Estudo da gelificação do produto de digestão de ECM descelularizada para uso em engenharia de tecidos / Gelation study of extracellular matrix digestion products for tissue engineering

Monteiro Lobato, Gabriela Matheus

26 April 2019

Os implantes utilizados para regeneração tecidual ainda falham na tentativa de mimetizar as propriedades da matriz extracelular (ECM), o que compromete a viabilidade e aplicabilidade do material. Além disso, permanece o desafio de desenvolver um método de aplicação minimamente invasivo para evitar danos teciduais adicionais (Badylak et al., 2015; Crapo et al., 2011; Xing et al., 2014). Assim, o objetivo do projeto é desenvolver um hidrogel injetável composto de ECM de pericárdio, tendão e osso bovino enzimaticamente digerida e reticulada com glutaraldeído, ésteres ativados de NHS e derivados de polietilenoglicol (PEG). O protocolo de digestão foi modificado de Willians (Williams et al., 2015), utilizando tripsina, pepsina e colagenase. A quantificação de GAGs e peptídeos mostrou que, independentemente do substrato e enzima utilizados, o processo em etapas gerou uma maior concentração de estruturas em relação ao processo contínuo. Adicionalmente, a análise de dicroísmo circular mostrou que o processo em etapas preservou mais estruturas secundárias. O perfil proteico das ECMs foi analisado como descrito em Flores (Flores et al., 2016), e foi verificado que ele é altamente diverso e tecido - específico. A ECM do pericárdio possui 94 tipos diferentes de proteínas, seguidas pela ECM do tendão (48) e pela ECM óssea (35), sendo o colágeno α1 (1) e o colágeno α2 (1) presentes em todas elas. Além disso, os produtos digeridos ECMp aumentaram a proliferação e diferenciação de células-tronco mesenquimais da medula óssea a osteoblastos maduros. A cinética do processo de gelificação, bem como as propriedades mecânicas do gel são dependentes do tipo de agente reticulante, assim como da concentração da gelatina. Este novo material é altamente personalizável e adaptável à aplicação biológica desejada. / The implants used for tissue regeneration still fail to mimic properties of extracellular matrix. It compromises the material viability and applicability. Furthermore, the challenge to manufacture a minimally invasive delivery system for it to avoid extra tissue damage still remains (Badylak et al., 2015; Crapo et al., 2011; Xing et al., 2014). Thus, the project goal is to develop an injectable hydrogel composed of pericardium, tendon and bovine bone ECM enzymatically digested and crosslinked with glutaraldehye, activated esters of NHS and polyethylene glycol (PEG) derivatives. The digestion protocol was modified from Willians (Williams et al., 2015), using trypsin, pepsin and collagenase as lytic enzymes. GAGs and peptides quantification showed that regardless of the substrate and enzyme, the stepwise process yields a higher amount of GAGs and peptides in comparison with the continuous process. In addition, circular dicroism analysis showed that the stepwise process preserves more secondary structures of proteins. ECMs protein profile was analyzed as in Flores (Flores et al., 2016) and verified that it is the highly diverse and tissue-specific. Pericardium ECM has 94 different types of proteins, followed by tendon ECM (48) and bones ECM (35), being collagen α1(1) and collagen α2(1) present in all of them. Furthermore, the ECMp digested products enhanced bone marrow mesenchymal stem cells proliferation and differentiation in mature osteoblast. The kinetics of the gelification process, as well as mechanical properties of the gel is dependent of the type of crosslinker and concentration of gelatin. This new material is highly customizable and adaptable to the biological application.

Engenharia de tecidos

Extracellular matrix

Hidrogel

Hydrogel

Matriz extracelular

Tissue engineering

The structural basis of arterial stiffness and its relationship to cardiovascular outcome

Berry, Karen L. (Karen Louise), 1972-

January 2003

Abstract not available

Arteries

Extracellular matrix

Hypertension

Marfan syndrome

Blood pressure

The wettability of biomaterials determines the protein adsorption and the cellular responses

