Browsing by Author "Dahlgren, Linda A."

Now showing 1 - 20 of 32
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    Adipose-Derived Adult Stem Cells as Trophic Mediators of Tendon Regeneration
    Stewart, Shelley Leigh (Virginia Tech, 2012-06-26)
    The adipose-derived stromal vascular fraction (SVF) is a promising new therapy for equine flexor tendonitis. This heterogeneous population of cells may improve tendon healing via the production of growth and chemotactic factors capable of recruiting endogenous stem cells and increasing extracellular matrix production by tendon fibroblasts (TFBL). The purpose of this study was to evaluate the ability of adipose-derived cells (ADC) culture expanded from the SVF to act as trophic mediators in vitro. We hypothesized that ADCs would produce growth and chemotactic factors important in tendon healing and capable of inducing cell migration and matrix protein gene expression. Superficial digital flexor tendons and adipose tissue were harvested from eight adult horses and processed to obtain SVF cells, ADCs and TFBLs. Adipose-derived cells and TFBLs were grown in monolayer culture for growth factor quantification, to produce conditioned media for microchemotaxis, and in co-culture for quantification of matrix protein gene expression by TFBLs. Growth factor gene expression by SVF cells was significantly greater than in ADCs or TFBLs. Co-culture of TFBLs and ADCs resulted in modest up-regulation of matrix protein expression (collagen types I and III, decorin, and cartilage oligomeric matrix protein) by TFBLs. Media conditioned by ADCs induced ADC migration in a dose dependent manner. These findings support the role of both SVF and ADCs as trophic mediators in tendon regeneration. The differences detected in gene expression between SVF cells and ADCs indicate that additional studies are needed to evaluate the changes that occur during culture of these cells.
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    Bone Marrow Mononuclear Cell for Equine Joint Disease
    Everett, James Blake (Virginia Tech, 2020-09-04)
    Osteoarthritis (OA) can be debilitating and career-ending for horses. Current treatments offer temporary and symptomatic relief, but potentially deleterious side effects. Bone marrow mononuclear cells (BMNC) are a rich source of macrophage progenitors that are anti-inflammatory and promote inflammation resolution. The objective of this study was to evaluate the ability of intra-articular BMNC therapy to improve clinical signs of naturally occurring equine OA. Horses presenting with clinical and radiographic evidence of moderate OA in a single joint were randomly assigned to 1 of 3 treatments: saline (negative control), triamcinolone (positive control), or BMNC (treatment group). Horses were subjectively and objectively evaluated for lameness and synovial fluid collected (cytology and cytokine/growth factor quantification) at 0, 7, and 21 days post-injection. Data were analyzed using General Estimating Equations with significance set at P<0.05. There were no adverse effects noted in any treatment group. No significant differences in synovial fluid cytology parameters, objective/subjective lameness scores, nor joint circumference were found between treatment groups at any time point. Within treatment groups, joint circumference did not change over time for saline- and triamcinolone-treated horses. However, joint circumference and objective lameness decreased significantly within BMNC-treated horses between Days 0 and 21 and Days 7 and 21. Lameness improved in saline-treated horses from 0 to 21 days, but did not improve in triamcinolone-treated horses. The decreased lameness and lack of adverse effects in the BMNC-treated horses in our study support a larger clinical trial using BMNC.
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    Bone marrow mononuclear cells for joint therapy: The role of macrophages in inflammation resolution and tissue repair
    Menarim, Bruno C.; MacLeod, James N.; Dahlgren, Linda A. (Baishideng, 2021-07-26)
    Osteoarthritis (OA) is the most prevalent joint disease causing major disability and medical expenditures. Synovitis is a central feature of OA and is primarily driven by macrophages. Synovial macrophages not only drive inflammation but also its resolution, through a coordinated, simultaneous expression of pro- and anti-inflammatory mechanisms that are essential to counteract damage and recover homeostasis. Current OA therapies are largely based on anti-inflammatory principles and therefore block pro-inflammatory mechanisms such as prostaglandin E2 and Nuclear factor-kappa B signaling pathways. However, such mechanisms are also innately required for mounting a pro-resolving response, and their blockage often results in chronic low-grade inflammation. Following minor injury, macrophages shield the damaged area and drive tissue repair. If the damage is more extensive, macrophages incite inflammation recruiting more macrophages from the bone marrow to maximize tissue repair and ultimately resolve inflammation. However, sustained damage and inflammation often overwhelms pro-resolving mechanisms of synovial macrophages leading to the chronic inflammation and related tissue degeneration observed in OA. Recently, experimental and clinical studies have shown that joint injection with autologous bone marrow mononuclear cells replenishes inflamed joints with macrophage and hematopoietic progenitors, enhancing mechanisms of inflammation resolution, providing remarkable and long-lasting effects. Besides creating an ideal environment for resolution with high concentrations of interleukin-10 and anabolic growth factors, macrophage progenitors also have a direct role in tissue repair. Macrophages constitute a large part of the early granulation tissue, and further transdifferentiate from myeloid into a mesenchymal phenotype. These cells, characterized as fibrocytes, are essential for repairing osteochondral defects. Ongoing "omics" studies focused on identifying key drivers of macrophage-mediated resolution of joint inflammation and those required for efficient osteochondral repair, have the potential to uncover ways for developing engineered macrophages or off-the-shelf pro-resolving therapies that can benefit patients suffering from many types of arthropaties, not only OA.
