Biosynthetic PCL-graft-collagen bulk material for tissue engineering applications

Gentile, P., McColgan-Bannon, K., Gianone, N.C., Sefat, Farshid, Dalgarno, K., Ferreira, A.M.

23 June 2017

Yes / Biosynthetic materials have emerged as one of the most exciting and productive fields in polymer chemistry due to their widespread adoption and potential applications in tissue engineering (TE) research. In this work, we report the synthesis of a poly(ε-caprolactone)-graft-collagen (PCL-g-Coll) copolymer. We combine its good mechanical and biodegradable PCL properties with the great biological properties of type I collagen as a functional material for TE. PCL, previously dissolved in dimethylformamide/dichloromethane mixture, and reacted with collagen using carbodiimide coupling chemistry. The synthesised material was characterised physically, chemically and biologically, using pure PCL and PCL/Coll blend samples as control. Infrared spectroscopy evidenced the presence of amide I and II peaks for the conjugated material. Similarly, XPS evidenced the presence of C–N and N–C=O bonds (8.96 ± 2.02% and 8.52 ± 0.63%; respectively) for PCL-g-Coll. Static contact angles showed a slight decrease in the conjugated sample. However, good biocompatibility and metabolic activity was obtained on PCL-g-Coll films compared to PCL and blend controls. After 3 days of culture, fibroblasts exhibited a spindle-like morphology, spreading homogeneously along the PCL-g-Coll film surface. We have engineered a functional biosynthetic polymer that can be processed by electrospinning. / The EPSRC Centre in Innovative Manufacturing in Medical Devices (MeDe Innovation; EP/K029592/1).

Biosynthetic

Collagen

Poly("-caprolactone)

Conjugation

Electrospinning

Tissue engineering

Engineered models of the lymphatic stroma to study cell and fluid transport

Hammel, Jennifer H.