Tzoneva-Velinova, Rumiana

January 2003

During the past several decades polymer materials become widely used as components of medical devices and implants such as hemodialysers, bioartificial organs as well as vascular and recombinant surgery. Most of the devices cannot avoid the blood contact in their use. When the polymer materials come in contact with blood they can cause different undesired host responses like thrombosis, inflammatory reactions and infections. Thus the materials must be hemocompatible in order to minimize these undesired body responses. The earliest and one of the main problems in the use of blood-contacting biomaterials is the surface induced thrombosis. The sequence of the thrombus formation on the artificial surfaces has been well established. The first event, which occurs, after exposure of biomaterials to blood, is the adsorption of blood proteins. Surface physicochemical properties of the materials as wettability greatly influence the amount and conformational changes of adsorbed proteins. In turn the type, amount and conformational state of the adsorbed protein layer determines whether platelets will adhere and become activated or not on the artificial surface and thus to complete the thrombus formation. The adsorption of fibrinogen (FNG), which is present in plasma, has been shown to be closely related to surface induced thrombosis by participating in all processes of the thrombus formation such as fibrin formation, platelet adhesion and aggregation. Therefore study the FNG adsorption to artificial surfaces could contribute to better understanding of the mechanisms of platelet adhesion and activation and thus to controlling the surface induced thrombosis. <br /> <br /> Endothelization of the polymer surfaces is one of the strategies for improving the materials hemocompatibility, which is believed to be the most ideal solution for making truly blood-compatible materials. Since at physiological conditions proteins such as FNG and fibronectin (FN) are the usual extracellular matrix (ECM) for endothelial cells (EC) adhesion, precoating of the materials with these proteins has been shown to improve EC adhesion and growth in vitro. ECM proteins play an essential role not only like a structural support for cell adhesion and spreading, but also they are important factor in transmitting signals for different cell functions. The ability of cells to remodel plasma proteins such as FNG and FN in matrix-like structures together with the classical cell parameters such as actin cytoskeleton and focal adhesion formation could be used as an criteria for proper cell functioning. The establishment and the maintaining of delicate balance between cell-cell and cell-substrate contacts is another important factor for better EC colonization of the implants. The functionality of newly established endothelium in order to produce antithromotic substances should be always considered when EC seeding is used for improving the hemocompatibility of the polymer materials. <br /> <br /> Controlling the polymer surface properties such as surface wettability represents a versatile approach to manipulate the above cellular responses and therefore can be used in biomaterial and tissue engineering applications for producing better hemocompatible materials.

Chemistry and allied sciences

Development of a Cancer Vaccine Targeting Tumor Blood Vessels

Huijbers, Elisabeth J. M

January 2012

A treatment strategy for cancer is the suppression of tumor growth by directing an immune response to the tumor vessels, which will destroy the tissue. In this thesis we describe the development of a vaccine that targets antigens expressed around angiogenic vasculature in most solid tumors. These antigens are alternative spliced extra domains of glycoproteins present in the extracellular matrix; e.g. the extra domain-B (ED-B) and extra domain-A (ED-A) of fibronectin and the C-domain of tenascin-C (TNCC). We show that it is possible to break self-tolerance and induce a strong antibody response against ED-B by vaccination. Furthermore, tumor growth was inhibited and the changes observed in the tumor tissue were consistent with an attack of the tumor vasculature by the immune system. For clinical development of therapeutic vaccines, targeting self-molecules like ED-B, a potent but non-toxic biodegradable adjuvant is required. The squalene-based Montanide ISA 720 (M720) in combination with CpG DNA fulfilled these requirements and induced an equally strong anti-self immune response as the preclinical golden standard Freund’s adjuvant. We have further characterized the immune response against ED-B generated with the adjuvant M720/GpG.  The ED-B vaccine also inhibited tumor growth in a therapeutic setting in a transgenic mouse model of pancreatic insulinoma in which tumorigenesis was already initiated. Furthermore, antibodies against ED-A and TNCC could be induced in mice and rabbits. We analyzed the expression of ED-A in breast tumors of transgenic MMTV-PyMT mice, a metastatic breast cancer model, with the aim to use this model to study the effect of an ED-A vaccine on metastasis. We also detected ED-B in canine mammary tumor tissue. Therefore vascular antigens might also represent potential therapeutic targets in dogs.  All together our preclinical data demonstrate that a vaccine targeting tumor blood vessels is a promising new approach for cancer treatment.