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    Bone Regeneration Potential of Mesenchymal Stromal Cells derived from a Clinically Relevant Rat Model of Osteoporosis
    Saverot, Scott-Eugene (Virginia Tech, 2020-04-09)
    Falls among the elderly are a major source of injury, often leading to serious fractures, hospitalization, and death. Osteoporosis (OP) is a global problem intimately related with these fractures, characterized by reduced bone mass, increased bone fragility. There exists a high failure rate in the translation of treatments to osteoporotic populations. Mesenchymal stromal cell (MSC) transplantation as a therapeutic strategy for OP has not yet been examined in clinical trials. This may be attributed to the mixed findings of pre-clinical studies aimed at determining the efficacy of MSC therapy towards bone regeneration in OP. The most common animal model of OP is ovariectomy (OVX) that simulates post-menopausal estrogen loss. A plethora of bone regeneration studies have used OVX models with 12-16 weeks post-OVX periods and have generally reported positive results from a variety of treatment modalities, including MSC therapy. However, the use of the minimum post-OVX period may not be appropriate to reflect the global changes in regenerative potential of OP patients. In our research group's previous study, MSC were isolated from a minimum 60 week post-OVX rat model, representing a severe case of OP. The MSC isolated from these animals are a unique cell population that we expect may better represent the outcomes of autologous cell therapies for the older patient population in the clinic. In the present study, adipose and bone marrow derived MSC from OVX and age-matched animals were evaluated for their osteogenic and adipogenic differentiation potentials in culture through passage 10. Results from this study suggest that bone marrow derived-MSC maintain their phenotype and functionality more effectively than adipose derived-MSC in OP. Further investigations used regenerative medicine approaches for cell expansion on keratin protein coated microcarriers in static culture. Hair-derived keratin biomaterials have demonstrated their utility as carriers of biologics and drugs for tissue engineering. An optimal microcarrier was selected that demonstrated superior retention of the protein coating through electrostatic interactions and high cell viability. Finally, the integration of cell-microcarriers into a perfusion bioreactor system was explored. Preliminary results demonstrated the feasibility of MSC growth and differentiation on microcarrier based packed beds. Moreover, AD-MSC from OP rats were unresponsive to both inductive media and shear stress related osteogenic cues. These results highlight the complexity and challenges associated with the MSC regenerative strategy.
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    Can isoprostanes be used to predict survival in horses with colic?
    Noschka, Erik (Virginia Tech, 2010-11-09)
    Approximately 4% of horses suffer from one colic episode per year. The outcome is fatal in 11% of cases. F2-isoprostanes are the "gold standard" for assessment of oxidative stress in vivo and have been used extensively to quantify lipid peroxidation in association with risk factors in various diseases in humans. Because horses with colic may have intestinal ischemia and/or inflammation characterized by oxidative stress and increased production of isoprostanes, measurement of isoprostane concentrations in colicky horses may be of clinical value. The purpose of this study was to gather preliminary data on the feasibility of using urine isoprostane concentrations as an early screening tool for the severity of colic and to determine the need for surgery. The long term goal of this investigation is to reduce the number of deaths due to colic by developing a stall-side test capable of identifying horses needing surgery as early as possible and expediting their timely referral. We hypothesized that urine isoprostanes and isoprostane metabolites would be significantly higher in horses with colic compared to normal horses and that they can be used an indicator for the need for surgical intervention. Urine samples were collected from 42 normal horses and 38 horses with colic (21 medical and 22 surgical). Urine isoprostane and isoprostane metabolite concentrations were measured by mass spectrometry and normalized by urine creatinine (Cr) concentrations. Statistical analysis was performed using a one way ANOVA (Tukey's post-hoc comparison) and a 2 sample t-test. Significance was set at P<0.05. Mean (± SD) concentrations of isoprostanes and isoprostane metabolites were significantly higher in urine samples of horses with colic (2.94 ± 1.69 ng/mg Cr and 0.31 ± 0.22 ng/mg Cr, respectively) compared to healthy horses (1.89 ± 1.39 ng/mg Cr and 0.22 ± 0.08 ng/mg Cr, respectively). Urine isoprostane metabolite concentrations were significantly higher in horses undergoing surgery (0.38 ± 0.28 ng/mg Cr) compared to healthy control horses and medically treated colic horses (0.26 ± 0.11 ng/mg Cr). Non-survivors had significantly higher mean urine isoprostane metabolite concentrations (0.47 ± 0.39 ng/mg Cr) compared to healthy control horses and surviving colic horses (0.29 ± 0.24 ng/mg Cr). Since urinary concentrations of isoprostane metabolites are increased in horses suffering from colic and in non-survivor colic horses, the measurement of urine concentrations of isoprostane metabolites may be an important prognostic indicator in equine colic.
