Browsing by Author "Voytik-Harbin, Sherry"
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Item Computational Mechanobiology Model Evaluating Healing of Postoperative Cavities Following Breast-Conserving Surgery(bioRxiv, 2023-04-28) Harbin, Zachary; Sohutskay, David; Vanderlaan, Emma; Fontaine, Muira; Mendenhall, Carly; Fisher, Carla; Voytik-Harbin, Sherry; Buganza Tepole, Adrian; Surgery, School of MedicineBreast cancer is the most commonly diagnosed cancer type worldwide. Given high survivorship, increased focus has been placed on long-term treatment outcomes and patient quality of life. While breast-conserving surgery (BCS) is the preferred treatment strategy for early-stage breast cancer, anticipated healing and breast deformation (cosmetic) outcomes weigh heavily on surgeon and patient selection between BCS and more aggressive mastectomy procedures. Unfortunately, surgical outcomes following BCS are difficult to predict, owing to the complexity of the tissue repair process and significant patient-to-patient variability. To overcome this challenge, we developed a predictive computational mechanobiological model that simulates breast healing and deformation following BCS. The coupled biochemical-biomechanical model incorporates multi-scale cell and tissue mechanics, including collagen deposition and remodeling, collagen-dependent cell migration and contractility, and tissue plastic deformation. Available human clinical data evaluating cavity contraction and histopathological data from an experimental porcine lumpectomy study were used for model calibration. The computational model was successfully fit to data by optimizing biochemical and mechanobiological parameters through the Gaussian Process. The calibrated model was then applied to define key mechanobiological parameters and relationships influencing healing and breast deformation outcomes. Variability in patient characteristics including cavity-to-breast volume percentage and breast composition were further evaluated to determine effects on cavity contraction and breast cosmetic outcomes, with simulation outcomes aligning well with previously reported human studies. The proposed model has the potential to assist surgeons and their patients in developing and discussing individualized treatment plans that lead to more satisfying post-surgical outcomes and improved quality of life.Item Computational Mechanobiology Model Evaluating Healing of Postoperative Cavities Following Breast-Conserving Surgery(Elsevier, 2023) Harbin, Zachary; Sohutskay, David; Vanderlaan, Emma; Fontaine, Muira; Mendenhall, Carly; Fisher, Carla; Voytik-Harbin, Sherry; Buganza Tepole, Adrian; Surgery, School of MedicineBreast cancer is the most commonly diagnosed cancer type worldwide. Given high survivorship, increased focus has been placed on long-term treatment outcomes and patient quality of life. While breast-conserving surgery (BCS) is the preferred treatment strategy for early-stage breast cancer, anticipated healing and breast deformation (cosmetic) outcomes weigh heavily on surgeon and patient selection between BCS and more aggressive mastectomy procedures. Unfortunately, surgical outcomes following BCS are difficult to predict, owing to the complexity of the tissue repair process and significant patient-to-patient variability. To overcome this challenge, we developed a predictive computational mechanobiological model that simulates breast healing and deformation following BCS. The coupled biochemical-biomechanical model incorporates multi-scale cell and tissue mechanics, including collagen deposition and remodeling, collagen-dependent cell migration and contractility, and tissue plastic deformation. Available human clinical data evaluating cavity contraction and histopathological data from an experimental porcine lumpectomy study were used for model calibration. The computational model was successfully fit to data by optimizing biochemical and mechanobiological parameters through Gaussian process surrogates. The calibrated model was then applied to define key mechanobiological parameters and relationships influencing healing and breast deformation outcomes. Variability in patient characteristics including cavity-to-breast volume percentage and breast composition were further evaluated to determine effects on cavity contraction and breast cosmetic outcomes, with simulation outcomes aligning well with previously reported human studies. The proposed model has the potential to assist surgeons and their patients in developing and discussing individualized treatment plans that lead to more satisfying post-surgical outcomes and improved quality