Your search keyword '"3D bioprinting"' showing total 616 results

1. Three-Dimensional-Bioprinted Non-Small Cell Lung Cancer Models in a Mouse Phantom for Radiotherapy Research.

Author

Mei, Yikun, Lakotsenina, Elena, Wegner, Marie, Hehne, Timon, Krause, Dieter, Hakimeh, Dani, Wu, Dongwei, Schültke, Elisabeth, Hausmann, Franziska, Kurreck, Jens, and Tolksdorf, Beatrice

Subjects

*NON-small-cell lung carcinoma, *BIOPRINTING, *LABORATORY mice, *LUNG cancer, *OVERALL survival

Abstract

Lung cancer continues to have one of the highest morbidity and mortality rates of any cancer. Although radiochemotherapy, in combination with immunotherapy, has significantly improved overall survival, new treatment options are urgently needed. However, preclinical radiotherapy testing is often performed in animal models, which has several drawbacks, including species-specific differences and ethical concerns. To replace animal models, this study used a micro-extrusion bioprinting approach to generate a three-dimensional (3D) human lung cancer model consisting of lung tumor cells embedded in human primary lung fibroblasts for radiotherapy research. The models were placed in a mouse phantom, i.e., a 3D-printed mouse model made of materials that mimic the X-ray radiation attenuation rates found in mice. In radiotherapy experiments, the model demonstrated a selective cytotoxic effect of X-rays on tumor cells, consistent with findings in 2D cells. Furthermore, the analysis of metabolic activity, cell death, apoptosis, and DNA damage-induced γH2AX foci formation revealed different results in the 3D model inside the phantom compared to those observed in irradiated models without phantom and 2D cells. The proposed setup of the bioprinted 3D lung model inside the mouse phantom provides a physiologically relevant model system to study radiation effects. [ABSTRACT FROM AUTHOR]

Published

2024

2. Gel-Based Suspension Medium Used in 3D Bioprinting for Constructing Tissue/Organ Analogs.

Author

Luo, Yang, Xu, Rong, Hu, Zeming, Ni, Renhao, Zhu, Tong, Zhang, Hua, and Zhu, Yabin

Subjects

BIOPRINTING, GELLAN gum, GEOMETRIC shapes, CELL anatomy, CELL survival

Abstract

Constructing tissue/organ analogs with natural structures and cell types in vitro offers a valuable strategy for the in situ repair of damaged tissues/organs. Three-dimensional (3D) bioprinting is a flexible method for fabricating these analogs. However, extrusion-based 3D bioprinting faces the challenge of balancing the use of soft bioinks with the need for high-fidelity geometric shapes. To address these challenges, recent advancements have introduced various suspension mediums based on gelatin, agarose, and gellan gum microgels. The emergence of these gel-based suspension mediums has significantly advanced the fabrication of tissue/organ constructs using 3D bioprinting. They effectively stabilize and support soft bioinks, enabling the formation of complex spatial geometries. Moreover, they provide a stable, cell-friendly environment that maximizes cell viability during the printing process. This minireview will summarize the properties, preparation methods, and potential applications of gel-based suspension mediums in constructing tissue/organ analogs, while also addressing current challenges and providing an outlook on the future of 3D bioprinting. [ABSTRACT FROM AUTHOR]

Published

2024

3. Improvement of Mechanical Properties of 3D Bioprinted Structures through Cellular Overgrowth.

Author

Wierzbicka, Adrianna, Bartniak, Mateusz, Grabarczyk, Jacek, Biernacka, Nikola, Aftyka, Mateusz, Wójcik, Tomasz, and Bociaga, Dorota

Subjects

BIOPRINTING, BIOMATERIALS, POLYMER solutions, POLYMER degradation, RHEOLOGY, CELL culture, SODIUM alginate, GELATIN

Abstract

The common use of hydrogel materials in 3D bioprinting techniques is dictated by the unique properties of hydrogel bioinks, among which some of the most important in terms of sustaining vital cell functions in vitro in 3D cultures are the ability to retain large amounts of liquid and the ability to modify rigidity and mechanical properties to reproduce the structure of the natural extracellular matrix. Due to their high biocompatibility, non-immunogenicity, and the possibility of optimizing rheological properties and bioactivity at the same time, one of the most commonly used hydrogel bioink compositions are polymer solutions based on sodium alginate and gelatin. In 3D bioprinting techniques, it is necessary for hydrogel printouts to feature an appropriate geometry to ensure proper metabolic activity of the cells contained inside the printouts. The desired solution is to obtain a thin-walled printout geometry, ensuring uniform nutrient availability and gas exchange during cultivation. Within this study's framework, tubular bioprinted structures were developed based on sodium alginate and gelatin, containing cells of the immortalized fibroblast line NIH/3T3 in their structure. Directly after the 3D printing process, such structures are characterized by extremely low mechanical strength. The purpose of this study was to perform a comparative analysis of the viability and spreading ability of the biological material contained in the printouts during their incubation for a period of 8 weeks while monitoring the effect of cellular growth on changes in the mechanical properties of the tubular structures. The observations demonstrated that the cells contained in the 3D printouts reach the ability to grow and spread in the polymer matrix after 4 weeks of cultivation, leading to obtaining a homogeneous, interconnected cell network inside the hydrogel after 6 weeks of incubation. Analysis of the mechanical properties of the printouts indicates that with the increasing time of cultivation of the structures, the degree of their overgrowth by the biological material contained inside, and the progressive degradation of the polymer matrix process, the tensile strength of tubular 3D printouts varies. [ABSTRACT FROM AUTHOR]