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    The Chondroid Conundrum: Transpharyngeal Removal of Guttural Pouch Chondroids in Horses
    Cardona, Guillermo Andres (Virginia Tech, 2023-08-18)
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    Comparison of bone marrow mesenchymal stem cells and tendon progenitor cells cultured on collagen surfaces
    Brown, James Augustus (Virginia Tech, 2010-04-29)
    Tendon injuries are a significant cause of morbidity in performance horses with superficial digital flexor tendon injury reported to represent up to 43% of overall Thoroughbred racehorse injuries. Natural repair is slow and results in inferior structural organization and biomechanical properties and, therefore, reinjury is common. The inability of tendon to regenerate after injury, or to heal with mechanical properties comparable to the original tissue, is likely attributable to low vascularity and cellularity of the tissue, low number of resident progenitor cells, and healing under weight-bearing conditions. Strategies to improve tendon healing have focused on enhancing the metabolic response of tenocytes, modulating the organization of the newly synthesized extracellular matrix, or administering progenitor cells to enhance repair. Significant research effort has been directed at the use of adult mesenchymal stem cells as a source of progenitor cells for equine tendon repair and recent clinical applications have utilized adult autologous stem cells derived either from adipose tissue or bone marrow aspirates. Isolation of a homogenous population of stem cells from bone marrow is time-consuming, and there is much variation in cell numbers, cell viability and growth rates among samples. Recently, a population of progenitor cells has been isolated from equine flexor tendons, thus providing an alternative source of progenitor cells from the target tissue for therapeutic intervention. The interaction between cells and the extracellular matrix (ECM) is an important factor in regulation of cell function. Proliferation, migration, differentiation and gene expression of many cell types are altered by adhesion to and interaction with matrix proteins and the extracellular environment. Tendon progenitor cells reside within a niche that comprises primarily parallel collagen fibers, and this niche plays an important role in regulating their function and differentiation. Culture conditions replicating this environment could be beneficial for both cell growth and matrix gene expression. The objectives of the study were to compare cell growth kinetics and biosynthetic capabilities of bone marrow mesenchymal stem cells (BMMSCs) and tendon derived progenitor cells (TPCs) cultured on commercially available bovine, highly purified bovine, porcine, and rattus collagen sources and standard tissue culture surfaces. We hypothesized that collagen type I matrix would preferentially support TPC proliferation and up regulate gene expression for collagens and organizational components of tendon and therefore provide a culture system and progenitor cell type with advantages over the current practice of BMMSC expansion on standard cell culture plastic surfaces. Cells were isolated from 6 young adult horses, expanded, and cultured on collagen-coated tissue culture plates, and no collagen control for 7 days. Samples were analyzed for cell number on days 4 and 7, and for mRNA expression of collagen type I, collagen type III, cartilage oligomeric matrix protein (COMP), and decorin on day 7. Glycosaminoglycan (GAG) synthesis was analyzed on day 7. Differences of cell number between collagen groups and cell type, and in gene expression and GAG synthesis between collagen groups and cell types, were evaluated by use of mixed-model repeated measures ANOVA. Pair-wise comparisons were made on significant differences identified with ANOVA using Tukey's post hoc test. Statistical significance was set at P<0.05. A statistical significant (P=0.05) increase in cell number for TPCs grown on rattus collagen versus control on day 4 was observed. No difference in GAG synthesis or expression of collagen type I, collagen type III, COMP or decorin mRNA was observed between collagen groups and non-collagen controls for either cell type on day 7. TPCs cultured on all collagen types yielded more cells than similarly cultured BMMSCs on day 4, but only porcine collagen was superior on day 7. TPCs synthesized more GAG than BMMSCs when cultured on control surfaces only. BMMSCs expressed more collagen type I mRNA when cultured on control, porcine and highly-purified collagen, and more collagen type III when cultured on control, porcine, highly-purified collagen, and rattus collagen, than TPCs. Tendon-progenitor cells expressed significantly more COMP when cultured on control and all collagen types, and decorin when cultured on porcine, highly purified bovine and bovine collagen when compared to BMMSCs. The results of this study revealed an advantage to culturing TPCs on randomly organized rattus collagen during the early growth phase. The beneficial effects of collagen-coated surfaces on cell proliferation is likely related to increased surface area for attachment and expansion provided by the random collagen matrix, and/or collagen-cell interactions. Tendon progenitor cells showed superior growth kinetics and expression of the matrix organizational components, COMP and decorin, than similarly cultured BMMSCs that expressed more collagen types III and I. TPCs synthesize more GAG compared to BMMSCs when cultured on plastic surfaces and there was no induction by collagen. Tendon progenitor cells should be considered as an alternative source of progenitor cells for injured equine tendons. Further in vitro studies characterizing factors that influence gene expression of both cell types is warranted.