18 November 2024

The lymphatic system plays essential roles in regulating fluid balance and immunosurveillance. Across the body, local lymphatic vessels collect waste in the form of lymph and deliver it to nearby lymph nodes (LNs) to be filtered and screened for pathogens. With broad implications in adaptive immunity, cancer metastasis, and cancer treatment, developing novel in vitro models will provide new platforms to explore lymphatic function in health and disease. This dissertation sought to develop tissue-specific engineered models of the LN stroma and the meningeal lymphatics to examine the transport of cells and fluid. Within the LN, fibroblastic reticular cells (FRCs) maintain a network of extracellular matrix conduits that guide varying rates of interstitial fluid flow (IFF) based on inflammatory state. Eventually, that flow exits the LN through the afferent lymphatics, consisting of lymphatic endothelial cells (LECs). We first developed a spatially organized model of the LN stroma consisting of a monolayer of LECs on the underside of a tissue culture insert and an FRC-laden hydrogel within. We demonstrate that high magnitude IFF (3.0 µm/s) had positive impacts on FRCs but disrupted the integrity of the LEC barrier, and these effects were accompanied by increased secretion of a variety of inflammatory chemokines. We also show that IFF of any magnitude decreased T cell egress from the model. Next, we sought to apply the LN stroma model toward understanding metastasis. LN metastasis is the most important prognostic factor in breast cancer, with size of metastasis informing treatment plan. Metastasis greatly alters the structure of the LN, which in turn alters transport. However, the impact of altered transport on cancer progression is not well understood. We added different numbers of breast cancer cells to our LN stroma model to examine tumor burden. We found that tumor cells invaded the LEC barrier at similar numbers regardless of initial burden. Additionally, at the highest tumor burden, diffusivity in the stroma was significantly decreased. Most excitingly, flow velocity was positively correlated with FRC spread in the hydrogel, demonstrating the contributions of FRCs to transport. Finally, we looked to the central nervous system (CNS). The meningeal lymphatics are responsible for draining cerebrospinal fluid to the cervical lymph nodes for CNS immunosurveillance. We developed a simple model of a meningeal lymphatic vessel lumen consisting of a monolayer of LECs on the underside of a tissue culture insert and a monolayer of meningeal fibroblasts within. This is, to our knowledge, the very first in vitro model of the meningeal lymphatics. We demonstrate that our model has barrier function and is capable of immune cell transmigration and egress. We examined how systemic chemotherapy for breast cancer could cause off-target disruption of the meningeal lymphatics and found that docetaxel was significantly deleterious. We further began to explore leukemia cell behavior in our LN stroma and meningeal lymphatics model. Throughout this dissertation, we emphasize the importance of incorporating fluid and cell transport into engineered models of immunity. These models represent a step toward building up the complexity of in vitro lymphatic models to improve pre-clinical screening and understand pathophysiology. / Doctor of Philosophy / The lymphatic system plays essential roles in regulating fluid balance and immune system surveillance. Across the body, local lymphatic vessels collect waste in the form of lymph and deliver it to nearby lymph nodes (LNs) to be filtered and screened for pathogens like viruses or bacteria. With broad implications in immunity, cancer metastasis, and cancer treatment, developing novel models in the lab using human cells and 3-dimensional biomaterials will provide new platforms to explore lymphatic function in health and disease. This dissertation sought to develop engineered models that were specific to the lymph node stroma and the meningeal lymphatics to examine the transport of cells and fluid. Within the LN, fibroblastic reticular cells (FRCs) maintain a network of channels that guide varying rates of interstitial fluid flow (IFF) based on how inflamed the LN is. Eventually, that flow exits the LN through the afferent lymphatics, consisting of lymphatic endothelial cells (LECs). We first developed a spatially organized model of the LN stroma consisting of LECs on the underside of a porous membrane and an FRC-laden hydrogel above the membrane and demonstrated that high magnitude IFF altered morphology, immune cell behavior, and inflammatory protein secretion in the model. Next, we sought to apply the LN stroma model toward understanding cancer metastasis. LN metastasis is the most important prognostic factor in breast cancer, with size of metastasis informing treatment plan. Metastasis greatly alters the structure of the LN, which in turn alters the transport of lymph and immune cells. However, the impact of altered transport on cancer progression is not well understood. We added different numbers of breast cancer cells to our LN stroma model to examine tumor burden and found that tumor cells invaded the LECs at similar rates regardless of initial density, but that diffusion, a transport parameter, was significantly changed by high tumor cell density. Finally, we looked to the central nervous system (CNS). The meningeal lymphatics are responsible for draining cerebrospinal fluid to the cervical lymph nodes to screen for pathogens in the CNS. We developed a simple model of a meningeal lymphatic vessel lumen consisting of LECs and meningeal fibroblasts on either side of a porous membrane. This is, to our knowledge, the very first in vitro model of the meningeal lymphatics. We examined how systemic chemotherapy for breast cancer could cause off-target disruption of the meningeal lymphatics and found that docetaxel was significantly damaging to the model. Throughout this dissertation, we emphasize the importance of incorporating fluid and cell transport into engineered models of lymphatics. These models represent a step toward building up complexity to improve the toolset for pre-clinical screening and studying disease progression.

lymphatics

lymph node

interstitial fluid flow

tissue engineering

transport

Experimental nanomechanics of natural or artificial spider silks and related systems

Greco, Gabriele

22 April 2020

Spider silks are biological materials that have inspired the humankind since its beginning. From raising the interest of ancient philosophers to the practical outcomes in the societies, spider silks have always been part of our culture and, thus, of our scientific development. They are protein-based materials with exceptional mechanical and biological properties that from liquid solutions passes to the solid fibres once extruded from the body of the spiders. Spider silks have deeply been investigated in these decades for their possible outcomes in biomedical technology as a supporting material for drugs delivery or tissues regeneration. Furthermore, spiders build webs with the support of different types of silks to create mechanically efficient structures, which are currently under investigation as models for metamaterials and fabrics with superior mechanical properties. This diversity in materials and structures makes spider silks scientific outcomes potentially infinite. In this work, we present some of the outputs of these three years of PhD. We explored the properties of the native material across different aspects (different species and glands) and trying to find possible derived applications (tissue engineering). Then we explored the mechanical behaviour of the natural structures (such as orb webs or attachment discs) coupled with their biological functions. In order to develop to an industrial level this material, we tried to understand and improve the physical properties of artificial spider silk, which helps also in understanding the ones of the native materials.

