Articular cartilage tissue engineering using chondrogenic progenitor cell homing and 3D bioprinting

Yu, Yin

01 May 2015

Articular cartilage damage associated with joint trauma seldom heals and often leads to osteoarthritis (OA). Current treatment often fails to regenerated functional cartilage close to native tissue. We previously identified a migratory chondrogenic progenitor cell (CPC) population that responded chemotactically to cell death and rapidly repopulated the injured cartilage matrix, which suggested their potential for cartilage repair. To test that potential we filled experimental full thickness chondral defects with an acellular hydrogel containing SDF-1α. We expect that SDF-1α can increase the recruitment of CPCs, and then promote the formation of a functional cartilage matrix with chondrogenic factors. Full-thickness bovine chondral defects were filled with hydrogel comprised of fibrin and hyaluronic acid and containing SDF-1α. Cell migration was monitored, followed by chondrogenic induction. Regenerated tissue was evaluated by histology, immunohistochemistry, and scanning electron microscopy. Push-out tests were performed to assess the strength of integration between regenerated tissue and host cartilage. Significant numbers of progenitor cells were recruited by SDF-1α within 12 days. By 5 weeks chondrogenesis, repair tissue cell morphology, proteoglycan density and surface ultrastructure were similar to native cartilage. SDF-1α treated defects had significantly greater interfacial strength than untreated controls. However, regenerated neocartilage had relatively inferior mechanical properties compared with native cartilage. In addition to that, we developed a 3D bioprinting platform, which can directly print chondrocytes as well as CPCs to fabricated articular cartilage tissue in vitro. We successfully implanted the printed tissue into an osteochondral defect, and observed tissue repair after implantation. The regerated tissue has biochemical and mechanical properties within the physiological range of native articular cartilage. This study showed that, when CPC chemotaxis and chondrogenesis are stimulated sequentially, in situ full thickness cartilage regeneration and bonding of repair tissue to surrounding cartilage could occur without the need for cell transplantation from exogenous sources. This study also demonstrated the potential of using 3D bioprinting to engineer articular cartilage implants for repairing cartilage defect.

Bioprinting

Cartilage repair

Cell homing

Chondrogenic Progenitor Cells

Stem Cells

Tissue Engineering

SURFACE FUNCTIONALIZATION VIA PHOTOINITIATED RADICAL POLYMERIZATION FOR RARE CELL ISOLATION AND MECHANICAL PROTECTION

Cahall, Calvin Frank

01 January 2018

Surface functionalization of living cells for cell therapeutics has gained substantial momentum in the last two decades. From encapsulating islets of Langerhans, to cell laden gels for tissue scaffolds, to individual cell encapsulation in thin hydrogels, to surface adhesives and inert surface camouflage, modification of living cell surfaces has a wide array of important applications. Here we use hydrogel encapsulation of individual cells as a mode of protection from mechanical forces for high throughput cell printing, and chemical stimuli for the isolation of rare cells in blood. In the first study, we review methods of surface functionalization and establish a metric of potential target biomarkers for circulating tumor cell (CTC) isolation. For extended applications in cancer detection through a fluid biopsy, common surface antigen densities were quantitatively assessed in relation to peripheral blood mononuclear cells (PBMCs) for potential targets of cell specific encapsulation. We then look to commercialization of our process after considering biopsy volumes and cell therapy dose sizes. Undesired batch-to-batch variation in our in-house synthesized photo-initiator could be eliminated by the use of fluorescein, a commercial fluorochrome of similar initiating power to our current eosin initiating system. Fluorescence and hydrogel generation were compared indicating a fluorescein conjugate has comparable power to that of our in-house conjugated eosin. Parameters involving the number of cells and fluid volumes processed were then analyzed systematically. Key parameters were studied to determine optimal equipment and protocol for clinically relevant batch sizes. The final study looks at the mechanical protection provided by thin hydrogel encapsulation. With growing interests in 3D bioprinting and goals of viable whole organ printing for transplant, high resolution and high throughput printing is a growing need. 3D bioprinting presents intense mechanical stimuli in the process that cells must endure. Here we analyze how hydrogel encapsulation reinforces the cellular membrane allowing cells to withstand the damaging forces associated with bioprinting.