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    Comparison of platelet counting technologies in equine platelet concentrates
    O'Shea, Caitlin Mary (Virginia Tech, 2014-04-16)
    Platelet rich plasma (PRP) is a popular autologous biological therapy used for the treatment of various equine ailments, including tendon and ligament injuries, osteoarthritis, and cutaneous wounds. A number of commercial products are available for producing PRP, each generating a slightly different product. Variations in platelet numbers and white blood cell (WBC) counts are believed to be the most critical variables, as they are directly related to concentrations of growth factors and inflammatory cytokines. Accurate documentation of platelet numbers is essential for prospective evaluation of clinical outcomes, but can be problematic in platelet concentrates depending on the counting method employed. The objectives of this study were to compare the performance of four platelet counting technologies in equine platelet concentrates and to evaluate the ability of the Magellan PRP system to concentrate equine platelets. We hypothesized that there would be no differences in platelet counts among the four counting technologies and that the Magellan system would generate platelet concentrations greater than 500,000/μL. Citrated whole blood was collected from 32 horses and platelet, WBC, and red blood cell concentrations were measured using a commercial hematology analyzer (Advia 2120) prior to preparation of PRP using the Magellan system. Platelets were quantified in individual identical aliquots of equine PRP produced by the Magellan system (n=32) using three different technologies: optical scatter (Advia 2120), impedance (CellDyn 3700), and hand count using direct microscopy (Thrombo-TIC). An immunofluorescent counting method was performed on a subset of 15 of the 32 samples using a mouse monoclonal anti-sheep antibody against integrin alpha αIIbβ₃ (anti-CD41/CD61) and a fluorescent secondary antibody. Measured platelet concentrations were compared using Passing and Bablok regression analyses and mixed model ANOVA. The Magellan PRP system yielded mean (± SD) platelet and WBC counts of 893,090 ± 226,610/μL and 35,806 ± 9,971/μL, respectively. Platelet counts generated by optical scatter were consistently higher than those generated by impedance. Systematic and proportional biases were observed between these two automated methods. No bias (systematic or proportional) was observed among any of the other counting methods. Despite the bias detected between the two automated systems, there were no significant differences on average among the four counting methods evaluated, based on the ANOVA. All four platelet counting methods tested are therefore suitable for quantifying platelets in equine PRP for clinical applications. The Magellan PRP system consistently generated desirably high platelet concentrations as well as higher than expected WBC concentrations. The high platelet concentrations served as a good test medium for the study; however, the concurrent high WBC counts may be undesirable for selected orthopedic applications.
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    Complementary Strategies to Promote Mesenchymal Stem Cell Differentiation for Ligament Tissue Engineering
    Shaffer, Robyn Denise (Virginia Tech, 2010-11-01)
    Anterior cruciate ligament (ACL) ruptures and tears are significant orthopedic problems that result in discomfort and limited mobility. Fully functional tissue engineered ligament replacements are promising alternatives to current graft choices for repair of ACL disruptions. The cell-based approach to construct engineered ligament grafts presented herein involves the culture of mesenchymal stem cells (MSC) on biodegradable, fibrous polymeric scaffolds to promote tissue formation. Multipotent MSCs are advantageous because of their in vitro proliferative capacity and ease of harvest; however; the promotion of MSC differentiation into mature fibroblasts and subsequent extracellular matrix (ECM) development is unknown. The proposed studies utilized three complementary methods to promote differentiation of MSCs: scaffold architecture, mechanical stretch and over-expression of the transcription factor, scleraxis. First, elastomeric scaffolds were fabricated by electrospinning a segmented poly(esterurethane urea) with variations in fiber diameter and fiber alignment. Primary mesenchymal stem cells and the mesenchymal stem cell line, C3H10T1/2, were seeded on these scaffolds and assumed spindle-shaped morphologies and oriented with the direction of fiber alignment. Fiber diameter affected cellular responses, including the expression of ECM genes (e.g. collagen type 1 and decorin) which were elevated on smaller mean fiber diameter scaffolds initially. However, scleraxis gene expression was greatest on larger mean fiber diameter scaffolds at the end of two weeks. Second, cyclic stretch was applied to C3H10T1/2 cells on semi-aligned scaffolds using a novel bioreactor. Cell attachment was verified during and after the application of mechanical stress by confocal microscopy. Cyclic stretch induced cells to assume a highly elongated morphology; however ECM gene expression changes were moderate. Third, forced constitutive expression of scleraxis was accomplished by nucleofection of C3H10T1/2 cells. Transient mRNA expression, accumulation of the gene product in the cell nucleus, and cell death were observed. Future work will seek to refine the experimental methods, including the development and testing of an inducible scleraxis transgene and the application of longer periods of mechanical stimulation. Finally, these complementary approaches may be combined to further extend this work in pursuit of directed differentiation of stem cells and the ensuing generation of a robust tissue graft.
