Manufacturing Silicone In-House For The Creation Of Customized Neurovascular Blood Vessel Mimics

Perisho, Jacob Wilbert

01 May 2024

The Tissue Engineering Lab at California Polytechnic State University San Luis Obispo focuses on creating tissue-engineered Blood Vessel Mimics (BVMs) designed for the preclinical testing of neurovascular devices. These BVMs are composed of silicone models, representing anatomically accurate neurovasculatures, that are sodded with vascular cell types and then cultivated in bioreactors (which maintain physiologic conditions). These silicone models are currently sourced externally from industry partners, so the primary goal of this thesis was to develop the means and methods for the Tissue Engineering Lab to manufacture silicone models in-house. The first aim of this thesis was to develop and explore injection molding as a possible technique for manufacturing silicone models; this included prototyping various designs of molds, developing a viable workflow for injection molding, then assessing the resulting silicone models through measurement characterization, cytotoxicity screening, and BVM set-ups. The first aim found that injection molding was a viable manufacturing technique for making silicone models. The second aim of this thesis explored an alternative manufacturing method, dip-casting, to produce silicone models. The development of dip-casting was similar to injection molding, where several prototyping stages resulted in a viable workflow for making silicone models; the resulting silicone models were then assessed via measurement characterization and a BVM set-up. The second aim found that, in addition to injection molding, dip-casting was a viable technique for making silicone models, although the overall morphology of the resulting models was less desirable than those made by injection molding. The third and final aim of this thesis compared both manufacturing techniques (i.e., injection molding and dip-casting); this aim established that injection molding was preferable for making simple (less intricate) silicone models, whereas dip-casting was preferable for producing complex (more intricate) silicone models. Although the dip-casting technique requires more development to capture complex shapes and produce models with desirable morphologies, the injection molding protocol was formalized into a prescribed workflow for the Tissue Engineering Lab to reference. Overall, this thesis developed and explored two different manufacturing techniques for making silicone models and found that both were capable of making silicone models that could be used to create tissue-engineered BVMs, with injection molded models being ready to implement as the dip-casting process continues to be refined.

Silicone Model

Injection Molding

Dip-Casting

Tissue-Engineering

Biomaterials

Biomedical Devices and Instrumentation

<b>DESIGNING TUNABLE VISCOELASTIC HYDROGELS FOR STUDYING PANCREATIC CANCER CELL FATE</b>

Han Nguyen (6631871)

25 April 2024

<p dir="ltr">Pancreatic ductal adenocarcinoma (PDAC) is the most common and lethal pancreatic cancer subtype. The silent tumor progression and aggressive development of chemo-resistance are the primary factors behind the dismal 13% 5-year survival rate. The tumor microenvironment (TME) has been the focus of many pancreatic cancer research since the TME actively interacts with cancer cells to promote tumor growth, drug resistance, and invasion. A thorough comprehension of PDAC cell and TME interaction is crucial to uncover the mechanism and key regulators behind PDAC’s rapid progression, high propensity for metastasis, and exceptional resistance to cancer therapeutics. Hydrogels have emerged as invaluable tools for investigating cell-matrix communication in three-dimensional (3D) environments, as their chemical and mechanical properties can be easily tuned to mimic the dynamic nature of native tissue. However, current biomimetic hydrogels used in PDAC models are elastic and often lack tissue-relevant viscoelastic properties, such as hysteresis and stress-relaxation. Stress-relaxation influences various cellular processes, including differentiation, proliferation, and cancer progression. This dissertation aims to address this gap by introducing viscoelasticity and fast stress relaxation into existing hydrogel platforms to more accurately replicate PDAC tissue mechanics. Specifically, we employ two chemistries: thiol-norbornene photopolymerization and boronic ester dynamic bonding to fabricate gelatin-based hydrogels. Gels formed solely via irreversible thiol-norbornene chemistry exhibit elasticity and slow stress-relaxation, while gels formed with both thiol-norbornene and reversible boronic ester bonds display viscoelastic properties and fast stress-relaxation. Cell-laden hydrogels with varying mechanical properties (low vs high stiffness, slow vs fast relaxation) were used as tools to explore the effects of matrix stiffening and viscoelasticity in promoting cancer aggressiveness. It was revealed that matrix stiffening, coupled with the inclusion of cancer-associated fibroblast induced the epithelial-mesenchymal transition phenotype (EMT) in pancreatic cancer cells. In addition, fast-relaxing hydrogels promoted cancer cell survival, growth, and EMT via engaging integrin β-1 (ITGB1). Blocking of ITGB1 receptors diminished cell growth, however, cells in fast-relaxing gels upregulated SNAIL1, a biomarker of poor cancer prognosis. Collectively, results from these studies describe our recent progress in understanding the mechanism by which stiff and viscoelastic substrates facilitate cancer development and how cellular functions can be controlled via modulating cell receptor-matrix binding.</p>