cell encapsulation

bioprinting

photopolymerization

surface polymerization

isolation

Polymer Science

Nuclear Rupture in Progeria Expressing Cells

Bathula, Kranthidhar

01 January 2018

Cells regularly take on various types of force in the body. They have structures that are able to mediate, transfer and respond to the forces. A mutation in force regulating proteins such as lamin in the nucleus or the KASH domain which connects the nucleus to the cytoskeleton of the cell can cause catastrophic events to occur. The aims of this study were to better understand the response of the nucleus when structural proteins are mutated or are not present while under force. Progeria, a rare disease where an additional farnesyl group is attached to lamin was used in this study. Different types of forces were used to represent similar conditions in the body. Confinement of endothelial cell width showed an increase of surface defects. When restricting proteins such as actin was removed the nucleus appeared to rupture. This was shown to occur at a higher rate in the progeria groups. Endothelial cells under shear force showed high amount of nuclear rupture in progeria expressing group. prolonged exposure showed more rupture which eventually cased cell death and cells to come off the surface. Progeria expressing smooth muscle cells under cyclic stretch also showed similar results as endothelial cells. The amount and rate of deformation of the nucleus when the cytoskeleton is connected and not was looked at. When the connected the rate of deformation was higher. The high rate of nuclear defects and rupture while under force in progeria expressing cells shows that the nuclei have different structural properties and are weaker. It’s also been shown that the LINC complex contributes to nuclear deformation when stretching.

Nuclear Rupture

Progeria

LINC Complex

Laminopathy

Nuclear Strain

Cell Strain

Musculoskeletal Diseases

Engineering Surface Properties to Modulate Inflammation and Stem Cell Recruitment through Macrophage Activation

Hotchkiss, Kelly M

01 January 2018

Biomaterials are becoming the most commonly used therapeutic method for treatment of lost or damaged tissue in the body. Metallic materials are chosen for high strength orthopaedic and dental applications. Titanium (Ti) implants are highly successful in young, healthy patients with the ability to fully integrate to surrounding tissue. However the main population requiring these corrective treatments will not be healthy or young, therefore further research into material modifications have been started to improve outcomes in compromised patients. The body’s immune system will generate a response to any implanted material, and control the final outcome. Among the first and most influential, cells to interact with the implant will be macrophages. Throughout this study we have 1) established the ability of macrophages to recognize and differentially activate in response to material surface properties, 2) investigated the role of integrin binding in macrophage activation to material properties, and 3) confirmed the importance of macrophage activation in vivo following Ti implant placement. The generation of a hydrophilic implant surface promoted the greatest anti-inflammatory and pro-regenerative macrophage activation. Surface wettability will control protein adsorption which can activated different integrin binding on macrophages and may be responsible for changes in activation. When integrin β3 subunit binding was prevented hydrophilic surfaces no longer promoted an anti-inflammatory macrophage activation. Additionally, when macrophage levels were reduced using two separate ablation models, MaFIA mice and clodronate liposomes, hydrophilic surfaces no longer promoted anti-inflammatory T-cell populations and cytokine profiles. There were also fewer stem cells adhered to implant surfaces at 1, 3, and 7 days when macrophage populations were compromised.

Macrophage

Biomaterials

Titanium

Implants

Stem Cells

T-cells

Immune Response

Biomaterials

Immunity

Decellularized Matrices Effect on the Adaptive Immune Response

Sowers, Kegan

01 January 2018

Decellularized extracellular matrices have been a growing area of interest in the biomedical engineering fields of tissue engineering and regenerative medicine.As these materials move toward clinical applications, the immune response to these materials will be a driving force toward their success in clinical approaches. Fully digested decellularized matrix constructs derived from porcine liver, muscle and lung were created to test the adaptive immune response. Hydrogel characterization ensured that the materials had relatively similar stiffness levels to reduce variability, and in vitro studies were conducted. Each individual construct as well as a gelatin control were plated with a co-culture of macrophages and T-cells to measure T-cell proliferation. In addition standard markers of inflammation through qPCR were measured in the macrophage group. Constructs were then placed into animals for 3 and 7 days in addition to a second group that received constructs for 21 days before secondary constructs were placed. These groups were then sacrificed following 3, 7 and 14 days to measure the residual and memory-like response of the constructs. Our results showed that t-cell proliferation was increased with decellularized constructs, particularly in tissue with higher DNA content. In vivo, animals with secondary treatments showed extended inflammatory response, driven by Th1 and Th17 polarization suggesting a memory-like response due to recognition of peptides in the constructs from secondary placements.