The simulated effect of the lightning first short stroke current on a multi-layered cylindrical model of the human leg

Lee, Yuan-chun Harry

January 2015

A dissertation submitted to the Faculty of Engineering and the Built Environment, University of the Witwatersrand, Johannesburg, in ful lment of the requirements for the degree of Master of Science in Engineering. Johannesburg, 2015 / This research investigates the e ects of the frequency components of the lightning First Short Stroke (FSS) on the current pathway through human tissues using frequency domain analysis. A Double Exponential Function (DEF) is developed to model the FSS with frequency components in the range 10 Hz 100 kHz. Human tissues are simulated using Finite Element Analysis (FEA) in COMSOL and comprises of two types of models: Single Layer Cylindrical Model (SLCM) and Multi-layered Cylindrical Model (MLCM). The SLCM models 54 human tissues independently and the MLCM models the human leg with ve tissue layers: bone marrow, cortical bone, muscle, blood and fat. Three aspects are analysed: current density, complex impedance and power dissipation. From the SLCM results, aqueous tissues have the lowest impedances and tissue heat dissipation is proportional to tissue impedance. Results from the MLCM show that 85% of the FSS current ows through muscle, 11% ows through blood, 3:5% through fat and the rest through cortical bone and bone marrow. From the results, frequency dependent equivalent circuit models consisting of resistors and capacitors connected in series are proposed. The simulation results are correlated with three main clinical symptoms of lightning injuries: neurological, cardiovascular and external burns. The results of this work are applicable to the analysis of High Voltage (HV) injuries at power frequencies. / MT2017

Tissue engineering

Tissue engineering--Simulation methods

Human engineering--Computer simulation

Electrical injuries

Computational biology

Matrix Metalloproteinase 9 (MMP-9) and Biodegradable Polymers in the Engineering of a Vascular Construct

Sung, Hak-Joon

19 April 2004

The role of matrix metalloproteinase (MMP)-9 and processing conditions of biodegradable polymer scaffolds has been investigated to optimize engineering vascular constructs. For a small diameter vascular construct, uniform 10 mm thickness of highly porous scaffolds were developed using a computer-controlled knife coater and exploiting phase transition properties of salts. The comparative study of fast vs. slow degrading three-dimensional scaffolds using a fast degrading poly D, L-lactic-glycolic acid co-polymer (PLGA) and a slow degrading poly e-caprolactone (PCL) indicated that fast degradation negatively affects cell viability and migration into the scaffold in vitro and in vivo, which is likely due to the fast polymer degradation mediated acidification of the local environment. MMP-9 was crucial for collagen remodeling process by smooth muscle cells (SMC). MMP-9 deficiency dramatically decreased inflammatory cell invasion as well as capillary formation within the scaffolds implanted in vivo. This study reports that the angiogenic response developed within the scaffolds in vivo was related to the presence of inflammatory response. Combinatorial polymer libraries fabricated from blended PLGA and PCL and processed at gradient annealing temperatures were utilized to investigate polymeric interactions with SMC. Surface roughness was also found to correlate with SMC adhesion. SMC aggregation, proliferation, and protein production, were highest in regions that exhibited increased surface roughness, reduced hardness, and decreased crystallinity of the PCL-rich phases. This study revealed a previously unknown processing temperature and blending compositions for two well-known polymers, which optimized SMC interactions.

