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You are researching: Hepatocytes
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Skin Tissue Engineering
Drug Delivery
Biological Molecules
Solid Dosage Drugs
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AUTHOR
Title
Bioprinting of Perfusable Vascularized Organ Models for Drug Development via Sacrificial-Free Direct Ink Writing
[Abstract]
Year
2024
Journal/Proceedings
Advanced Functional Materials
Reftype
DOI/URL
DOI
Groups
AbstractAbstract 3D bioprinting enables the fabrication of human organ models that can be used for various fields of biomedical research, including oncology and infection biology. An important challenge, however, remains the generation of vascularized, perfusable 3D models that closely simulate natural physiology. Here, a novel direct ink writing (DIW) approach is described that can produce vascularized organ models without using sacrificial materials during fabrication. The high resolution of the method allows the one-step generation of various sophisticated hollow geometries. This sacrificial-free DIW (SF-DIW) approach is used to fabricate hepatic metastasis models of various cancer types and different formats for investigating the cytostatic activity of anti-cancer drugs. To this end, the models are incorporated into a newly developed perfusion system with integrated micropumps and an agar casting step that improves the physiological features of the bioprinted tissues. It is shown that the hepatic environment of the tumor models is capable of activating a prodrug, which inhibits breast cancer growth. This versatile SF-DIW approach is able to fabricate complicated perfusable constructs or microfluidic chips in a straightforward and cost-efficient manner. It can also be easily adapted to other cell types for generating vascularized organ tissues or cancer models that may support the development of new therapeutics.
AUTHOR
Title
Evaluation of allylated gelatin as a bioink supporting spontaneous spheroid formation of HepG2 cells
[Abstract]
Year
2024
Journal/Proceedings
International Journal of Biological Macromolecules
Reftype
Groups
AbstractThe spheroid culture system has gained significant attention as an effective in vitro model to mimic the in vivo microenvironment. Even though numerous studies were focused on developing spheroids, the structural organization of encapsulated cells within hydrogels remains a challenge. Allylated gelatin or GelAGE is used as a bioink due to its excellent physicochemical properties. In this study, GelAGE was evaluated for its capacity to induce spontaneous spheroid formation in encapsulated HepG2 cells. GelAGE was synthesized and characterized using 1HNMR spectroscopy and ninhydrin assay. Then the physicochemical and biological attributes of GelAGE hydrogel was examined. The results demonstrate that GelAGE has remarkable ability to induce the encapsulated cells to self-organize into spheroids.
AUTHOR
Title
Man vs. machine: Automated bioink mixing device improves reliability and reproducibility of bioprinting results compared to human operators
Year
2024
Journal/Proceedings
IJB
Reftype
DOI/URL
DOI
AUTHOR
Title
Silymarin enriched gelatin methacrylamide bioink imparts hepatoprotectivity to 3D bioprinted liver construct against carbon tetrachloride induced toxicity
[Abstract]
Year
2024
Journal/Proceedings
European Journal of Pharmaceutics and Biopharmaceutics
Reftype
Groups
AbstractThree-dimensional liver bioprinting is an emerging technology in the field of regenerative medicine that aids in the creation of functional tissue constructs that can be used as transplantable organ substitutes. During transplantation, the bioprinted donor liver must be protected from the oxidative stress environment created by various factors during the transplantation procedure, as well as from drug-induced damage from medications taken as part of the post-surgery medication regimen following the procedure. In this study, Silymarin, a flavonoid with the hepatoprotective properties were introduced into the GelMA bioink formulation to protect the bioprinted liver against hepatotoxicity. The concentration of silymarin to be added in GelMA was optimised, bioink properties were evaluated, and HepG2 cells were used to bioprint liver tissue. Carbon tetrachloride (CCl4) was used to induce hepatotoxicity in bioprinted liver, and the effect of this chemical on the metabolic activities of HepG2 cells was studied. The results showed that Silymarin helps with albumin synthesis and shields liver tissue from the damaging effects of CCl4. According to gene expression analysis, CCl4 treatment increased TNF-α and the antioxidant enzyme SOD expression in HepG2 cells while the presence of silymarin protected the bioprinted construct from CCl4-induced damage. Thus, the outcomes demonstrate that the addition of silymarin in GelMA formulation protects liver function in toxic environments.
AUTHOR
Title
Biocompatibility evaluation of antioxidant cocktail loaded gelatin methacrylamide as bioink for extrusion-based 3D bioprinting
[Abstract]
Year
2023
Journal/Proceedings
Biomedical Materials
Reftype
DOI/URL
DOI
Groups
AbstractThree-dimensional (3D) liver bioprinting is a promising technique for creating 3D liver models that can be used for in vitro drug testing, hepatotoxicity studies, and transplantation. The functional performance of 3D bioprinted liver constructs are limited by the lack of cell–cell interactions, which calls for the creation of bioprinted tissue constructs with high cell densities. This study reports the fabrication of 3D bioprinted liver constructs using a novel photocrosslinkable gelatin methacrylamide (GelMA)-based bioink formulation. However, the formation of excess free radicals during photoinitiation poses a challenge, particularly during photocrosslinking of large constructs with high cell densities. Hence, we designed a bioink formulation comprising the base polymer GelMA loaded with an antioxidant cocktail containing vitamin C (L-ascorbic acid (AA)) and vitamin E (α-tocopherol (α-Toc)). We confirmed that the combination of antioxidants loaded in GelMA enhanced the ability to scavenge intracellular reactive oxygen species formed during photocrosslinking. The GelMA formulation was evaluated for biocompatibility in vitro and in vivo. These results demonstrated that the bioink had adequate rheological characteristics and was biocompatible. Furthermore, when compared to bioprinted constructs with lower cell density, high-density primary rat hepatocyte constructs demonstrated improved cell-cell interactions and liver-specific functions like albumin and urea secretion, which increased 5-fold and 2.5-fold, respectively.
