porous silk scaffolds can be used for tissue engineering annulus fibrosus.

There is no optimal treatment for symptomatic degenerative disc disease which affects millions of people worldwide. One novel approach would be to form a patch or tissue replacement to repair the annulus fibrosus (AF) through which the NP herniates. As the optimal scaffold for this has not been defined the purpose of this study was to determine if porous silk scaffolds would support AF cell attachment and extracellular matrix accumulation and whether chemically decorating the scaffold with RGD peptide, which has been shown to enhance attachment for other cell types, would further improve AF cell attachment and tissue formation. Annulus fibrosus cells were isolated from bovine caudal discs and seeded into porous silk scaffolds. The percent cell attachment was quantified and the cell morphology and distribution within the scaffold was evaluated using scanning electron microscopy. The cell-seeded scaffolds were grown for up to 8 weeks and evaluated for gene expression, histological appearance and matrix accumulation. AF cells attach to porous silk scaffolds, proliferate and synthesize and accumulate extracellular matrix as demonstrated biochemically and histologically. Coupling the silk scaffold with RGD-peptides did not enhance cell attachment nor tissue formation but did affect cell morphology. As well, the cells had higher levels of type II collagen and aggrecan gene expression when compared to cells grown on the non-modified scaffold, a feature more in keeping with cells of the inner annulus. Porous silk is an appropriate scaffold on which to grow AF cells. Coupling RGD peptide to the scaffold appears to influence AF cell phenotype suggesting that it may be possible to select an appropriate scaffold that favours inner annulus versus outer annulus differentiation which will be important for tissue engineering an intervertebral disc.

Osteochondral defect repair using a novel tissue engineering approach: sheep model study.

Porous calcium polyphosphate (CPP) constructs of desired density were formed by sintering CPP powders. Articular cartilage was formed on these constructs in cell culture over an 8-week period with the resulting cartilage layer forming on the CPP surface and within the near surface pores thereby mechanically anchoring the cartilage to the CPP. The biphasic constructs so formed were implanted in sheep femoral condyle sites and left for short-term periods (3 to 4 months) or longer periods (9 months). Implant fixation within the condyle sites was achieved through bone ingrowth into the inferior CPP pores. The properties and characteristics of the as-in vitro-formed, short- and long-term implanted tissues were compared. The results indicated that such implants might be useful for repair of small subchondral defects.

Substrate porosity enhances chondrocyte attachment, spreading, and cartilage tissue formation in vitro.

Tissue engineering is being explored as a new approach to treat damaged cartilage. As the biomaterial used may influence tissue formation, the effects of substrate geometry on chondrocyte behavior in vitro were examined. Articular chondrocytes were isolated and cultured on the surface of smooth, rough, porous-coated, and fully porous Ti-6Al-4V substrates. The percentage of chondrocytes that attached to each substrate at 24 h was determined. After 24 and 72 h, chondrocytes were visualized by scanning electron microscopy and cell areas were measured. Collagen and proteoglycan accumulation within the first 24 h was determined by incorporation with [3H]-proline and [35S]-SO4, respectively. Chondrocyte attachment as well as matrix accumulation was enhanced as substrate surface area increased. Cell areas on the fully porous substrate were over four times greater than on any other substrate by 72 h in culture. After 8 weeks in culture, a continuous layer of cartilaginous tissue formed only on the surface of the fully porous substrate. This suggests that fully porous Ti-6Al-4V substrates provide the conditions that favor cartilage tissue formation by influencing cell attachment and extent of cell spreading. Understanding how substrate porosity influences chondrocyte behavior may help identify methods to further enhance cartilage tissue formation in vitro.

Cyclic compressive mechanical stimulation induces sequential catabolic and anabolic gene changes in chondrocytes resulting in increased extracellular matrix accumulation.