Vaccine

Therapeutic

Cancer

Tumor

Angiogenesis

Immunization

Vascular

Extracellular matrix

The Filzig protein affects embryonic cuticle and taenidia organization in Drosophila

Geberemedhin, Mengistu Tadese

January 2011

Abstract The surface of multicellular organisms is covered with epithelial cells that provide a barrier to the external environment. As part of this barrier function, most epithelia produce apical extracellular matrices (aECMs). The generation of such chemical and physical barriers requires specialized deposition of macromolecules and is likely to involve a spatial and temporal coordination of biochemical activities at the apical surface. A challenging task is thus to characterize key proteins that underlie apical cell surface organization and correct aECM assembly. The Drosophila trachea provides an excellent system to study aECM formation, as they produce an ordered aECM, called the cuticle. The tracheal cuticle is unique by its presence of cuticular ridges, called taenidial folds, which prevent collapse of tracheal tubes while allowing them to expand and contract along their length. A gene called filzig encodes a transmembrane serine protease and is required for taenidial organization. The aim of this research was to further understand Filzig function through characterization of filzig mutants and Filzig protein expression. The results showed that Filzig is expressed in cuticle-producing epithelia as cuticle deposition begins. Moreover, Flz localized to the apical epithelial surface, as well as to the aECM. The apical Flz localization does not reflect the pattern of cuticle ridges, indicating that Flz-localization is not a determinant for taneidial patterning. Instead, Flz might act on extracellular targets that localize to the future taneidial folds. Alternatively, Filzig is involved in a cascade of self-organizing activity of cuticular components to form the regular taenidial folds.

apica extracellular matrix

transmembrane proteins

cuticle

taenidia

chitin

Coating Collagen Modules with Fibronectin Increases in vivo HUVEC Survival and Vessel Formation through the Suppression of Apoptosis

Cooper, Thomas

13 January 2010

Modular tissue engineering is a novel approach to creating scalable, self-assembling three-dimensional tissue constructs with inherent vascularisation. Under initial methods, the subcutaneous implantation of human umbilical vein endothelial cell (HUVEC)-covered collagen modules in immunocompromised mice resulted in significant host inflammation and limited HUVEC survival. Subsequently, a minimally-invasive injection technique was developed to minimize surgery-related inflammation, and cell death was attributed to extensive apoptosis within 72 hours of implantation. In confirmation of in vitro results, coating collagen modules with fibronectin (Fn) was shown in vivo to reduce short-term HUVEC apoptosis by nearly 40%, while increasing long-term HUVEC survival by 30% to 45%. Consequently, a 100% increase in the number of HUVEC-lined vessels was observed with Fn-coated modules, as compared to collagen-only modules, at 7 and 14 days post-implantation. Furthermore, vessels appeared to be perfused with host erythrocytes by day 7, and vessel maturation and stabilization was evident by day 14.

modular tissue engineering

endothelial cells

apoptosis

extracellular matrix

fibronectin

0541

Coating Collagen Modules with Fibronectin Increases in vivo HUVEC Survival and Vessel Formation through the Suppression of Apoptosis

Cooper, Thomas

13 January 2010

Modular tissue engineering is a novel approach to creating scalable, self-assembling three-dimensional tissue constructs with inherent vascularisation. Under initial methods, the subcutaneous implantation of human umbilical vein endothelial cell (HUVEC)-covered collagen modules in immunocompromised mice resulted in significant host inflammation and limited HUVEC survival. Subsequently, a minimally-invasive injection technique was developed to minimize surgery-related inflammation, and cell death was attributed to extensive apoptosis within 72 hours of implantation. In confirmation of in vitro results, coating collagen modules with fibronectin (Fn) was shown in vivo to reduce short-term HUVEC apoptosis by nearly 40%, while increasing long-term HUVEC survival by 30% to 45%. Consequently, a 100% increase in the number of HUVEC-lined vessels was observed with Fn-coated modules, as compared to collagen-only modules, at 7 and 14 days post-implantation. Furthermore, vessels appeared to be perfused with host erythrocytes by day 7, and vessel maturation and stabilization was evident by day 14.