of life.Item Eliciting and Characterizing Porcine Vocalizations: When Pigs Fly(Elsevier, 2022-04-30) Zhang, Lujuan; Fujiki, Robert Brinton; Brookes, Sarah; Calcagno, Haley; Awonusi, Oluwaseyi; Kluender, Keith; Berry, Kevin; Venkatraman, Anumitha; Maulden, Amanda; Sivasankar, M. Preeti; Voytik-Harbin, Sherry; Halum, Stacey; Otolaryngology -- Head and Neck Surgery, School of MedicineBackground/Objectives: While voice-related therapeutic interventions are often researched preclinically in the porcine model, there are no well-established methods to induce porcine glottic phonation. Described approaches such as training animals to phonate for positive reinforcement are time-consuming and plagued by inherent variability in the type of phonation produced and contamination of background noise. Thus, a reliable method of assessing glottic phonation in the porcine model is needed. Methods: In this study, we have created a novel pulley-based apparatus with harness for “pig-lifting” with surrounding acoustic insulation and high-directional microphone with digital recorder for recording phonation. Praat and Matlab were used to analyze all porcine vocalizations for fundamental frequency (F0), intensity, duration of phonation and cepstral peak prominence (CPP). Glottic phonation was detected using F0 (≥ 2000 hz), duration (≥.3 seconds) and researcher perceptual judgment. Partial-glottic phonations were also analyzed. Reliability between researcher judgment and acoustic measures for glottic phonation detection was high. Results: Acoustic analysis demonstrated that glottic and partial-glottic phonation was consistently elicited, with no formal training of the minipigs required. Glottic vocalizations increased with multiple lifts. Glottic phonation continued to be elicited after multiple days but became less frequent. Glottic and partial-glottic phonations had similar CPP values over the 6 experimental days. Conclusion: Our cost-effective, reliable method of inducing and recording glottic phonation in the porcine model may provide a cost effective, preclinical tool in voice research.Item Impact of Needle Selection on Survival of Muscle-Derived Cells When Used for Laryngeal Injections(Longdom Publishing, 2023) Awonusi, Oluwaseyi; Harbin, Zachary J.; Brookes, Sarah; Zhang, Lujuan; Kaefer, Samuel; Morrison, Rachel A.; Newman, Sharlé; Voytik-Harbin, Sherry; Halum, Stacey; Otolaryngology -- Head and Neck Surgery, School of MedicineObjective: To describe how differing injector needles and delivery vehicles impact Autologous Muscle-Derived Cell (AMDC) viability when used for laryngeal injection. Methods: In this study, adult porcine muscle tissue was harvested and used to create AMDC populations. While controlling cell concentration (1 × 107 cells/ml), AMDCs including Muscle Progenitor Cells (MPCs) or Motor Endplate Expressing Cells (MEEs) were suspended in either phosphate-buffered saline or polymerizable (in-situ scaffold forming) type I oligomeric collagen solution. Cell suspensions were then injected through 23- and 27-gauge needles of different lengths at the same rate (2 ml/min) using a syringe pump. Cell viability was measured immediately after injection and 24- and 48-hours post-injection, and then compared to baseline cell viability prior to injection. Results: The viability of cells post-injection was not impacted by needle length or needle gauge but was significantly impacted by the delivery vehicle. Overall, injection of cells using collagen as a delivery vehicle maintained the highest cell viability. Conclusion: Needle gauge, needle length, and delivery vehicle are important factors that can affect the viability of injected cell populations. These factors should be considered and adapted to improve injectable MDC therapy outcomes when used for laryngeal applications.Item Laryngeal Reconstruction Using Tissue-Engineered Implants in Pigs: A Pilot Study(Wiley, 2021-10) Brookes, Sarah; Zhang, Lujuan; Puls, Theodore J.; Kincaid, John; Voytik-Harbin, Sherry; Halum, Stacey; Otolaryngology -- Head and Neck Surgery, School of MedicineObjective/hypothesis: There are currently no treatments available that restore dynamic laryngeal function after hemilaryngectomy. We have shown that dynamic function can be restored post hemilaryngectomy in a rat model. Here, we report in a first of its kind, proof of concept study that this previously published technique is scalable to a porcine model. Study design: Animal study. Methods: Muscle and fat biopsies were taken from three Yucatan minipigs. Muscle progenitor cells (MPCs) and adipose stem cells (ASCs) were isolated and cultured for 3 weeks. The minipigs