Biomaterials

Tissue engineering

pancreatic adenocarcinoma progression

Tissue Engineering Biomimetic

Cell Matrix Interactions

Design, development, and validation of a perfusion-compression bioreactor to study osteogenesis in bone explants

Graham, Alexis Victoria

08 December 2023

The current gold standard treatment for bone defects is autologous cancellous bone graft, which involves increased surgery time and donor site morbidity, and limited supply of bone and cells for regeneration. Bioreactors may aid in the generation of mechanically conditioned bone grafts with more cells compared to traditional grafts. However, the specific parameters of fluid flow and mechanical loading which contribute to osteogenesis and cell viability in bioreactors are not fully characterized. Here, a perfusion-compression bioreactor system was developed to study osteogenesis in porcine trabecular bone explants. Loading accuracy was over 88% across six bioreactors at a 0.1 s-1 strain rate and 20 N target force, akin to running. A flow rate of 0.2 mL/min appeared to be more favorable for cell viability than 1 mL/min. Overall, this work offers a foundation for future efforts to enhance cell viability and osteogenesis in bone explants.

bioreactor

tissue engineering

osseointegration

mechanobiology

mechanical loading

perfusion flow

Systems and Integrative Engineering

The development, validation, and characterization of an ex-vivo porcine full thickness skin model for the study of the subcutaneous compartment

Jordanna Michelle Payne (15348601)

27 April 2023

<p>This dissertation details the creation, validation, and characterization of a porcine ex-vivo culture model to study subcuteneous tissue. The viability of the model was assessed over seven days of culture by digestion and the proliferation and death of cells was monitored by immunohistochmeical labelling and image analysis. The model was then used in a timecourse proteomics experiment to characterize the effect of culture on subcutaneous proteome. The model was then compared to a commercially available human ex-vivo model with respect to viability and changes to the subcutaneous proteome. </p>