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    Complementary strategies to promote the regeneration of bone-ligament transitions using graded electrospun scaffolds
    Samavedi, Satyavrata (Virginia Tech, 2013-05-03)
    Grafts currently used for the repair of anterior cruciate ligament (ACL) ruptures integrate poorly with bone due to a significant mismatch in properties between graft and bone. Specifically, conventional grafts (e.g., hamstring tendon) are unable to recapitulate intricate gradients in mechano-chemical properties and extracellular matrix (ECM) architecture found at natural bone-ligament (B-L) transitions, and thus result in stress-concentrations at the graft-bone interface leading to graft failure. In contrast, tissue-engineered scaffolds possessing gradients in properties can potentially guide the establishment of phenotypic gradients in bone marrow stromal cells (BMSCs), and thus aid the regeneration of B-L transitions in the long-term. Towards the eventual goal of regenerating complex tissue transitions, this project employs three complementary strategies to fabricate graded scaffolds. The three strategies involve the presentation of gradients in 1) mineral content, 2) scaffold architecture and 3) growth factor (GF) concentration within scaffolds to control BMSC morphology and phenotype. The first strategy involved co-electrospinning two polymers (one doped with hydroxyapatite) from offset spinnerets onto a rotating drum to produce scaffolds possessing a gradient in mineral content. Post-electrospinning, these graded scaffolds were treated with a simulated body fluid to further enhance the gradient. Analysis of mRNA expression of osteoblastic makers by BMSCs and the deposition of bone-specific ECM proteins indicated that the scaffolds could guide the formation of an osteoblastic phenotypic gradient. The second strategy involved electrospinning two polymer solutions onto a custom-designed dual-drum collector to fabricate scaffolds possessing region-wise differences in fiber alignment, diameter and chemistry. Specifically, electrospinning onto the dual-drum collector resulted in the deposition of aligned fibers from one polymer solution in the gap region between the drums, randomly oriented fibers from the other polymer solution on one of the drums and a mixture of fibers from both polymer solutions in the overlap region in between. The topographical cues within these scaffolds were shown to result in region-dependent BMSC morphology and orientation. Although the long-term goal of the third strategy was to create a co-electrospun scaffold possessing a gradient in GF concentration, a new technique to protect GF activity within electrospun scaffolds via the use of gelatin microspheres was first validated. Preliminary results from these studies indicate that microspheres can protect and deliver a model protein (lysozyme) in active conformation from electrospun scaffolds. These results further suggest that gradients of GF concentration can be achieved in the long-term by protecting GFs within microspheres and co-electrospinning as described in the first strategy. In conclusion, the results from this project suggest that graded scaffolds can help guide the formation of gradients in cell morphology, orientation and phenotype, and thus potentially promote the regeneration of B-L transitions in the long-term. The three strategies described in this project can be employed in concert to create scaffolds intended for the regeneration of complex tissue transitions.
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    Cytokine and Growth Factor Concentrations in Canine Autologous Conditioned Serum
    Sawyere, Dominique M. (Virginia Tech, 2016-05-27)
    The object of this study was to compare growth factor and cytokine profiles in canine autologous conditioned serum (ACS) to canine plasma. Blood collected from 16 medium to large breed dogs was used to produce ACS (Orthokine® vet irap 10 syringes) and citrated plasma (control). Canine-specific ELISA assays were run per manufacturers’ instructions for interleukin (IL)-10, IL-4, tumor necrosis factor (TNF)-α, insulin-like growth factor (IGF)-1, fibroblast growth factor (FGF)-2, transforming growth factor (TGF)-β1, IL-1β, and interleukin-1 receptor antagonist (IL-1ra). Serum, in addition to plasma and ACS, was collected from an additional 6 dogs for TNF-α, IL-1β, and IL-1ra analysis (total of 22 dogs). Data were analyzed for differences in cytokine concentrations between ACS, plasma, and serum using the Wilcoxon signed-rank test with significance set at P<.05.There was a large variability in growth factor and cytokine concentrations between individual dogs in both plasma and ACS. There were no significant differences in IL-10, TNF-α, IGF-1, FGF-2, and TGF-β1 concentrations between ACS, plasma, or serum. ACS concentrations of IL-1β (median, range; 46.3 pg/mL, 0-828.8) and IL-4 (0.0 pg/mL, 0-244.1) were significantly increased compared to plasma (36.6 pg/mL, 0-657.1 and 0.0 pg/mL, 0-0, respectively). IL-1ra concentrations in ACS (median, range; 3458.9 pg/mL, 1,243.1-12,089.0) were significantly higher than plasma (692.3 pg/mL, 422.5- 1,475.6), as was the IL-1ra:IL-1β ratio (39.9 and 7.2, respectively).
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    Design, Fabrication, and Characterization of Three Dimensional Complete Scaffolds for Bone Tissue Engineering
    Andric, Tea (Virginia Tech, 2012-03-03)
    Skeletal loss and bone deficiencies are major worldwide problem that is only expected to increase due to increase in aging population. As current standards in treatment autografts and allografts are not without drawbacks, there is a need for alternative bone grafts substitutes. The goal of this project was to utilize electrospinning and heat sintering techniques to create biodegradable full thickness three dimensional biomimetic polymeric scaffolds with macro and nano architecture similar to natural bone for bone tissue engineering. First we have investigated pretreatment with 0.1M NaOH and electrospinning gelatin/PLLA blends as means to increase overall mineral precipitation and distribution throughout the scaffolds when incubated in concentrated simulated body fluid (SBF)10XSBF. Mixture of 10% gelatin and PLLA resulted in the significantly higher degree of mineralization, increased mechanical properties, and scaffolds that supported cellular adhesion and proliferation. In the next step we applied heat sintering technique to fabricate 3D electrospun scaffolds that were used to evaluate effects of mineralization and fiber orientation on scaffold strength. Fiber orientation can make a slight difference in nanofibrous scaffold compressive mechanical properties, but this difference is not as profound as the difference seen with increased mineralization. We also developed a technique to fabricate scaffolds that mimic the organization of an osteon, the structural unit of cortical bone. Resulting scaffolds consisted of concentric layers of electrospun gelatin/PLLA nanofibers wrapped around microfiber core with diameters that ranged from 200-600µm. Individual osteon-like scaffolds were heat sintered to fabricate three dimensional scaffolds contained a system of channels running parallel to the length of the scaffolds, as found naturally in bone tissue. Finally we combined two previously fabricated structures, sintered electrospun sheets and individual osteon-like scaffolds, to create novel scaffolds that mimic dual structural organization of natural bone with cortical and trabecular regions. Mineralization for 24 hr significantly increased mechanical properties of the scaffolds, both yield stress and compressive modulus under physiological conditions. Both nonminerlized and mineralized scaffolds were found to support cellular attachment and proliferation over 28 days in culture, but scaffolds mineralized for 24hr were found to better support osteoblastic differentiation and mineral deposition.