modular tissue engineering

endothelial cells

apoptosis

extracellular matrix

fibronectin

0541

Development of Osteoinductive Tissue Engineering Scaffolds with a Bioreactor

Thibault, Richard

24 July 2013

The conventional treatments for craniofacial bone defects currently are unsatisfactory due to several drawbacks. Replacement of lost bone by autografts typically causes donor site morbidity while allografts, xenografts, and demineralized bone matrix all have a chance of disease transmission. Current synthetic implants placed within the defect site generally lack osseointegration and biodegradability. There are several methods of generating a hybrid extracellular matrix (ECM) and synthetic material construct. These include coating the synthetic material scaffold with collagen and calcium phosphate, incorporating acellular biological tissue within the scaffold material, and using cells to generate an ECM coating on the synthetic material scaffold. The research performed for this thesis developed and characterized mesenchymal stem cell (MSC)-generated extracellular matrix poly(ε-caprolactone) constructs (PCL/ECM) for the replacement of bone tissue. The osteogenic potential of the PCL/ECM constructs was explored by culturing i) MSCs and ii) whole marrow cells combined with MSCs onto the construct with or without the osteogenic differentiation supplement, dexamethasone. It was established that the osteogenic differentiation of MSCs seeded onto ECM-containing constructs was maintained even in the absence of dexamethasone and that the co-culture of MSCs and whole bone marrow cells without dexamethasone and ECM enhances the proliferation of a cell population (or populations) present in the whole bone marrow. The osteogenicity of the constructs encouraged the characterization of the protein and mineral composition of the ECM coating on the PCL/ECM constructs. Characterization revealed that at short culture durations the MSCs used to generate the ECM deposited cellular adhesion proteins that are a prerequisite protein network for further bone formation. At the later culture durations, it was determined that the ECM was composed of collagen 1, hydroxyapatite, matrix remodeling proteins, and regulatory proteins. The prior studies on the PCL/ECM constructs persuaded exploration of the effect of various devitalization and demineralization processes on the retention of the ECM components within and the osteogenicity of the PCL/ECM constructs. Analysis demonstrated that the freeze-thaw technique is a milder method of devitalization of cell-generated ECM constructs as compared to other methods, but it reduced the osteogenicity of the constructs. In addition, it was elucidated that void spaces in the surface of the constructs are important for allowing access of MSCs into the interior of the constructs.

Bone

tissue engineering

extracellular matrix

scaffold

mesenchymal stem cells

A Novel Human Adipocyte-Derived Basement Membrane for Tissue Engineering Applications

Damm, Aaron

06 September 2012

Tissue engineering strategies have traditionally focused on the use of synthetic polymers as support scaffolds for cell growth. Recently, strategies have shifted towards a natural biologically derived scaffold, with the main focus on decellularized organs. Here, we report the development and engineering of a scaffold naturally secreted by human preadipocytes during differentiation. During this differentiation process, the preadipocytes remodel the extracellular matrix by releasing new extracellular proteins. Finally, we investigated the viability of the new basement membrane as a scaffold for tissue engineering using human pancreatic islets, and as a scaffold for soft tissue repair. After identifying the original scaffold material, we sought to improve the yield of material, treating the cell as a bioreactor, through various nutritional and cytokine stimuli. The results suggest that adipocytes can be used as bioreactors to produce a designer-specified engineered human extracellular matrix scaffold for specific tissue engineering applications.

Adipocytes

humalipogel

Bioscaffold

Extracellular Matrix

Growth Factor

Natural Biomaterials

Correlation Between MMP-2 and -9 Levels and Local Stresses in Arteries Using a Heterogeneous Mechanical Model

Kim, Yu Shin

06 July 2007

The mechanical environment influences vascular smooth muscle cell (VSMC) functions related to the vascular remodeling. However, the relationships are not appropriately addressed by most mechanical models of arteries assuming homogeneity. Accounting for the effects of heterogeneity is expected to be important to our understanding of VSMC functions. We hypothesized that local stresses computed using a heterogeneous mechanical model of arteries positively correlate to the levels of matrix metalloproteinase (MMP)-2 and -9 in situ. We developed a mathematical model of an arterial wall accounting for nonlinearity, residual strain, anisotropy, and structural heterogeneity. The distributions of elastin and collagen fibers, quantified using their optical properties, showed significant structural heterogeneity. Anisotropy was represented by the direction of collagen fibers, which was measured by the helical angle of VSMC nuclei. The recruiting points of collagen fibers were computed assuming a uniform strain of collagen fibers under physiological loading conditions; an assumption motivated by the morphology. This was supported by observed uniform length and orientation of VSMC nuclei under physiological loading. The distributions of circumferential stresses computed using both heterogeneous and corresponding homogeneous models were correlated to the distributions of expression and activation of MMP-2 and -9 in porcine common carotid arteries, which were incubated in an ex vivo perfusion organ culture system under either normotensive or hypertensive conditions for 48 hours. While strains computed using incompressibility were identical in both models, the heterogeneous model, unlike the homogeneous model, predicted higher circumferential stresses in the outer layer. The tissue levels of MMP-2 and -9 were positively correlated to circumferential stresses computed using the heterogeneous model, which implies that areas of high stress are expected to be sites of localized remodeling and agrees with results from cell culture studies. The results support the role of mechanical stress in vascular remodeling and suggest the importance of structural heterogeneity in studying mechanobiological responses.

Matrix metalloproteinase

Extracellular matrix

Blood-vessels

Mechanical modeling