Development of tunable bioinks to fabricate 3D-printed in vitro models: a special focus on skeletal muscle models with potential applications in metabolic alteration studies

[eng] In vitro engineered three-dimensional tissue models are attracting an increasing interest due to their potential applications in preclinical assays. On the one hand, they are an alternative to the high costs, ethical issues and time-consuming experiments associated with animal models. On the o...

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Detalles Bibliográficos
Autor: García Lizarribar, Andrea
Tipo de recurso: tesis doctoral
Estado:Versión publicada
Fecha de publicación:2022
País:España
Institución:Universidad de Barcelona
Repositorio:Dipòsit Digital de la UB
OAI Identifier:oai:diposit.ub.edu:2445/185742
Acceso en línea:https://hdl.handle.net/2445/185742
http://hdl.handle.net/10803/674271
Access Level:acceso abierto
Palabra clave:Impressió 3D
Materials biomèdics
Cultiu de teixits
Múscul estriat
Caquèxia
Càncer
Three-dimensional printing
Biomedical materials
Tissue culture
Striated muscle
Cachexia
Cancer
Descripción
Sumario:[eng] In vitro engineered three-dimensional tissue models are attracting an increasing interest due to their potential applications in preclinical assays. On the one hand, they are an alternative to the high costs, ethical issues and time-consuming experiments associated with animal models. On the other hand, unlike traditional monolayer cultures, 3D models are fabricated with polymer matrices that can mimic the spatial organization and physiological environment of native tissue. The scalability of these models to the market is currently limited by the fabrication methods. Additive manufacturing techniques, as extrusion bioprinting, provide the automated and controlled deposition of biomaterials with encapsulated cells to fabricate 3D models with unlimited shapes. However, few biomaterials fulfill the rheological, mechanical and biological needs for tissue engineering approaches. Printable biomaterials are commonly highly concentrated viscous fluids that could resemble the mechanical properties of stiff tissues, as skeletal muscle. However, they result in restrictive matrices with closed pores that can hamper the migration and proliferation of cells. As a solution, biomaterials have been chemically modified to obtain photocrosslinkable hydrogels, which provide 3D cultures with flexible physical properties. Nevertheless, current bioprinted muscle tissue models show poorly differentiated fibers and lack of functionality. Based on these precedents, this thesis is focused on the development of photocrosslinkable bioinks with tunable physical properties to fabricate customized in vitro 3D models of skeletal muscle tissue and neuroblastoma. To that end, gelatin, alginate and cellulose natural polymers are chemically modified to obtain UV- crosslinkable hydrogels with disparate physical properties. It is found that composite biomaterials of gelatin methacryloyl and alginate methacrylate present the best mechanical properties for stiff tissues as skeletal muscle and tumors. On this basis, the physical properties and composition of GelMA-AlgMA are modified to obtain matrices that resemble the physiological conditions of each tissue. It is found that neuroblastoma models require dense polymer networks to mimic the restrictive matrices found in solid tumors of high-risk patients. Neuroblastoma cell clusters in bioprinted cultures with a high concentration of AlgMA display the characteristic phenotype of aggressive solid tumors. Therefore, this bioink is proposed for the fabrication of stiff neuroblastoma tumor models. In contrast, this formulation was found unsuitable for skeletal muscle models, which present low proliferation and differentiation. Instead, the physical properties of GelMA-AlgMA bioink are tuned by changing the fabrication parameters, and fibrin is added to the composition to obtain a highly porous bioprinted model that resembles the mechanical properties of muscle tissue. As a result, muscle precursor cells are spontaneously differentiated into highly aligned mature fibers that, in combination with an electric pulse stimulation system, develop into mature muscle fibers with contraction capability and pronounced sarcomere units. The functionality of the bioprinted tissue agrees with the metabolic activity analysis, which corresponds to the behavior of native tissue. Hence, this model could be used to monitor the effects of drugs in the metabolic respiration of muscle mitochondria, simplifying the traditional protocols based on the isolation of single fibers. As an approach to obtain faithful platforms for the study of muscle pathologies as cancer cachexia, bioprinted muscle rings are treated with medium conditioned with colorectal cancer cells. This study shows that soluble factors secreted by cancer cells induce the upregulation of protein degradation pathways and degeneration of muscle fibers. In particular, high levels of soluble TNFRI are associated with severe cachexia, which correlates with the plasma level of tumor-bearing mice. The results indicate a close resemblance between the gene expression pattern of the bioprinted model and muscle tissue of cachectic mice, whereas monolayer cultures present several disparities. Together, GelMA-AlgMA-Fibrin is presented as a promising biomaterial for the fabrication of bioprinted models of healthy skeletal muscle tissue and muscle wasting on cancer cachexia disease.