Combinatorial biosurface chip

Biomaterials

Tissue engineering

Vascular construct

Biodegradable polymers

MMP-9

Angiogenesis

Vascular grafts Materials

Metalloproteinases

Neovascularization

Tissue engineering

Development and Application of a 3-D Perfusion Bioreactor Cell Culture System for Bone Tissue Engineering

Porter, Blaise Damian

23 November 2005

Tissue engineering strategies that combine porous biomaterial scaffolds with cells capable of osteogenesis or bioactive proteins have shown promise as effective bone graft substitutes. Attempts to culture bone tissue-engineering constructs thicker than 1mm in vitro often result in a shell of viable cells and mineralized matrix surrounding a necrotic core. To address this limitation, we developed a perfusion bioreactor system that improves mass transport throughout large cell-seeded constructs. Additionally, we established and validated 3-D computational methods to model flow and shear stresses within the microporosity of perfused constructs. Micro-CT scanning and analysis techniques were used to non-destructively monitor mineral development over time in culture. CFD modeling of axial perfusion through cylindrical scaffolds with a regular microarchitecture revealed a uniform flow field distributed throughout the scaffold. Perfusion resulted in a 140-fold increase in mineral deposition at the interior of 3 mm thick polymer scaffolds seeded with rat bone marrow stromal cells. The total detected mineral volume tripled as the construct length was increased from 3 to 9 mm. Increasing scaffold length to 9 mm did not affect the mineral volume fraction (MVF) within the full volume of each construct. Mineral volume, spatial distribution, density, particle size and particle number were then quantified on cell-seeded constructs in 5 different culture environments. The effect of time varying flow conditions was compared with continuous perfusion as well as two different control cell culture methods in an attempt to enhance mineralized matrix within the constructs. Intermittent elevated perfusion and dynamic culture in an orbital rocker plate produced the greatest amount of mineral within 9 mm long constructs compared to low continuous flow and high continuous flow cases. Together, these studies indicate that dynamic culture conditions enhance construct development with regards to cell viability, mineralized matrix deposition, growth rate, and distribution. Furthermore, these techniques provide a rational approach to selecting perfusion culture conditions that optimize the amount and distribution of mineralized matrix production. Finally, the established perfusion bioreactor, in combination with micro-CT analysis, provides a foundation for evaluating new scaffolds and cell types that may be useful for the development of effective bone graft substitutes.

Micro-CT analysis

Perfusion bioreactor

3D cell culture

Bone tissue engineering

Bone substitutes

Tissue engineering

Perfusion (Physiology)

Bioreactors

Mechanotransduction in Engineered Cartilaginous Tissues: In Vitro Oscillatory Tensile Loading

Vanderploeg, Eric James

19 May 2006

Disease and degeneration of articular cartilage and fibrocartilage tissues severely compromise the quality of life for millions of people. Although current surgical repair techniques can address symptoms in the short term, they do not adequately treat degenerative joint diseases such as osteoarthritis. Thus, novel tissue engineering strategies may be necessary to combat disease progression and repair or replace damaged tissue. Both articular cartilage and the meniscal fibrocartilage in the knee joint are subjected to a complex mechanical environment consisting of compressive, shear, and tensile forces. Therefore, engineered replacement tissues must be both mechanically and biologically competent to function after implantation. The goal of this work was to investigate the effects of oscillatory tensile loading on three dimensional engineered cartilaginous tissues in an effort to elucidate important aspects of chondrocyte and fibrochondrocyte mechanobiology. To investigate the metabolic responses of articular chondrocytes and meniscal fibrochondrocytes to oscillatory tensile loading, various protocols were used to identify stimulatory parameters. Several days of continuously applied tensile loading inhibited extracellular matrix metabolism, whereas short durations and intermittently applied loading could stimulate matrix production. Subpopulations of chondrocytes, separated based on their zonal origin within the tissue, differentially responded to tensile loading. Proteoglycan synthesis was enhanced in superficial zone cells, but the molecular structure of these molecules was not affected. In contrast, neither total proteoglycan nor protein synthesis levels of middle and deep zone chondrocytes were substantially affected by tensile loading; however, the sizes of these new matrix molecules were altered. Up to 14 days of intermittently applied oscillatory tensile loading induced modest increases in construct mechanical properties, but longer durations adversely affected these mechanical properties and increased degradative enzyme activity. These results provide insights into cartilage and fibrocartilage mechanobiology by elucidating cellular responses to tensile mechanical stimulation, which previously had not been widely explored for these tissues. Understanding the role that mechanical stimuli such as tension can play in the generation of engineered cartilaginous tissues will further the goal of developing successful treatment strategies for degenerative joint diseases.

