Photoclickable inks: 3D printing intelligent gelling systems with biomedical applications
| Autor(a) principal: | |
|---|---|
| Data de Publicação: | 2023 |
| Tipo de documento: | Dissertação |
| Idioma: | eng |
| Título da fonte: | Repositórios Científicos de Acesso Aberto de Portugal (RCAAP) |
| Texto Completo: | http://hdl.handle.net/10773/44617 |
Resumo: | Over the past decade, 3D printing has gained increasing popularity, being a technique capable of producing well-defined tissue-like structures. One of its most appealing features is the ability to create personalized therapies to meet the specific demands of individual patients. However, challenges including the selection of materials, as well as crosslinking strategies still need to be addressed, in order to enhance the inks characteristics and simultaneously create printable, robust, and cytocompatible biomaterials. Hence, this study reports the development of natural-based photoclickable inks, composed of hyaluronic acid (HA) and proteins [bovine serum albumin (BSA) and human platelet lysates (hPL)] for 3D extrusion printing, taking advantage of the versatility, efficiency, and fast kinetics of thiol-ene click chemistry. To this end, HA was modified with norbornene (HA-Nor) moieties, while proteins were thiolated (BSA-SH and hPL-SH). 1H-NMR and ATR-FTIR analysis of the resulting polymers, HA-Nor, BSA-SH and hPL-SH, confirmed the success of their modification. These polymers were mixed, varying the protein concentration and, subsequently, bio-orthogonally photo-crosslinked, using visible light and LAP as photoiniator, creating hydrogel cell-friendly networks. Rheological characterization affirmed the chemistry’s potential in rapidly gelling networks (t < 20 s) achieving an elastic modulus, G’, of approximately 104 Pa, highlighting its suitability for 3D printing applications. Moreover, the mechanical characterization of the hydrogels revealed that those containing higher BSA-SH concentration were more robust, indicating the presence of more crosslinking points, as expected. The mechanical and rheological properties of the inks enabled 3D extrusion printing. Additionally, direct and indirect contact of hASCs with the materials through seeding, confirmed their cytocompatibility and non-toxicity, maintaining cell viability up to 14 days, which was assessed through fluorescence microscopy images and metabolic activity. Therefore, HA-Nor/BSA-SH and HA-Nor/hPL-SH inks are expected to be promising future bioinks for regenerative medicine and tissue engineering of soft tissues, opening avenues for personalized medicine. |
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Photoclickable inks: 3D printing intelligent gelling systems with biomedical applicationsBiofabrication3D printingInksHydrogelsPhotocrosslinkingThiol-ene click chemistryOver the past decade, 3D printing has gained increasing popularity, being a technique capable of producing well-defined tissue-like structures. One of its most appealing features is the ability to create personalized therapies to meet the specific demands of individual patients. However, challenges including the selection of materials, as well as crosslinking strategies still need to be addressed, in order to enhance the inks characteristics and simultaneously create printable, robust, and cytocompatible biomaterials. Hence, this study reports the development of natural-based photoclickable inks, composed of hyaluronic acid (HA) and proteins [bovine serum albumin (BSA) and human platelet lysates (hPL)] for 3D extrusion printing, taking advantage of the versatility, efficiency, and fast kinetics of thiol-ene click chemistry. To this end, HA was modified with norbornene (HA-Nor) moieties, while proteins were thiolated (BSA-SH and hPL-SH). 1H-NMR and ATR-FTIR analysis of the resulting polymers, HA-Nor, BSA-SH and hPL-SH, confirmed the success of their modification. These polymers were mixed, varying the protein concentration and, subsequently, bio-orthogonally photo-crosslinked, using visible light and LAP as photoiniator, creating hydrogel cell-friendly networks. Rheological characterization affirmed the chemistry’s potential in rapidly gelling networks (t < 20 s) achieving an elastic modulus, G’, of approximately 104 Pa, highlighting its suitability for 3D printing applications. Moreover, the mechanical characterization of the hydrogels revealed that those containing higher BSA-SH concentration were more robust, indicating the presence of more crosslinking points, as expected. The mechanical and rheological properties of the inks enabled 3D extrusion printing. Additionally, direct and indirect contact of hASCs with the materials through seeding, confirmed their cytocompatibility and non-toxicity, maintaining cell viability up to 14 days, which was assessed through fluorescence microscopy images and metabolic activity. Therefore, HA-Nor/BSA-SH and HA-Nor/hPL-SH inks are expected to be promising future bioinks for regenerative medicine and tissue engineering of soft tissues, opening avenues for personalized medicine.Na última década, a impressão 3D tem vindo a ganhar uma popularidade crescente, sendo uma técnica capaz de produzir estruturas bem definidas semelhantes aos tecidos nativos. Uma das suas características mais atrativas é a capacidade de permitir terapias personalizadas para atender às necessidades específicas de cada paciente. No entanto, desafios, incluindo a seleção de materiais, bem como de estratégias de reticulação, precisam de ser abordados, de modo a melhorar as características das tintas e simultaneamente criar biomateriais imprimíveis, robustos e citocompatíveis. Assim, este estudo foca-se no desenvolvimento de tintas “fotoclicáveis” à base de polímeros naturais, compostas por ácido hialurónico (HA) e proteínas [albumina do soro bovino (BSA) e lisados de plaquetas humanas (hPL)] para impressão 3D por extrusão, tirando partido da versatilidade, eficiência e cinética rápida da química de click tiol-eno. Para este fim, o HA foi modificado com grupos funcionais