Published

2024

4. 3D-Printable Gelatin Methacrylate-Xanthan Gum Hydrogel Bioink Enabling Human Induced Pluripotent Stem Cell Differentiation into Cardiomyocytes.

Author

Deidda, Virginia, Ventisette, Isabel, Langione, Marianna, Giammarino, Lucrezia, Pioner, Josè Manuel, Credi, Caterina, and Carpi, Federico

Subjects

BIOPRINTING, PLURIPOTENT stem cells, XANTHAN gum, TISSUE engineering, THREE-dimensional printing, CELL culture

Abstract

We describe the development of a bioink to bioprint human induced pluripotent stem cells (hiPSCs) for possible cardiac tissue engineering using a gelatin methacrylate (GelMA)-based hydrogel. While previous studies have shown that GelMA at a low concentration (5% w/v) allows for the growth of diverse cells, its 3D printability has been found to be limited by its low viscosity. To overcome that drawback, making the hydrogel both compatible with hiPSCs and 3D-printable, we developed an extrudable GelMA-based bioink by adding xanthan gum (XG). The GelMA-XG composite hydrogel had an elastic modulus (~9 kPa) comparable to that of cardiac tissue, and enabled 3D printing with high values of printing accuracy (83%) and printability (0.98). Tests with hiPSCs showed the hydrogel's ability to promote their proliferation within both 2D and 3D cell cultures. The tests also showed that hiPSCs inside hemispheres of the hydrogel were able to differentiate into cardiomyocytes, capable of spontaneous contractions (average frequency of ~0.5 Hz and amplitude of ~2%). Furthermore, bioprinting tests proved the possibility of fabricating 3D constructs of the hiPSC-laden hydrogel, with well-defined line widths (~800 μm). [ABSTRACT FROM AUTHOR]

Published

2024

5. The Utilization of Central Composite Design for the Production of Hydrogel Blends for 3D Printing.

Author

Araujo, Thalita Fonseca and Silva, Luciano Paulino

Subjects

BIOPRINTING, CARBOXYMETHYLCELLULOSE, THREE-dimensional printing, DESIGN techniques, BIOPOLYMERS

Abstract

Central composite design (CCD) is a statistical experimental design technique that utilizes a combination of factorial and axial points to study the effects of multiple variables on a response. This study focused on optimizing hydrogel formulations for 3D printing using CCD. Three biopolymers were selected: sodium alginate (SA), gelatin (GEL), and carboxymethyl cellulose (CMC). The maximum and minimum concentrations of each polymer were established using a Google Scholar search, and CCD was employed to generate various combinations for hydrogel preparation. The hydrogels were characterized in accordance with their swelling degree (SD) in phosphate-buffered saline (PBS) and Dulbecco's Modified Eagle Medium (DMEM), as well as their printability in 2D and 3D assays. The formulation consisting of 7.5% SA, 7.5% GEL, and 2.5% CMC exhibited the best swelling properties and exceptional printability, surpassing all other tested formulations. This study highlights the effectiveness of design of experiment methodologies in accelerating the development of optimized hydrogel formulations for various applications in 3D printing and suggests avenues for future research to explore their performance in specific biological contexts. [ABSTRACT FROM AUTHOR]

Published

2024

6. Exploring the Frontier of 3D Bioprinting for Tendon Regeneration: A Review.

Author

Rosset, Josée, Olaniyanu, Emmanuel, Stein, Kevin, Almeida, Nátaly Domingues, and França, Rodrigo

Subjects

*BIOPRINTING, *TENDON injuries, *TENDONS, *FUNCTIONAL status, *QUALITY of life

Abstract

The technology of 3D bioprinting has sparked interest in improving tendon repair and regeneration, promoting quality of life. To perform this procedure, surgical intervention is often necessary to restore functional capacity. In this way, 3D bioprinting offers a scaffold design, producing tendons with precise microarchitectures, promoting the growth of new tissues. Furthermore, it may incorporate bioactive compounds that can further stimulate repair. This review elucidates how 3D bioprinting holds promise for tendon repair and regeneration, detailing the steps involved and the various approaches employed. They demonstrate future challenges and perspectives and provide valuable information on the concept, bioprinting design, and 3D bioprinting techniques for the repair of tendon injuries. [ABSTRACT FROM AUTHOR]

Published

2024

7. 3D Models Currently Proposed to Investigate Human Skin Aging and Explore Preventive and Reparative Approaches: A Descriptive Review.