Biomedical imaging

Tissue engineering

subcutaneous tissue engineering

tissue engineering platforms

subcutaneous proteomics

ex vivo culture

ex vivo culture models

time course proteomics

Efeitos do LRP6 e Frizzled6 na diferenciação endotelial de DPSC /

Silva, Gleyce Oliveira

January 2015

Orientador: Carlos Henrique Ribeiro Camargo / Banca: Mabel Mariela Rodríguez Cordeiro / Banca: Bruno das Neves Cavalcanti / Banca: Renata de Azevedo Canevari / Banca: Márcia Carneiro Valera Garakis / Resumo: O objetivo deste estudo foi avaliar a função da via de sinalização Wnt/β- catenina através dos receptores LRP6 e Frizzled6 na diferenciação de células-tronco de polpa dental de dentes permanentes (DPSC) em células endoteliais. DPSC foram transduzidas com marcadores eGFP e vetores lentivirais shRNA (LRP6, Frizzled6 ou vetor vazio - controle) para os experimentos. Os testes in vitro avaliaram a expressão de GSK3-β e β- catenina por western blot na presença de rhWnt1 e rhVEGF165 e de VEGF e CXCL-8 (IL-8) por ELISA. A expressão de marcadores endoteliais (western blot e PCR) e formação de túbulos capilares foram analisados após a diferenciação endotelial das DPSCs. In vivo, fatias dentárias/matrizes condutivas semeadas com DPSCs-shRNA foram implantadas em subcutâneo de dorso de camundongos imunodeprimidos por 28 dias e o número de vasos sanguíneos foi determinado por imunohistoquímica para eGFP e coloração por HE. β-catenina ativa foi mais expressa em shRNA-LRP6 e shRNA-Frizzled6 que nas células controle, e sua expressão aumentou com a suplementação com rhVEGF165 e rhWnt1. A expressão de GSK3-β fosforilado foi menor, porém também aumenta ou permanece estável com rhVEGF165 ou rhWnt1. Quanto à expressão de VEGF, em shRNA-Frizzled6 foi maior que nas células controle e em shRNA-LRP6 (p<0,05), enquanto que a expressão de IL8 foi menor em shRNA-LRP6, diferindo estatisticamente das outras células. A expressão dos marcadores endoteliais CD31 e VEGFR2 diminuiu nas células shRNA-LRP6, enquanto que em shRNAFrizzled6 a expressão de VEGFR2 foi aumentada. A formação de túbulos capilares de shRNA-Frizzled6 e shRNA-LRP6 foi menor quando comparado ao controle, porém shRNA-Frizzled6 obteve uma tendência de aumento na proliferação de capilares em 144h. In vivo, DPSC-shRNALRP6 apresentou menor número de capilares formados quando comparados com as outras duas... / Abstract: The aim of this study was to evaluate the function of Wnt/β-catenin signaling through LRP-6 and Frizzled-6 receptors in the differentiation of dental pulp stem cells from permanent teeth (DPSC) into endothelial cells. DPSC were transduced with EGFP-tagged lentiviral shRNA vectors (LRP6, Frizzled6 or empty vector - control) for experiments. In vitro assay evaluated GSK3-β and β-catenin expression by western blot in rhWnt1 and rhVEGF165 presence, and VEGF and CXCL-8 (IL-8) expression by ELISA. Endothelial markers expression (western blot and PCR) and tube formation were analyzed after endothelial differentiation of DPSCs. In vivo, tooth slices/scaffolds seeded with transduced DPSCs were implanted subcutaneously in back of immunodefficient mice and blood vessels were counted per immunohistochemistry for eGFP and HE staining. Active β- catenin was more expressed in shRNA-LRP6 and shRNA-Frizzled6 than in control cells, and increased with rhVEGF165 and rhWnt1 supplementation. Phosphorylated GSK3-β expression was lower, however also increased or maintained with rhVEGF165 or rhWnt1. VEGF expression was higher in shRNA-Frizzled6 than in control and shRNA-LRP6 (p<0,05), IL8 expression was lower in shRNA-LRP6, with statistically difference of the others cells. Endothelial markers CD31 and VEGFR2 expression decreased in shRNA-LRP6, but VEGFR2 expression increased in shRNAFrizzled6. shRNA-Frizzled6 and shRNA-LRP6 tube formation was lower when compared to control, however shRNA-Frizzled6 had tendency to increase proliferation in 144h. In vivo, shRNA-LRP6 showed fewer blood vessels formed than other cells (p<0,05). Collectively, the results of this study suggest that Wnt/β-catenin signaling regulates endothelial differentiation of DPSC through LRP6 / Doutor

Engenharia tecidual.

Vasos sanguineos.

Células-tronco.

Tissue engineering

Characterization of silk proteins from African wild silkworm cocoons and application of fibroin matrices as biomaterials