norborneno (HA-Nor) e as proteínas foram tioladas (BSA-SH e hPL-SH). As análises de 1HNMR e ATR-FTIR dos polímeros resultantes, HA-Nor, BSA-SH e hPL-SH, confirmaram o sucesso da modificação dos mesmos. Estes polímeros foram misturados variando a concentração de proteína e, posteriormente, fotoreticulados bio-ortogonalmente usando luz visível e LAP como fotoiniciador, criando redes de hidrogel favoráveis às células. A caracterização reológica afirmou o potencial da química na gelificação rápida de redes interconectadas (t <20 s), atingindo um módulo elástico, G', de aproximadamente 104 Pa, destacando a sua adequação para aplicações de impressão 3D. Adicionalmente, a caracterização mecânica dos hidrogéis revelou que aqueles contendo maior teor de BSA-SH eram mais robustos, indicando a presença de mais pontos de reticulação, tal como esperado. As propriedades mecânicas e reológicas das tintas permitiram a impressão 3D por extrusão. Além disso, o contacto direto e indireto de hASCs com os materiais por meio de semeadura, confirmou a sua citocompatibilidade e a sua não toxicidade, mantendo a viabilidade celular durante 14 dias, que foi avaliada por meio de imagens de microscopia de fluorescência e atividade metabólica. Assim, espera-se que as tintas HA-Nor/BSA-SH e HA-Nor/hPL-SH sejam biotintas futuras promissoras para aplicação na medicina regenerativa e engenharia de tecidos moles, abrindo caminho em direção à medicina personalizada.2025-12-21T00:00:00Z2023-12-13T00:00:00Z2023-12-13info:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/masterThesisapplication/pdfhttp://hdl.handle.net/10773/44617engMalafaia, Andreia Isabel Pinhoinfo:eu-repo/semantics/embargoedAccessreponame:Repositórios Científicos de Acesso Aberto de Portugal (RCAAP)instname:FCCN, serviços digitais da FCT – Fundação para a Ciência e a Tecnologiainstacron:RCAAP2025-03-31T01:53:18Zoai:ria.ua.pt:10773/44617Portal AgregadorONGhttps://www.rcaap.pt/oai/openaireinfo@rcaap.ptopendoar:https://opendoar.ac.uk/repository/71602025-05-29T04:43:07.573196Repositórios Científicos de Acesso Aberto de Portugal (RCAAP) - FCCN, serviços digitais da FCT – Fundação para a Ciência e a Tecnologiafalse |
| dc.title.none.fl_str_mv |
Photoclickable inks: 3D printing intelligent gelling systems with biomedical applications |
| title |
Photoclickable inks: 3D printing intelligent gelling systems with biomedical applications |
| spellingShingle |
Photoclickable inks: 3D printing intelligent gelling systems with biomedical applications Malafaia, Andreia Isabel Pinho Biofabrication 3D printing Inks Hydrogels Photocrosslinking Thiol-ene click chemistry |
| title_short |
Photoclickable inks: 3D printing intelligent gelling systems with biomedical applications |
| title_full |
Photoclickable inks: 3D printing intelligent gelling systems with biomedical applications |
| title_fullStr |
Photoclickable inks: 3D printing intelligent gelling systems with biomedical applications |
| title_full_unstemmed |
Photoclickable inks: 3D printing intelligent gelling systems with biomedical applications |
| title_sort |
Photoclickable inks: 3D printing intelligent gelling systems with biomedical applications |
| author |
Malafaia, Andreia Isabel Pinho |
| author_facet |
Malafaia, Andreia Isabel Pinho |
| author_role |
author |
| dc.contributor.author.fl_str_mv |
Malafaia, Andreia Isabel Pinho |
| dc.subject.por.fl_str_mv |
Biofabrication 3D printing Inks Hydrogels Photocrosslinking Thiol-ene click chemistry |
| topic |
Biofabrication 3D printing Inks Hydrogels Photocrosslinking Thiol-ene click chemistry |
| description |
Over the past decade, 3D printing has gained increasing popularity, being a technique capable of producing well-defined tissue-like structures. One of its most appealing features is the ability to create personalized therapies to meet the specific demands of individual patients. However, challenges including the selection of materials, as well as crosslinking strategies still need to be addressed, in order to enhance the inks characteristics and simultaneously create printable, robust, and cytocompatible biomaterials. Hence, this study reports the development of natural-based photoclickable inks, composed of hyaluronic acid (HA) and proteins [bovine serum albumin (BSA) and human platelet lysates (hPL)] for 3D extrusion printing, taking advantage of the versatility, efficiency, and fast kinetics of thiol-ene click chemistry. To this end, HA was modified with norbornene (HA-Nor) moieties, while proteins were thiolated (BSA-SH and hPL-SH). 1H-NMR and ATR-FTIR analysis of the resulting polymers, HA-Nor, BSA-SH and hPL-SH, confirmed the success of their modification. These polymers were mixed, varying the protein concentration and, subsequently, bio-orthogonally photo-crosslinked, using visible light and LAP as photoiniator, creating hydrogel cell-friendly networks. Rheological characterization affirmed the chemistry’s potential in rapidly gelling networks (t < 20 s) achieving an elastic modulus, G’, of approximately 104 Pa, highlighting its suitability for 3D printing applications. Moreover, the mechanical characterization of the hydrogels revealed that those containing higher BSA-SH concentration were more robust, indicating the presence of more crosslinking points, as expected. The mechanical and rheological properties of the inks enabled 3D extrusion printing. Additionally, direct and indirect contact of hASCs with the materials through seeding, confirmed their cytocompatibility and non-toxicity, maintaining cell viability up to 14 days, which was assessed through fluorescence microscopy images and metabolic activity. Therefore, HA-Nor/BSA-SH and HA-Nor/hPL-SH inks are expected to be promising future bioinks for regenerative medicine and tissue engineering of soft tissues, opening avenues for personalized medicine. |
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2023 |
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2023-12-13T00:00:00Z 2023-12-13 2025-12-21T00:00:00Z |
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