Overcoming the limited ability of articular cartilage to self-repair may be possible through tissue engineering. However, bioengineered cartilage formed using current methods does not match the physical properties of native cartilage. In previous studies we demonstrated that mechanical stimulation improved cartilage tissue formation. This study examines the mechanisms by which this occurs. Application of uniaxial, cyclic compression (1 kPa, 1 Hz, 30 min) significantly increased matrix metalloprotease (MMP)-3 and MMP-13 gene expression at 2 h compared to unstimulated cells. These returned to constitutive levels by 6 h. Increased MMP-13 protein levels, both pro- and active forms, were detected at 6 h and these decreased by 24 h. This was associated with tissue degradation as more proteoglycans and collagen had been released into the culture media at 6 h when compared to the unstimulated cells. This catabolic change was followed by a significant increase in type II collagen and aggrecan gene expression at 12 h post-stimulation and increased synthesis and accumulation of these matrix molecules at 24 h. Mechanical stimulation activated the MAP kinase pathway as there was increased phosphorylation of ERK1/2 and JNK as well as increased AP-1 binding. Mechanical stimulation in the presence of the JNK inhibitor, SP600125, blocked AP-1 binding preventing the increased gene expression of MMP-3 and -13 at 2 h and type II collagen and aggrecan at 12 h as well as the increased matrix synthesis and accumulation. Given the sequence of changes, cyclic compressive loading appears to initiate a remodelling effect involving MAPK and AP-1 signalling resulting in improved in vitro formation of cartilage.

Repair of osteochondral defects with biphasic cartilage-calcium polyphosphate constructs in a sheep model.

There has been interest in developing novel biological treatments to repair focal cartilage defects. We have developed a method of forming biphasic constructs ("osteochondral"-type plug) in vitro consisting of cartilaginous tissue, formed on and anchored to the intended articulation surface of a porous ceramic substrate. The purpose of this study was to evaluate the biochemical and biomechanical properties and morphology of in vitro-formed biphasic constructs 3 and 9 months after implantation into 4mm diameter full thickness osteochondral defects in the trochlear groove of sheep stifles. The implants withstood loading in vivo up to 9 months with evidence of fusion to adjacent native cartilage and fixation by bone ingrowth into the ceramic substrate. The cartilage layer was eroded from those implants that were proud to the joint surface. Control implants (ceramic only) had fibrous tissue on the articulating surface after implantation for 3-4 months. Neither the cellularity nor proteoglycan content of the implanted cartilage, when it remained, changed significantly between 3 and 9 months and the collagen content increased slightly. The elastic equilibrium modulus of the cartilage improved with time with the greatest improvement (10-fold) occurring early during the first 3-4 months after implantation. This study suggests that biphasic constructs may be suitable to repair joint defects as the implants were maintained up to 9 months in sheep. Importantly the mechanical properties of the implanted cartilage improved significantly after implantation suggesting that cartilage can mature in vivo after implantation. The results indicate that further study of this treatment approach is warranted to attempt to overcome the technical surgical difficulties identified in this study.

A single application of cyclic loading can accelerate matrix deposition and enhance the properties of tissue-engineered cartilage.

OBJECTIVE: Mechanical stimulation is a widely used method to enhance the formation and properties of tissue-engineered cartilage. While studies have evaluated the responsiveness of chondrocytes to mechanical stimuli, little is known about how much stimulation is actually required. Thus, the purpose of this study was to investigate the effect of a single application of cyclic loading to chondrocytes on the formation and properties of in vitro-formed tissue. DESIGN: Isolated bovine articular chondrocytes were seeded on ceramic substrates in 3D culture and subjected to a single application of compressive cyclic loading at 1, 8 or 15 days after seeding. Once the time at which the chondrocytes were most sensitive to mechanical loading was determined, the effect of a single application on the synthesis and accumulation of matrix molecules as well as the mechanical properties of the in vitro-formed cartilage tissue was evaluated. RESULTS: Chondrocytes were more responsive to cyclic loading applied early in culture. Cyclic forces applied 24 h after the cultures were established increased collagen and proteoglycan syntheses (48 +/- 11% and 49 +/- 11%, respectively). This single application of cyclic loading also increased the accumulation of collagen (stimulated: 207 +/- 20 microg, control: 173 +/- 9 microg) and proteoglycans (stimulated: 302 +/- 24 microg, control: 270 +/- 14 microg) as well as improved the mechanical properties of the in vitro-formed tissue (twofold increase in equilibrium stress and modulus) determined 4 weeks after the applied stimulus. CONCLUSIONS: A single application of cyclic loading to chondrocytes early in culture increased matrix accumulation and enhanced the mechanical properties of the in vitro-formed tissue. This suggests that mechanical forces do not have to be applied intermittently over long periods of time to accelerate in vitro tissue formation.

Effect of zoledronate on bone quality in the treatment of aseptic loosening of hip arthroplasty in the dog.