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    Effect of a single intra-articular injection of bupivacaine on synovial fluid prostaglandin E2 concentrations in normal canine stifles
    Giangarra, Jenna E.; Barry, Sabrina L.; Dahlgren, Linda A.; Lanz, Otto I.; Benitez, Marian E.; Werre, Stephen R. (2018-04-25)
    Objective: To identify if synovial fluid prostaglandin E2 increases in response to a single intra-articular dose of bupivacaine in the normal canine stifle. Results: There were no significant differences in synovial fluid prostaglandin E2 (PGE2) concentrations between treatment groups or over time within bupivacaine or saline groups. Samples requiring ≥ 3 arthrocentesis attempts had significantly higher PGE2 concentrations compared to samples requiring 1 or 2 attempts. Following correction for number of arthrocentesis attempts, PGE2 concentrations were significantly higher than baseline at 24 and 48 h in the bupivacaine group; however there were no significant differences between the bupivacaine and saline groups. In normal dogs, a single bupivacaine injection did not cause significant synovial inflammation, as measured by PGE2 concentrations, compared to saline controls. Future research should minimize aspiration attempts and include evaluation of the synovial response to bupivacaine in clinical cases with joint disease.
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    Effect of a single intra-articular injection of bupivacaine on synovial fluid prostaglandin E2 concentrations in normal canine stifles
    Giangarra, Jenna Elizabeth (Virginia Tech, 2018-06-19)
    Intra-articular bupivacaine is a common analgesic used in dogs with orthopedic disease. Bupivacaine has been linked to chondrotoxicity. The mechanism for bupivacaine's chondrotoxicity is unknown, but may involve inflammation. Prostaglandin E2 (PGE2) is an inflammatory mediator and a marker of joint inflammation. The aim of this study was to compare synovial fluid PGE2 concentrations after a single intra-articular injection of bupivacaine with a saline control in normal canine stifles. We hypothesized that bupivacaine stifles would have a significantly elevated PGE2 concentration compared to controls. Stifles from eight healthy, adult Beagles were randomly selected as the treated stifle and infused with bupivacaine. The contralateral stifle was injected with saline. Synovial fluid was collected before and after injection. PGE2 was quantified using a commercial ELISA. Data were transformed and mixed model ANOVA was performed with significance set at p<0.05. There were no significant differences in PGE2 concentration between treatment groups or times. Samples acquired with one or two aspiration attempts had significantly lower PGE2 concentrations than samples with =3 aspiration attempts (p=0.001). When adjusted for number of attempts, PGE2 concentrations were significantly higher 24 (p=0.003) and 48 (p=0.041) hours after injection compared to baseline in the bupivacaine group, but not in the saline group. Intra-articular bupivacaine injection did not result in increased synovial fluid PGE2 concentrations compared to controls; however, multiple aspiration attempts did, suggesting that synovial fluid PGE2 concentration is sensitive to multiple fluid collection attempts. Future studies investigating synovial fluid inflammatory mediators should consider methods to minimize aspiration attempts.
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    Effect of Electrospun Mesh Diameter, Mesh Alignment, and Mechanical Stretch on Bone Marrow Stromal Cells for Ligament Tissue Engineering
    Bashur, Christopher Alan (Virginia Tech, 2009-04-21)
    The overall goal of this research project is to develop methods for producing a tissue engineered ligament. The envisioned tissue engineering strategy involves three steps: seeding bone marrow stromal cells (BMSCs) onto electrospun scaffolds, processing them into cords that allow cell infiltration, and conditioning them with uniaxial cyclic stretch. These steps were addressed in three complimentary studies to establish new methods to engineer a tissue with ligament-like cells depositing organized extracellular matrix (ECM). In the first study scaffold topographies were systematically varied to determine topographies that induce cells to orient and differentiate into ligament-like cells in static culture. Scaffolds — electrospun from poly (ester-urethane urea) (PEUUR) with different fiber diameters degrees of fiber alignments — were biocompatible and supported cell growth. Topographic cues guided cell alignment, and cell elongation increased with increasing fiber alignment. Finally, expression of the ligament-like markers collagen type I and decorin were enhanced on the smallest fiber diameters compared to larger diameters. In the second study BMSCs — seeded onto aligned electrospun PEUUR scaffolds — were cyclically stretched to determine the effect of dynamic mechanical stimulation on BMSC alignment and differentiation. BMSCs remained aligned parallel to the direction of fiber alignment and expressed ligament markers (e.g. collagen type I, decorin, scleraxis, and tenomodulin) on electrospun scaffolds after the application of stretch. However, the cyclic stretch regimen was not able to enhance expression of ECM components. In the third study techniques were developed to produce more clinically relevant constructs with improved cell infiltration. Specifically, a co-electrospun scaffold composed of two well integrated components was developed to create larger pores. The scaffold was also embedding in a photo-crosslinkable hydrogel to prevent the fibers from collapsing. These results demonstrate the feasibility of making a tissue engineered ligament by seeding BMSCs on an aligned, co-electrospun scaffold with submicron diameter fibers and then applying cyclic mechanical stretch. Future work will involve combining these three steps to achieve materials suitable for in vivo testing.