Mhuka, Vimbai

11 1900

Challenges in treating injuries, together with an increased need for repair of damaged tissues and organs, have made regenerative medicine a major research area today. Biomaterials such as silk fibroin (SF) have proven to be excellent tissue scaffolds possessing properties essential in tissue engineering such as biocompatibility, biodegradability and exceptional mechanical properties. SF nanofibres are especially attractive due to their large surface-to-volume ratio and high porosity which is beneficial in regenerative medicine. However, to design biomaterial scaffolds, chemical and physical properties of SF have to be sufficiently known. The thesis aims to contribute to knowledge by characterizing silk fibroin from the African wild silkworm species Gonometa rufobrunnae, Gonometa postica, Argema mimosae, Epiphora bahuniae and Anaphe panda. Moreover, the feasibility of producing nanofibrous biomaterial scaffolds from these fibroins is explored. The chemical composition of degummed fibres was investigated using Capillary electrophoresis whilst Infrared (IR) and Raman spectroscopic techniques were utilized to determine structural characteristics of the fibroin. In addition, thermal behaviour and mechanical properties of the fibroins were also investigated. Nanofibres were fabricated via electrospinning. The effects of solution concentration, voltage, polymer flow rate and tip to collector distance were studied to give optimum electrospinning conditions. IR spectroscopy was also utilized to observe the conformational structure of the degummed and electrospun fibres whilst scanning electron microscopy (SEM) provided information on the size and morphology of the fibres. The use of the nanofibres as biomaterials was evaluated using cytotoxicity tests. Results showed that glycine, alanine and serine constituted over 70% of the amino acid composition of all the fibroins. Gonometa fibroin had more glycine than alanine whilst the opposite was true for Argema mimosae, Epiphora bahuniae and Anaphe panda fibroin. The abundance of basic amino acids in Gonometa rufobrunnae, Gonometa postica, Argema mimosae and Epiphora bahuniae fibroin makes them prime candidates for cell and tissue culture. The amino acid composition of the fibroins influenced secondary structure as the β-sheet structure. Anaphe panda, Argema mimosae and Epiphora bahuniae silks was made up of mostly alanine-alanine (Ala-Ala)n polypeptides whilst Gonometa fibroin had an interesting mixture of both glycine-alanine (Gly-Ala)n and (Ala-Ala)n units. The unique structures impacted the mechanical and thermal properties of the fibroins. Production of Gonometa nanofibres was mainly dependent on fibroin solution concentration. A minimum of 27 % w/v was needed to produce defect free nanofibres. Diameters of the electrospun fibres produced ranged from 300 to 2500 nm. IR spectroscopy data highlighted that the β-sheet conformation of degummed fibroin was degraded during the formation of the nanofibres rendering them water soluble. It was however possible to regenerate the β-sheet structure in the nanofibres by exposing them to various solvents. Cytotoxicity tests using Sulforhodamine B (SRB) assay demonstrated that the nanofibres were not toxic to cells, a major prerequisite for use as a biomaterial. This thesis successfully provides useful data in an area that has been minimally explored. Results suggest that SF from African silkworm species offers diversity in properties and are therefore attractive for use as biomaterials, especially in cell and tissue engineering. As far as we could determine, we are the first to extend the use of fibroin from African silk species by producing Gonometa SF nanofibres that are of potential use as biomaterial scaffolds. / Chemistry / D. Phil. (Chemisty)

610.28

Silk

Tissue engineering

Regenerative medicine

Biomedical materials

Nanochemistry

Reconstituted collagen fibres for tissue engineering applications

Zeugolis, D. I.

January 2006

No description available.

600

Collagen-based scaffolds for heart valve tissue engineering

Chen, Qi

January 2013

Tissue engineered heart valve (TEHV) is believed to be a promising candidate for curative heart valve replacements. Collagen, elastin and chondroitin-4-sulfate (C4S) comprise the extra-cellular matrix (ECM) of native heart valves and therefore are suitable materials for TEHV scaffolds. Freeze-drying technique was able to produce scaffolds with relative densities of 0.3%-2.0% and pore sizes of 33.2µm-201.5µm, without having any major effects on the ultra-structures on the scaffold materials. Subsequent dehydrothermal (DHT) treatment and ultra-violet (UV) irradiation introduced inter- or intra-molecular crosslinks in the scaffolds in forms of ester and amide bonds, as well as the accompanying denaturation of the proteins (i.e. ultra-structure transition from helices to random coils). The collagen-based scaffolds had tensile, compressive and effective bending moduli ranging from 39.8kPa to 1082kPa, from 2.4kPa to 213.9kPa, and from 11.0kPa to 415.8kPa, respectively. The different behaviours of the wall stretching and the wall buckling in the individual pores of the scaffolds contributed to the different tensile, compressive and bending moduli. The mechanical properties could be tailored through controlling the freezing temperature, the relative density and the composition of the scaffolds. A lower freezing temperature might lead to lower mechanical properties because different pore structures were introduced. When the the relative density of the scaffold increased, the values of the moduli increased exponentially, with an exponential dependence factor larger for the compressive modulus than for the tensile modulus. Adding elastin or C4S into the collagen scaffolds lowered the mechanical properties due to the decrease in the collagen content. Layered structures that combined collagen-rich layers with elastin-rich and/or C4S -rich layers allowed the scaffolds to make use of the different mechanical properties of different layers, and hence to show anisotropic bending behaviour depending on the loading directions. The lower effective bending modulus (9.6 to 25.0kPa) in the with curvature (WC) direction than that (18.1kPa to 39.3kPa) in the against curvature (AC) direction mimicked the characteristic behaviour of the native heart valves and would be beneficial for a mechanically desirable TEHV. The DHT treatment and UV irradiation were able to increase the mechanical properties of the scaffolds to up to 2.5 times of the original values, by reinforcing the scaffold materials with more crosslinks. In the hydrated status, the hydrophilic C4S improved the water uptake ability of the scaffold and the hydrophobic elastin reduced it. The hydrated layered scaffolds still exhibited bending anisotropy despite much lower effective bending modulus. Finite element models of the scaffolds produced results that were in agreement with the experiments, and enabled us to perform distributed loading and internal stress analysis on the scaffolds. The collagen-based scaffolds were seeded with cardiosphere-derived cells (CDCs), and they attached to the scaffolds and showed visible cell division, proliferation and migration. The CDCs exhibited preferred proliferation behaviours on the collagen-C4S scaffolds to that on the collagen-elastin scaffolds because of the cell affinity to the C4S, as well as the elastin-induced contractile cell phenotype and scaffold volume shrinkage. This difference seemed to be less evident in the layered scaffolds due to the cell communication between the layers. The crosslinking process also had effects on the cell proliferation in the ways that it induced ultra-structure changes or volume shrinkage in the scaffolds. The layered scaffold-cell constructs designed and produced in this study served as a forwarding step towards a mechanically desirable and biologically active TEHV.