Adaptive immune system

biomaterials

extracellular matrices

decellularization

hydrogels

inflammation

Biomaterials

Designing Biomimetic Implant Surfaces to Promote Osseointegration under Osteoporotic Conditions by Revitalizing Mechanisms Coupling Bone Resorption to Formation

Lotz, Ethan M

01 January 2019

In cases of compromised bone remodeling like osteoporosis, insufficient osseointegration occurs and results in implant failure. Implant retention relies on proper secondary fixation, which is developed during bone remodeling. This process is disrupted in metastatic bone diseases like osteoporosis. Osteoporosis is characterized low bone mass and bone strength resulting from either accelerated osteoclast-mediated bone resorption or impaired osteoblast-mediated bone formation. These two processes are not independent phenomena. In fact, osteoporosis can be viewed as a breakdown of the cellular communication connecting bone resorption to bone formation. Because bone remodeling occurs at temporally generated specific anatomical sites and at different times, local regulators that control cross-talk among the cells of the BRU are important. Previous studies show Ti implant surface characteristics like roughness, hydrophilicity, and chemistry influence the osteoblastic differentiation of human MSCs and maturation of OBs. Furthermore, microstructured Ti surfaces modulate the production of factors shown to be important in the reciprocal communication necessary for the maintenance of healthy bone remodeling. Semaphorin signaling proteins are known to couple the communication of osteoblasts to osteoclasts and are capable of stimulating bone formation or bone resorption depending on certain cues. Implant surface properties can be optimized to exploit these effects to favor rapid osseointegration in patients with osteoporosis.

Titanium

Osseointegration

Bone Remodeling

Osteoclast

Osteoblast

Mesenchymal Stem Cell

Biomaterials

Dental Materials

Generation And Evaluation Of Decellularized Hypertensive Rat Lung Scaffolds For Tissue Engineering Applications

Unknown Date

There are not enough donor lungs available to meet the increasing demand for lung transplantation. To compound the problem, transplant recipients have a projected survival time of only 5.7 years despite life-long immunosuppression. An alternative approach for acquiring transplantable lungs and reducing post-operative complications may be possible through tissue engineering. Perfusion-decellularization generates natural, three-dimensional extracellular matrix (ECM) scaffolds of an organ that are apt for tissue engineering. Decellularization of the heart, lung, liver, kidney, and pancreas has been reported in animal models and from human tissue. Decellularization of fibrotic and emphysematic lungs indicated that this technique can efficiently remove cells from diseased tissue—a potential source of materials for engineering of transplantable lung tissue. Pulmonary hypertension (PHT) is a vascular disease characterized by increased pulmonary vascular resistance leading to right heart failure and death. Lungs damaged by PHT are unsuitable for transplantation; however, decellularization of these organs may provide scaffolds appropriate for ex vivo lung engineering. Monocrotaline-induced PHT (MCT-PHT) is a well-established model of this disease in rats closely resembling the clinical presentation of PHT in humans. Thus, decellularization and recellularization of hypertensive lungs was evaluated using the MCT-PHT model. Decellularization of control and MCT-PHT Sprague-Dawley rat lungs was accomplished by treating the lungs with Triton X-100, sodium deoxycholate (SDC), NaCl, and DNase. The resulting acellular matrices were extensively characterized by molecular, mechanical, and structural analyses revealing that decellularization was able to remove cells while leaving the ECM components and lung ultrastructure intact; however, the vasculature of MCT-PHT acellular lung scaffolds was narrower than control scaffolds—a hallmark of PHT. To evaluate the effect of narrowed vasculature on the use of hypertensive lungs for tissue engineering, an optimal vascular recellularization technique was developed. Gravity-based seeding of endothelial cells followed by bioreactor-based whole-organ culture resulted in efficient vascular recellularization of control lung scaffolds. However, this method led to heterogeneous re-endothelialization of the vasculature of MCT-PHT matrices suggesting that additional manipulation or optimization is required. / acase@tulane.edu

Tissue Engineering

Decellularization

Recellularization

Lung

Endothelial Cells

Scaffolds

School of Medicine

Biomedical Sciences Graduate Program

Ph.D

A Hydrogel Tool-kit For In Vitro Neural Regeneration Models

Unknown Date

Soft tissue reconstruction in the nervous system is sensitive to the mechanical and chemical cues of the growth microenvironment. Many technologies have been designed to study these stimuli and their effect on the regional extracellular environment (ECM). Because of the hard-to-achieve and costliness of these technologies, biologists are usually reluctant to employ them to study cellular behaviors. In addition, the complexity of the nervous system, particularly in cases of nerve repair and reconstruction, necessitates the development of facile high- throughput investigational tools. The objective for this dissertation is to examine and manipulate neuronal cell-cell and cell-ECM responses to varying nervous system microenvironment stimuli in a 3-D in vitro model. / acase@tulane.edu

Tissue Engineering

In Vitro

Neural Regeneration

School of Science & Engineering

Biomedical Engineering

Ph.D

The effects of cyclic hydrostatic pressure on chondrocytes in an alginate substrate

Journot, Brice James

01 May 2012

No description available.