Author

Lombardi, Francesca, Augello, Francesca Rosaria, Ciafarone, Alessia, Ciummo, Valeria, Altamura, Serena, Cinque, Benedetta, and Palumbo, Paola

Subjects

*BIOPRINTING, *TECHNOLOGICAL innovations, *SKIN aging, *EXTRACELLULAR matrix, *TRANSLATIONAL research, *FIBROBLASTS

Abstract

Skin aging is influenced by intrinsic and extrinsic factors that progressively impair skin functionality over time. Investigating the skin aging process requires thorough research using innovative technologies. This review explores the use of in vitro human 3D culture models, serving as valuable alternatives to animal ones, in skin aging research. The aim is to highlight the benefits and necessity of improving the methodology in analyzing the molecular mechanisms underlying human skin aging. Traditional 2D models, including monolayers of keratinocytes, fibroblasts, or melanocytes, even if providing cost-effective and straightforward methods to study critical processes such as extracellular matrix degradation, pigmentation, and the effects of secretome on skin cells, fail to replicate the complex tissue architecture with its intricated interactions. Advanced 3D models (organoid cultures, "skin-on-chip" technologies, reconstructed human skin, and 3D bioprinting) considerably enhance the physiological relevance, enabling a more accurate representation of skin aging and its peculiar features. By reporting the advantages and limitations of 3D models, this review highlights the importance of using advanced in vitro systems to develop practical anti-aging preventive and reparative approaches and improve human translational research in this field. Further exploration of these technologies will provide new opportunities for previously unexplored knowledge on skin aging. [ABSTRACT FROM AUTHOR]

Published

2024

8. Advances in 3D Bioprinting for Neuroregeneration: A Literature Review of Methods, Bioinks, and Applications.

Author

Islam, Abrar, Vakitbilir, Nuray, Almeida, Nátaly, and França, Rodrigo

Subjects

PARAMETERS (Statistics), MICROSTRUCTURE, SURFACE morphology, THREE-dimensional printing

Abstract

Recent advancements in 3D-bioprinting technology have sparked a growing interest in its application for brain repair, encompassing tissue regeneration, drug delivery, and disease modeling. This literature review examines studies conducted over the past five years to assess the current state of research in this field. Common bioprinting methods and key parameters influencing their selection are explored, alongside an analysis of the diverse types of bioink utilized and their associated parameters. The extrusion-based 3D-bioprinting method emerged as the most widely studied and popular topic, followed by inkjet-based and laser-based bioprinting and stereolithography. Regarding bioinks, fibrin-based and collagen-based bioinks are predominantly utilized. Furthermore, this review elucidates how 3D bioprinting holds promise for neural tissue repair, regeneration, and drug screening, detailing the steps involved and various approaches employed. Neurovascular 3D printing and bioscaffold 3D printing stand out as the top two preferred methods for brain repair. The recent studies' shortcomings and potential solutions to address them are also examined and discussed. Overall, by synthesizing recent findings, this review provides valuable insights into the potential of 3D bioprinting for advancing brain repairment strategies. [ABSTRACT FROM AUTHOR]

Published

2024

9. The Prospect of Hepatic Decellularized Extracellular Matrix as a Bioink for Liver 3D Bioprinting.

Author

Shi, Wen, Zhang, Zhe, and Wang, Xiaohong

Subjects

*BIOPRINTING, *HEPATIC fibrosis, *REGENERATIVE medicine, *CIRRHOSIS of the liver, *EXTRACELLULAR matrix

Abstract

The incidence of liver diseases is high worldwide. Many factors can cause liver fibrosis, which in turn can lead to liver cirrhosis and even liver cancer. Due to the shortage of donor organs, immunosuppression, and other factors, only a few patients are able to undergo liver transplantation. Therefore, how to construct a bioartificial liver that can be transplanted has become a global research hotspot. With the rapid development of three-dimensional (3D) bioprinting in the field of tissue engineering and regenerative medicine, researchers have tried to use various 3D bioprinting technologies to construct bioartificial livers in vitro. In terms of the choice of bioinks, liver decellularized extracellular matrix (dECM) has many advantages over other materials for cell-laden hydrogel in 3D bioprinting. This review mainly summarizes the acquisition of liver dECM and its application in liver 3D bioprinting as a bioink with respect to availability, printability, and biocompatibility in many aspects and puts forward the current challenges and prospects. [ABSTRACT FROM AUTHOR]

Published

2024

10. Three-Dimensional Bioprinting: A Comprehensive Review for Applications in Tissue Engineering and Regenerative Medicine.