610.28

Bio-inspired polymer nanocomposites for tissue engineering applications

Pooyan, Parisa

08 June 2015

Increasing emphasis has been placed on the use of renewable resources, on decreased reliance on petroleum in order to better utilize global energy needs. Biological structures available in nature have been a constant inspiration to the design and fabrication of the new line of functional biomaterials whose unique phenomena can be exploited in novel applications. In tissue engineering for example, a natural biomimetic material with close resemblance to the profile features existed in a native extracellular matrix could provide a temporary functional platform to regulate and control cellular interactions at a molecular level and to subsequently direct a tissue regeneration. However, the lack of rigidity of natural materials typically limits their mass production. One promising approach to address this shortcoming is to introduce a biomimetic composite material reinforced by high purity nanofibers found in nature. As an attractive reinforcing filler phase, cellulose nanowhiskers (CNWs) offer exceptional properties such as high aspect ratio, large interface area, and significant mechanical performance. As such, CNWs could integrate a viable nanofibrous porous candidate, resulting in superior structural diversity and functional versatility. Inspired by the fascinating properties of cellulose and its derivatives, we have designed two bio-inspired nanocomposite materials reinforced with CNWs in this work. The successful grafting of CNWs within the host matrix and their tendency to interconnect with one another through strong hydrogen bonding gave rise to the formation of a three-dimensional rigid percolating network, fact which imparted considerable mechanical strength and thermal stability to the entire structure with only a small amount of filler content, i.e. 3 wt.%. Also, the biocompatibility of the nanocomposite was probed by in-vitro incubation of human-bone-marrow-derived mesenchymal stem cells (MSCs), which resulted in the invasion and proliferation of MSCs around the nanocomposite at day 8 of culture. The green functional biomaterial with its unique features in this work could open new perspectives in the self-assembly of nanobiomaterial for tissue-engineered scaffolding, while it could make the design of the next generation of fully green functional biomaterial a reality.

Scaffolds

Polymer nanocomposites

Cellulose nanowhiskers

Material's characterization

Tissue engineering

Development of Multiscale Electrospun Scaffolds for Promoting Neural Differentiation of Induced Pluripotent Stem Cells

Khadem Mohtaram, Nima

12 December 2014

Electrospun biomaterial scaffolds can be engineered to support the neural differentiation of induced pluripotent stem cells. As electrospinning produces scaffolds consisting of nano or microfibers, these topographical features can be used as cues to direct stem cell differentiation. These nano and microscale scaffolds can also be used to deliver chemical cues, such as small molecules and growth factors, to direct the differentiation of induced pluripotent stem cells into neural phenotypes. Induced pluripotent stem cells can become any cell type found in the body, making them a powerful tool for engineering tissues. Therefore, a combination of an engineered biomaterial scaffold with induced pluripotent stem cells is a promising approach for neural tissue engineering applications. As detailed in this thesis, electrospun scaffolds support the neuronal differentiation of induced pluripotent stem cells through delivering the appropriate chemical cues and also presenting physical cues, specifically topography to enhance neuronal regeneration. This thesis seeks to evaluate the following topics: multifunctional electrospun scaffolds for promoting neuronal differentiation of induced pluripotent stem cells, neuronal differentiation of human induced pluripotent stem cells seeded on electrospun scaffolds with varied topographies, and controlled release of glial cell-derived neurotrophic factor from random and aligned electrospun nanofibers. / Graduate / nkhadem@uvic.ca

Neural Tissue Engineering

Induced Pluripotent Stem Cells

Spinal Cord Injuries