underwent a left laterovertical partial laryngectomy sparing the left arytenoid cartilage and transecting the recurrent laryngeal nerve. Each layer was replaced with a tissue-engineered implant: 1) an acellular mucosal layer composed of densified Type I oligomeric collagen, 2) a skeletal muscle layer composed of autologous MPCs and aligned oligomeric collagen differentiated and induced to express motor endplates (MEE), and 3) a cartilage layer composed of autologous ASCs and densified oligomeric collagen differentiated to cartilage. Healing was monitored at 2 and 4 weeks post-op, and at the 8 week study endpoint. Results: Animals demonstrated appropriate weight gain, no aspiration events, and audible phonation. Video laryngoscopy showed progressive healing with vascularization and re-epithelialization present at 4 weeks. On histology, there was no immune reaction to the implants and there was complete integration into host tissue with nerve and vascular ingrowth. Conclusions: This pilot study represents a first in which a transmural vertical partial laryngectomy was performed and successfully repaired with a customized, autologous stem cell-derived multi-layered tissue-engineered implant.Item Oligomeric collagen as an encapsulation material for islet/β-cell replacement: effect of islet source, dose, implant site, and administration format(American Physiological Society, 2020-08) Hernandez Stephens, Clarissa; Morrison, Rachel A.; McLaughlin, Madeline; Orr, Kara; Tersey, Sarah A.; Scott-Moncrieff, J. Catharine; Mirmira, Raghavendra G.; Considine, Robert V.; Voytik-Harbin, Sherry; Pediatrics, School of MedicineReplacement of islets/β-cells that provide long-lasting glucose-sensing and insulin-releasing functions has the potential to restore extended glycemic control in individuals with type 1 diabetes. Unfortunately, persistent challenges preclude such therapies from widespread clinical use, including cumbersome administration via portal vein infusion, significant loss of functional islet mass upon administration, limited functional longevity, and requirement for systemic immunosuppression. Previously, fibril-forming type I collagen (oligomer) was shown to support subcutaneous injection and in situ encapsulation of syngeneic islets within diabetic mice, with rapid (<24 h) reversal of hyperglycemia and maintenance of euglycemia for beyond 90 days. Here, we further evaluated this macroencapsulation strategy, defining effects of islet source (allogeneic and xenogeneic) and dose (500 and 800 islets), injection microenvironment (subcutaneous and intraperitoneal), and macrocapsule format (injectable and preformed implantable) on islet functional longevity and recipient immune response. We found that xenogeneic rat islets functioned similarly to or better than allogeneic mouse islets, with only modest improvements in longevity noted with dosage. Additionally, subcutaneous injection led to more consistent encapsulation outcomes along with improved islet health and longevity, compared with intraperitoneal administration, whereas no significant differences were observed between subcutaneous injectable and preformed implantable formats. Collectively, these results document the benefits of incorporating natural collagen for islet/β-cell replacement therapies.Item Optimizing transport methods to preserve function of self‐innervating muscle cells for laryngeal injection(Wiley, 2024-12-08) Kaefer, Samuel L.; Zhang, Lujuan; Brookes, Sarah; Morrison, Rachel A.; Voytik-Harbin, Sherry; Halum, Stacey; Otolaryngology -- Head and Neck Surgery, School of MedicineObjectives: Recently, our laboratory has discovered a self-innervating population of muscle cells, called motor endplate-expressing cells (MEEs). The cells innately release a wide variety of neurotrophic factors into the microenvironment promoting innervation when used as an injectable treatment. Unlike other stem cells, the therapeutic potential of MEEs is dependent on the cells' ability to maintain phenotypical cell surface proteins in particular motor endplates (MEPs). The goal of this study is to identify transport conditions that preserve MEE viability and self-innervating function. Methods: Muscle progenitor cells (MPCs) of adult Yucatan pigs were cultured and induced to generate MEEs. Effects of short-term cryopreservation methods were studied on MPC and MEE stages. A minimally supplemented medium was investigated for suspension-mediated transport, and MEEs were loaded at a constant concentration (1 × 107 cells/mL) into plastic syringes. Samples were subjected to varying temperatures (4, 22, and 37°C) and durations (6, 18, 24, and 48 h), which