Periprosthetic bone loss, which is a direct cause of aseptic loosening in total hip arthroplasty (THA), can be suppressed by bisphosphonates. It is unknown how the quality of this bone is affected in the presence of both wear debris (from implant) and bisphosphonates. The objective of this study was to evaluate the effect of zoledronate (ZLN) on bone quality in the presence of wear debris [polyethylene (PE) particles] in a canine model of uncemented THA. Thirty dogs underwent THA, and aseptic loosening was induced via implantation of PE particles packed into the femoral component. For 26 weeks until sacrifice, two groups (each n = 10) received weekly injections of ZLN (low dose 2 mug/kg, high dose 10 mug/kg) and the third group (control) received saline. Histological and radiographic examinations were performed to evaluate the degree of implant reaction. Histomorphometry (static/dynamic) was performed to evaluate bone turnover. Back-scattered electron imaging was used to quantify the newly formed bone and to evaluate the mineralization distribution. Density fractionation and X-ray diffraction were used to evaluate mineral properties, while four-point bending was used to determine mechanical properties. A dose-dependent presence of newly formed subperiosteal bone was found, which appeared to be less mineralized than the adjacent cortical bone. The high-dose ZLN group showed decreased cortical porosity and turnover and increased mineralization profile, failure strength, and modulus. We conclude that ZLN affects some of the material properties of cortical bone and allows the newly formed subperiosteal bone to remain and therefore affect the overall quality of the bone.

The influence of anatomic location on functional outcome in lower-extremity soft-tissue sarcoma.

BACKGROUND: The purpose of this study was to explore the relationship between the anatomical location of lower-extremity soft-tissue sarcoma and functional outcome. METHODS: Function was evaluated with the Musculoskeletal Tumor Society (MSTS 1993) score and Toronto Extremity Salvage Score (TESS); 207 patients (median age, 54 years) were eligible. The median maximum tumor diameter was 8.0 cm; 58 tumors were superficial and 149 were deep. Nine locations based on anatomical compartments were defined: 6 tumors were in the groin/femoral triangle; 8, the buttock; 52, the anterior thigh; 22, the medial thigh; 20, the posterior thigh; 10, the popliteal fossa; 13, the posterior calf; 11, the anterolateral leg; and 7, the foot or ankle. RESULTS: Treatment of superficial tumors did not lead to significant changes in MSTS score (mean, 90.6% preoperatively vs. 93.0% postoperatively; P =.566) or TESS (mean, 86.4% preoperatively vs. 90.9% postoperatively; P =.059). Treatment of deep tumors lead to significant reductions in MSTS score and TESS (mean MSTS, 86.9% preoperatively vs. 83.0% postoperatively; P =.001; and mean TESS, 83.0% preoperatively vs. 79.4% postoperatively; P =.015). Anatomical location was not a significant predictor of aggregated MSTS and TESS evaluations. Exploratory analysis showed variation in MSTS pain and gait handicap or limp items and TESS dressing, sitting, bending, and bathing items by anatomical location. CONCLUSIONS: The treatment of superficial tumors does not lead to significant changes in MSTS score or TESS. Anatomical location is not a significant predictor of aggregated MSTS and TESS evaluations. However, there is variation in MSTS and TESS item scores across anatomical locations.

Chondrocyte interactions with porous titanium alloy and calcium polyphosphate substrates.

Chondrocytes maintain their phenotype and form cartilagenous tissue when cultured on calcium polyphosphate (CPP) or titanium alloy (Ti alloy), porous three-dimensional materials. To understand how these materials may influence chondrocyte phenotype and matrix synthesis, the early interactions of cultured cells with CPP and titanium alloy were examined. These were compared to chondrocytes grown in monolayer culture on tissue culture polystyrene, conditions in which cultured chondrocytes dedifferentiate and do not form cartilagenous tissue. Scanning electron microscopy of cells up to 72 h in culture showed that bovine chondrocytes on CPP, Ti alloy, and polystyrene were an admixture of round and spread cells. The spread cells on CPP and titanium alloy were not entirely flattened but maintained a polygonal shape. In contrast, spread chondrocytes in monolayer culture were flatter and significantly larger, a difference that was maintained even in the absence of serum. All cells cultured on CPP and Ti alloy exhibited subcortical ring-like distribution of actin filaments whereas the flattened cells on polystyrene showed actin filaments distributed throughout the cytoplasm. Cells on CPP and Ti alloy synthesized significantly less collagen and proteoglycans than cells cultured on polystyrene at 72 h of culture. In summary the cells on the porous three-dimensional materials differed from those on polystyrene in terms of cell morphology and size, actin cytoskeleton organization, and synthesis of selected matrix macromolecules. The data suggests that CPP and titanium alloy may mediate their effect by limiting cell spreading in part by favoring the maintenance of a ring-like actin distribution.