Tensile loading

Mechanical stimulation

Meniscus

Tissue engineering

Fibrocartilage

Cartilage

Tissue engineering

Biomechanics

Loads (Mechanics)

The role of extracellular matrix proteins in traumatic brain injury and cell transplantation

Tate, Ciara Caltagirone

03 July 2006

With over 50,000 deaths and 80,000 disorders annually in the United States resulting from traumatic brain injury (TBI), there is a demand for improved therapeutic strategies. Cell transplantation offers the potential to treat TBI by targeting multiple mechanisms in a sustained fashion. However, efforts are needed to improve survival and integration of transplanted cells, and ultimately enhance functional recovery. Using tissue engineering strategies, we aimed to mimic key aspects of fetal tissue grafts by combining neural stem cells with a fibronectin or laminin based scaffold that could be delivered to the injured brain in a minimally invasive fashion. We found that the incorporation of extracellular matrix proteins into a cell transplantation paradigm led to improved donor cell survival and restored cognitive ability for treated animals. To begin to examine how fibronectin and laminin mediate these improvements, we first examined the endogenous role of these two proteins in the injured brain. Using a clinically-relevant model of TBI, we found both proteins are increased in the injured brain at acute time points. The spatial localization of fibronectin and laminin with specific support cells in the brain suggests a role for these proteins in repair, warranting further investigation. Using conditional plasma fibronectin knockout animals, we found that fibronectin is neuroprotective to the traumatically injured brain. Specifically, injured fibronectin knockout animals had more severe motor and cognitive deficits, increased cell death, and decreased retention of phagocytic cells compared to injured wild type animals. Thus, we have identified novel therapeutic treatments for TBI which utilize tissue engineered transplants and/or exploit endogenous repair mechanisms for fibronectin.

Tissue engineering

Traumatic brain injury

Fibronectin

Laminin

Neural stem cells

Cell transplantation

Tissue engineering

Brain Wounds and injuries Treatment

Fibronectins

Delivery of BMP-2 for bone tissue engineering applications

Johnson, Mela Ronelle

04 January 2010

Bone defects and fracture non-unions remain a substantial challenge for clinicians due to a high occurrence of delayed union or non-union requiring surgical intervention. The current grafting procedures used to treat these injuries have many limitations and further long-term complications associated with them. This has resulted in research efforts to identify graft substitution therapies that are able to repair and replace tissue function. Many of these tissue engineered products include the use of growth factors to induce cell differentiation, migration, proliferation, and/or matrix production. However, current growth factor delivery methods are limited by poor retention of growth factors upon implantation resulting in low bioactivity. These limiting factors lead to the use of high doses and frequent injections, putting the patients at risk for adverse effects. The goal of this work was to develop and evaluate the efficacy of BMP-2 delivery systems to improve bone regeneration. We examined two approaches for delivery of BMP-2 in this work. First, we evaluated the use of a self-assembling lipid microtube system for the sustained delivery of BMP-2. We determined that sustained delivery of BMP-2 from the lipid microtube system was able to enhance osteogenic differentiation compared to empty microtubes, however did not demonstrate a significant advantage compared to a bolus BMP-2 dose in vitro. Second, we developed and assessed the functionality of an affinity-based system to sequester BMP-2 at the implant site and retain bioactivity by incorporating heparin within a collagen matrix. Incorporation of heparin in the collagen matrix improved BMP-2 retention and bioactivity, thus enhancing cell-mediated mineralized matrix deposition in vitro. Lastly, the affinity-based BMP-2 delivery system was evaluated in a challenging in vivo bone repair model. Delivery of pre-bound BMP-2 and heparin in a collagen matrix resulted in new bone formation with mechanical properties not significantly different to those of intact bone. Whereas delivery of BMP-2 in collagen or collagen/heparin matrices had similar volumes of regenerated mineralized tissue but resulted in mechanical properties significantly less than intact bone properties. The work presented in this thesis aimed to address parameters currently preventing optimal performance of protein therapies including stability, duration of exposure, and localization at the treatment site. We were able to demonstrate that sustained delivery of BMP-2 from lipid microtubes was able to induce osteogenic differentiation, although this sustained delivery approach was not significantly advantageous over a bolus dose. Additionally, we demonstrated that the affinity-based system was able to improve BMP-2 retention within the scaffold and in vitro activity. However, in vivo implantation of this system demonstrated that only delivery of pre-complexed BMP-2 and heparin resulted in regeneration of bone with mechanical properties not significantly different from intact bone. These results indicate that delivery of BMP-2 and heparin may be an advantageous strategy for clinically challenging bone defects.