was followed by statistical analysis of viability. Transport conditions maintaining viability acceptable for cellular therapy were examined for apoptosis rates and expression of desired myogenic, neurotrophic, neuromuscular junction, and angiogenic genes. Results: Cryopreservation proved detrimental to our cell population. However, a minimally supplemented medium, theoretically safe for injection, was identified. Transport temperature and duration impacted cell viability, with warmer temperatures leading to faster death rates prior to the end of the study. Transport conditions did not appear to affect apoptotic rate. Any expression change of desirable genes fell within the acceptable range. Conclusions: Transport state, medium, duration, and temperature must be considered during the transport of injectable muscle cells as they can affect cell viability and expression of integral genes. These described factors are integral in the planning of general cell transport and may prove equally important when the cell population utilized for laryngeal injection is derived from a patient's own initial muscle biopsy.Item STIFFNESS OF 3D COLLAGEN MATRICES REGULATES CDC42 ACTIVITY OF ENDOTHELIAL COLONY FORMING CELLS DURING EARLY VACUOLE(Office of the Vice Chancellor for Research, 2012-04-13) Kim, Seung Joon; Voytik-Harbin, Sherry; Yoder, Mervin; Na, SungsooRecent preclinical reports have provided evidence that endothelial colony forming cells (ECFCs), a subset of endothelial progenitor cells, significantly improve vessel formation, largely due to their robust vasculogenic potential. While it has been known that the Rho family GTPase Cdc42 is involved in this ECFC-driven vessel formation process, the effect of extracellular matrix (ECM) stiffness on its activity during vessel formation is largely unknown. Using a fluorescence resonance energy transfer (FRET)-based Cdc42 biosen-sor, we examined the spatio-temporal activity of Cdc42 of ECFCs in three-dimensional (3D) collagen matrices with varying stiffness. The result re-vealed that ECFCs exhibited an increase in Cdc42 activity in a soft (150 Pa) matrix, while they were much less responsive in a stiff (1000 Pa) matrix. In both soft and stiff matrices, Cdc42 was highly activated near vacuoles; how-ever, its activity is higher in a soft matrix than that in a stiff matrix. The ob-served Cdc42 activity was closely associated with vacuole area. Soft matri-ces induced higher Cdc42 activity, faster vacuole formation, and larger vac-uole area than stiff matrices. Time courses of Cdc42 activity and vacuole formation data revealed that Cdc42 activity proceeds vacuole formation. Collectively, these results suggest that matrix stiffness is critical in regulat-ing Cdc42 activity in ECFCs and its activation is an important step in early vacuole formation.Item Use of autologous adipose-derived mesenchymal stem cells for creation of laryngeal cartilage(Wiley, 2018-04) Zhang, Hongji; Voytik-Harbin, Sherry; Brookes, Sarah; Zhang, Lujuan; Wallace, Joseph; Parker, Noah; Halum, Stacey; Biomedical Engineering, School of Engineering and TechnologyOBJECTIVES/HYPOTHESIS: Adipose-derived mesenchymal stem cells (ASCs) are an exciting potential cell source for tissue engineering because cells can be derived from the simple excision of autologous fat. This study introduces a novel approach for tissue-engineering cartilage from ASCs and a customized collagen oligomer solution, and demonstrates that the resultant cartilage can be used for laryngeal cartilage reconstruction in an animal model. STUDY DESIGN: Basic science experimental design. METHODS: ASCs were isolated from F344 rats, seeded in a customized collagen matrix, and cultured in chondrogenic differentiation medium for 1, 2, and 4 weeks until demonstrating cartilage-like characteristics in vitro. Large laryngeal cartilage defects were created in the F344 rat model, with the engineered cartilage used to replace the cartilage defects, and the rats followed for 1 to 3 months. Staining examined cellular morphology and cartilage-specific features. RESULTS: In vitro histological staining revealed rounded chondrocyte-appearing cells evenly residing throughout the customized collagen scaffold, with positive staining for cartilage-specific markers. The cartilage was used to successfully repair large cartilaginous defects in the rat model, with excellent functional results. CONCLUSIONS: This study is the first study to demonstrate, in an animal model, that ASCs cultured in a unique form of collagen oligomer can create functional cartilage-like grafts that can be successfully used for partial laryngeal cartilage replacement.