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    Effects of Three Corticosteroids on Equine Articular Cocultures In Vitro
    Trahan, Richard Angellas (Virginia Tech, 2018-06-08)
    The objective was to compare the effects of three corticosteroids at various equimolar concentrations on equine articular explant co-cultures in an inflammatory environment. Synovial and osteochondral explant co-cultures from 6 equine cadavers were exposed to IL-1β (10 ng/mL) and various concentrations (10-4, 10-7, or 10-10 M) of MPA, TA, IPA. Concentrations of PGE2, MMP-13, LDH, and GAG in media were determined at 48 and 96 hours. Results indicated wells with low concentrations of MPA (10-7 and 10-10 M at 48 and 96 hours), TA (10-7 M at 48 hours and 10-7 and 10-10 M at 48 and 96 hours), and IPA (10-10 M at 48 hours) had significantly less PGE2 than positive control samples. Groups with low concentrations (10-7 and 10-10 M) of MPA and TA had significantly less PGE2 than the highest concentration (10-4 M) at 48 hours. Significantly less MMP-13 was detected for all concentrations of MPA, TA, and IPA at 96 hours. The LDH assay results indicated cytotoxicity only for samples treated with IPA at 10-4 M at 48 and 96 hours. GAG was significantly lower for samples treated with TA 10-7 M at 48 hours and MPA 10-10 M at 96 hours versus positive controls. These findings suggest corticosteroids at low concentrations mitigated the inflammatory and catabolic effects of IL-1β to a greater extent than high concentrations. Effects of IPA and MPA were similar to TA at clinically relevant low equimolar concentrations.
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    Equine Septic Arthritis and Serum Amyloid A
    Ludwig, Elsa Karen (Virginia Tech, 2016-07-07)
    Bacterial infection within a joint, septic arthritis, is a serious condition in horses that can lead to long-term joint disease if the infection is not resolved quickly. Equine septic arthritis is diagnosed primarily based on clinical signs and synovial fluid cytology. Septic synovial fluid is characterized by significant elevations in total protein (TP) and total nucleated cell count (TNCC). However, in some cases it can be difficult to distinguish between septic arthritis and non-septic joint inflammation (synovitis) based on clinical signs and synovial fluid cytology alone. A rapid assay to help confirm septic arthritis would be advantageous. A new assay to quantify the major equine acute phase protein, serum amyloid A (SAA) may fulfill this need. Serum amyloid A increases in the body in response to injury, infection, and inflammation and shows promise as a useful tool in confirming a diagnosis of sepsis, as inflammation causes mild increases in SAA and infection causes marked elevations. In our study, serial serum and synovial fluid samples were collected from horses with experimental models of synovitis and septic arthritis, synovial fluid cytology was performed, and serum and synovial fluid SAA were quantified. Synovial fluid TNCC and TP concentrations increased significantly following induction of both models. Serum and synovial fluid SAA concentrations remained normal in synovitis horses and increased significantly in septic arthritis horses. Any elevation in serum or synovial fluid SAA above normal values may be supportive of synovial sepsis since synovial inflammation alone did not result in SAA elevations in our model.
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    Evaluation of extracorporeal shockwave for treatment of horses with thoracolumbar pain
    Burns, Lauren Trager (Virginia Tech, 2019-09-24)
    The objective of this study was to evaluate effects of extracorporeal shockwave therapy (ESWT) on spinal mechanical nociceptive threshold (MNT) and multifidus muscle cross-sectional area (CSA) in horses with thoracolumbar pain. We hypothesized that ESWT would increase MNT and multifidus CSA. Twelve horses with thoracolumbar pain were included. Prior to treatment, each thoracolumbar spine was radiographed to document existing pathology. Horses received 3 ESWT treatments, 2 weeks apart (days 0, 14, 28). Palpation scores were documented (days 0, 45, 65) and ultrasonographic CSA of left and right multifidus was recorded at T12, T14, T16, T18, L3 and L5 (days 0, 45, 65). MNT was measured at T12, T14, T16, T18, L3 and L5 every 7 days (day 0-56). Change in MNT in 10/12 horses was significant at each timepoint compared to day 0 (P<0.05). MNT increased at all timepoints at 6 sites in 2/12, at 5 sites in 3/12, at 4 sites in 4/12 and at 1 site in 1/12 (P<0.05). MNT average percent increase from day 0-56 was 64% for T12-T18 and 29% for L3-L5. There was no statistical difference in MNT from day 35-56 (P=0.25). A bimodal analgesic trend was observed following ESWT. Degree of radiographic change was not associated with response to treatment and no significant change in multifidus CSA was observed. In conclusion, 3 treatments of ESWT 2 weeks apart raised MNT over a 56-day period in horses with back pain, but did not influence change in CSA of the multifidus.