ALGINATE

CARTILAGE

CHONDROCYTE

CHONDROGENIC PROGENITOR CELL

HYDROSTATIC PRESSURE

TISSUE ENGINEERING

Controlled drug delivery systems and integration into 3D printing

Do, Anh-Vu Tran

01 August 2018

Controlled drug delivery systems have been utilized to enhance the therapeutic effects of many current drugs by effectively delivering drugs in a time-dependent and repeatable manner. The ability to control the delivery of drugs, whether through sequential, instantaneous, sustained, delayed and/or enhanced release has the potential to provide effective dosing regimens with enhanced therapeutic effects for a plethora of diseases and injuries. For instance, such systems can enhance anti-tumoral responses or, alternatively, promoting tissue regeneration. The current need for organ and tissue replacement, repair and regeneration for patients is continually growing such that supply is not meeting the high demand primarily due to a paucity of donors as well as biocompatibility issues that lead to immune rejection of the transplant. To overcome this problem, scientists working in the field of tissue engineering and regenerative medicine have investigated the use of scaffolds as an alternative to transplantation. These scaffolds are designed to mimic the extracellular matrix (ECM) by providing structural support as well as promoting attachment, proliferation, and differentiation with the goal of yielding functional tissues or organs. Continued advancement and hybrid approaches using different material combinations and printing methodologies will further advance the progress of 3D printing technologies toward developing scaffolds, and other implantable drug delivery devices, capable of being utilized in the clinic. Such advancements will not only make inroads into improving structural integrity of implantable devices but will also provide platforms for controlled drug delivery from such devices. The primary focus of this thesis will be on controlled drug delivery as well as the integration of controlled drug delivery into 3D printed devices aimed at promoting tissue regeneration. We initially assessed the efficacy of a controlled drug delivery system for the treatment of cancer using on-demand, and sustained, release of an anticancer drug, doxorubicin (DOX), for the treatment of melanoma in a murine model. Using a melanoma model, we investigated the antitumor potential of combining ultrasound (US) with poly(lactic-co-glycolic acid) (PLGA) microspheres loaded with DOX. An in vitro release assay demonstrated an ability of US to affect the release kinetics of DOX from DOX-loaded PLGA microspheres by inducing a 12% increase in rate of release where this treatment resulted in synergistic tumor cell (B16-F10 melanoma cells) killing. Melanoma-bearing mice treated intratumorally with DOX (8 µg)-loaded microspheres and subjected to US treatment at the tumor site were shown to significantly extended survival compared to untreated mice or mice subjected to either treatment alone. The synergistic increase in survival of melanoma-challenged mice treated with the combination of US and DOX-loaded microspheres implicates a promising additional tool for combatting an otherwise currently incurable cancer. We then further investigated other novel control drug delivery systems which included a 3D printed device (tube) for the purposes of sequential drug delivery. 3D printed hollow alginate tubes were fabricated through co-axial bioprinting and then injected with PLGA to provide sequential release of distinct fluorescent dyes (model drugs), where fluorescein was initially released from alginate followed by the delayed release (up to 55 h) of rhodamine B in PLGA. With an alginate shell and a PLGA core, the fabricated tubes showed no cytotoxicity when incubated with the human embryonic kidney (HEK293) cell line or bone marrow stromal stem cells (BMSC). Microscale printing through two-photon polymerization (2PP) was then investigated for controlled drug delivery potential. Poly(ethylene glycol) dimethacrylate (PEGDMA) devices were fabricated using a Photonic Professional GT two-photon polymerization system while rhodamine B was homogenously entrapped inside the polymer matrix during photopolymerization. These devices were printed with varying porosity and morphology and using varying printing parameters such as slicing and hatching distance. Overall, tuning the hatching distance, slicing distance, and pore size of the fabricated devices provided control of rhodamine B release due to resulting changes in the motility of the small molecule and its access to structure edges. In general, increased spacing provided higher drug release while smaller spacing resulted in some occlusion, preventing media infiltration and thus resulting in reduced drug release. 2PP was further explored for its ability to tailor topographical cues in addition to controlled drug release. These physical cues, similar to those of the ECM, have been seen to promote differentiation. With 2PP, we explored microscale topographies with nanoscale precision, where different star size topographies were fabricated. It was observed that the smallest star size topographies differentiated human iPSCs towards the endoderm and mesoderm germ layer. Integrating the facility for controlled drug release into 3D printed devices provides a demand for constructs that not only need to fulfill their purpose of temporarily substituting for the missing tissue at the site of injury, but also providing the necessary cues to promote appropriate tissue regeneration. With 3D printing technology, novel drug delivery constructs were fabricated and tested to appraise functionality such as the ability to control drug delivery and the ability to function as a non-toxic medium for cellular attachment, proliferation, and forced differentiation.

3D Printing

Bioprinting

Controlled Drug Delivery

Tissue Engineering

Two-Photon Polymerization