Fracture repair

Growth factor delivery

Heparin

Bone tissue engineering

BMP-2

Fractures

Fractures Treatment

Bone-grafting

Tissue engineering

Regenerative medicine

Cryopreservation effects on a pancreatic substitute comprised of beta cells or recombinant myoblasts encapsulated in non-adhesive and adhesive alginate hydrogels

Ahmad, Hajira Fatima

05 September 2012

For clinical translation of a pancreatic substitute, long-term storage is essential, and cryopreservation is a promising means to achieve this goal. The two main cryopreservation methods are conventional freezing and vitrification, or ice-free cryopreservation. However, as both methods have their potential drawbacks for cryopreservation of a pancreatic substitute, they must be systematically evaluated in order to determine the appropriate method of cryopreservation. Furthermore, previous studies have indicated benefits to encapsulation in 3-D adhesive environments for pancreatic substitutes and that adhesion affects cell response to cryopreservation. Thus, the overall goal of this thesis was to investigate cryopreservation effects on model pancreatic substitutes consisting of cells encapsulated in non-adhesive and adhesive 3-D alginate hydrogels. Murine insulinoma betaTC-tet cells encapsulated in unmodified alginate hydrogels were chosen as the model pancreatic substitute in a non-adhesive 3-D environment. Murine myoblast C2C12 cells, stably transfected to secrete insulin, encapsulated in partially oxidized, RGD-modified alginate hydrogels were chosen as the model pancreatic substitute in a 3-D adhesive environment. With respect to cryopreservation effects on intermediary metabolism of betaTC-tet cells encapsulated in unmodified alginate, results indicate that relative carbon flow through the tricarboxylic acid cycle pathways examined is unaffected by cryopreservation. Additionally, insulin secretory function is maintained in Frozen constructs. However, vitrification by a cryopreservation cocktail referred to as DPS causes impairment in insulin secretion from encapsulated betaTC-tet cells, possibly due to a defect in late-stage insulin secretion. Results from Stable C2C12 cells encapsulated in RGD vs. RGE-alginate indicate that up to one day post-warming, cell-matrix interactions do not affect cellular response to cryopreservation after vitrification or freezing. Although there are differences in metabolic activity and insulin secretion immediately post-warming for DPS-vitrified RGD-encapsulated Stable C2C12 cells relative to Fresh controls, metabolic activity and insulin secretion are maintained at all time points assayed for Frozen constructs. Overall, due to results comparable to Fresh controls and simplicity of procedure, conventional freezing is appropriate for cryopreservation of betaTC-tet cells encapsulated in unmodified alginate or Stable C2C12 cells encapsulated in partially oxidized, RGD-modified alginate.

Metabolic flux analysis

RGD-modified alginate

Adhesion

Tissue engineering

Artificial pancreas

Tissue engineering

Alginates