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    Focused Ultrasound Methods for the treatment of Tendon Injuries
    Meduri, Chitra (Virginia Tech, 2023-07-19)
    Tendon injuries are prevalent, debilitating and difficult to treat. Common interventions such as anti-inflammatory medication, growth factor injections and surgery are associated with short-term efficacy and long rehabilitation periods. Tendons possess an incomplete healing response which is reparative (scar-mediated) rather than regenerative, resulting in a 'healed' tissue that is mechanically inferior to the native tendon. While it is widely accepted that mechanical-loading based treatments offer long-term symptomatic resolution and improved functionality, the exact mechanisms of action of such mechanotransduction-based healing cascades remain unclear. Nevertheless, there is significant motivation for the development of non-invasive and efficient rehabilitative treatments that mechanically stimulate the injured tendons to achieve functional healing responses. Focused Ultrasound (FUS) methods are an attractive treatment option as they are non-invasive, utilize higher intensities for shorter durations and are targeted to a very specific treatment volume, hence inducing significant bio-effects in the tissue without affecting surrounding structures. Herein, we present a body of work that includes the development of FUS pulsing to precisely target murine Achilles tendons and emphasize distinct bioeffects (thermal-dominant and mechanical-dominant). We investigated the feasibility of applying FUS pulsing to murine Achilles tendons ex vivo and in vivo and demonstrated that FUS can be safely applied without any deleterious effects in the tendons and surrounding tissues. The animals showed no symptoms of distress after multi-session treatments. Overall, results suggest that tendon material properties are not adversely altered by FUS pulsing. Histological analyses showed mild matrix disorganization, suggesting the need for slight modifications in the ultrasound pulsing parameters and treatment durations. When applied to injured tendons, mechanical dominant schemes seemed to drive larger improvements in material properties compared to thermal-dominant pulsing, confirming our original hypothesis that mechanical stimulation may play a bigger role in tendon healing compared to purely thermal-dominant stimulation. Additionally, feasibility of histotripsy ablation in murine Achilles tendons was successfully investigated ex vivo and in vivo and experimentation to further optimize these methods are ongoing. Such (non-thermal) ablative paradigms will be extremely useful when conservative treatment options are unavailable and debridement of scar tissue is warranted to interrupt the degenerative process and stimulate healing. Finally, a pilot investigation into FUS-induced strains was performed to guide our parameter selection process and deliver controlled strains to achieve healing responses (similar to current clinical rehabilitation protocols). We were able confirm that strains between 1% and 6% (or higher) can be induced by manipulating ultrasound treatment parameters. Overall, or results reiterate the potential of FUS in eliciting the desired bioeffects and thus achieve healing in tendons and provide a snapshot of the expected effects of using such pulsing methods to treat tendon injuries.
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    In Vitro Equine Flexor Tendonitis: New Model Development and Therapeutic Investigation
    Cissell, James Michael (Virginia Tech, 2009-07-08)
    Flexor tendonitis is a common cause of lameness and wastage in the equine athlete. Current techniques for tendonitis therapy provide limited success, and horses that do recover tend to return at a decreased level of performance. Current treatment techniques have begun to focus on regenerative medicine to improve tissue healing. Investigations of new treatments are made difficult by the lack of reliable in vitro models that allow for accurate comparison of treatment protocols. New techniques are often implemented into the clinical setting prior to thorough investigation for safety and efficacy. In vitro testing is an important step in the development of new therapeutic agents. However, results of in vitro tests should only be deemed as useful if the model used is one that is reliable and mimics the clinical situation that the reseachers are attempting to investigate. Equine flexor tendonitis is believed to be the result of microdamage caused by cyclic loading of tendons. Cyclic loading of fibroblasts results in increased production of the inflammatory cytokine prostaglandin E2 (PGE2). Thus the exposure of tendon fibroblasts to exogenous PGE2 may induce metabolic changes in the cells similar to what is seen in clinically affected animals making this a useful model for the investigation of therapeutic techniques. Currently a variety of techniques exist for treatment of flexor tendonitis; however, no single treatment has separated itself as superior. A new technique using autogenous conditioned serum (ACS) in humans for treatment of muscle injury has been shown to speed tissue regeneration. ACS produced from human blood has been shown to contain significantly increased levels of III growth factors that may improve tendon fibril formation and strength. We propose to investigate the effect of ACS on cellular metabolism in equine tendon fibroblast monolayers. This will involve cell culture, PGE2-induced cellular injury, and analysis of the cellular response to injury when treated with ACS. Controls will include fetal bovine serum, normal equine serum, and ACS without PGE2-induced cellular injury. The cellular response will be investigated biochemically by quantification of DNA, glycosaminoglycan, and soluble collagen levels and by real time PCR to assess gene expression for matrix metalloproteinases (MMP)-1, MMP-3, and MMP-13, collagen types I and III, and the non-collagenous proteins cartilage oligomeric matrix protein (COMP) and decorin. Data will be analyzed by analysis of variance and post-hoc comparisons. Significance will be set at p<0.05. We hypothesize that the addition of exogenous PGE2 to culture media for monolayers of equine tendon fibroblasts will insight alterations in cellular metabolism that will generate a suitable model for the in vitro study of fibroblast response to novel therapies. We then hypothesize that the addition of ACS to PGE2-treated fibroblasts will result in increased gene expression for collagen types I and III, cartilage oligomeric matrix protein, and decorin. ACS will also stimulate increased protein production of collagen and glycosaminoglycans, and stimulate increased cell proliferation. The use of ACS will decrease gene expression of inflammatory molecules important in tendon degradation, namely matrix metalloproteinases -1, -3, and -13.