Author

Mirsky, Nicholas A., Ehlen, Quinn T., Greenfield, Jason A., Antonietti, Michael, Slavin, Blaire V., Nayak, Vasudev Vivekanand, Pelaez, Daniel, Tse, David T., Witek, Lukasz, Daunert, Sylvia, and Coelho, Paulo G.

Subjects

*BIOPRINTING, *REGENERATIVE medicine, *THREE-dimensional printing, *TISSUE engineering, *CLINICAL medicine, *ARTIFICIAL implants, *ORTHOPEDIC surgery

Abstract

Since three-dimensional (3D) bioprinting has emerged, it has continuously to evolved as a revolutionary technology in surgery, offering new paradigms for reconstructive and regenerative medical applications. This review highlights the integration of 3D printing, specifically bioprinting, across several surgical disciplines over the last five years. The methods employed encompass a review of recent literature focusing on innovations and applications of 3D-bioprinted tissues and/or organs. The findings reveal significant advances in the creation of complex, customized, multi-tissue constructs that mimic natural tissue characteristics, which are crucial for surgical interventions and patient-specific treatments. Despite the technological advances, the paper introduces and discusses several challenges that remain, such as the vascularization of bioprinted tissues, integration with the host tissue, and the long-term viability of bioprinted organs. The review concludes that while 3D bioprinting holds substantial promise for transforming surgical practices and enhancing patient outcomes, ongoing research, development, and a clear regulatory framework are essential to fully realize potential future clinical applications. [ABSTRACT FROM AUTHOR]

Published

2024

11. Biomechanical Properties and Cellular Responses in Pulmonary Fibrosis.

Author

He, Andong, He, Lizhe, Chen, Tianwei, Li, Xuejin, and Cao, Chao

Subjects

*LUNGS, *PULMONARY fibrosis, *BIOPRINTING, *ETIOLOGY of diseases, *TISSUE mechanics, *LUNG transplantation, *SELF-healing materials

Abstract

Pulmonary fibrosis is a fatal lung disease affecting approximately 5 million people worldwide, with a 5-year survival rate of less than 50%. Currently, the only available treatments are palliative care and lung transplantation, as there is no curative drug for this condition. The disease involves the excessive synthesis of the extracellular matrix (ECM) due to alveolar epithelial cell damage, leading to scarring and stiffening of the lung tissue and ultimately causing respiratory failure. Although multiple factors contribute to the disease, the exact causes remain unclear. The mechanical properties of lung tissue, including elasticity, viscoelasticity, and surface tension, are not only affected by fibrosis but also contribute to its progression. This paper reviews the alteration in these mechanical properties as pulmonary fibrosis progresses and how cells in the lung, including alveolar epithelial cells, fibroblasts, and macrophages, respond to these changes, contributing to disease exacerbation. Furthermore, it highlights the importance of developing advanced in vitro models, based on hydrogels and 3D bioprinting, which can accurately replicate the mechanical and structural properties of fibrotic lungs and are conducive to studying the effects of mechanical stimuli on cellular responses. This review aims to summarize the current understanding of the interaction between the progression of pulmonary fibrosis and the alterations in mechanical properties, which could aid in the development of novel therapeutic strategies for the disease. [ABSTRACT FROM AUTHOR]

Published

2024

12. The Impact of Gelatin and Fish Collagen on Alginate Hydrogel Properties: A Comparative Study.

Author

Wierzbicka, Adrianna, Bartniak, Mateusz, Waśko, Joanna, Kolesińska, Beata, Grabarczyk, Jacek, and Bociaga, Dorota

Subjects

SODIUM alginate, GELATIN, COLLAGEN, BIOPRINTING, ALGINATES, ALGINIC acid, POLYMER solutions, HYDROGELS, PRION diseases

Abstract

Hydrogel materials based on sodium alginate find versatile applications in regenerative medicine and tissue engineering due to their unique properties, such as biocompatibility and biodegradability, and the possibility of the customization of their mechanical properties, such as in terms of the individual requirements of separate clinical applications. These materials, however, have numerous limitations in the area of biological activity. In order to eliminate their limitations, sodium alginate is popularly applied in combination with added gelatin, which represents a product of collagen hydrolysis. Despite numerous beneficial biological properties, matrix materials based on gelatin have poor mechanical properties and are characterized by their ability for rapid degradation in an aqueous environment, particularly at the physiological temperature of the body, which significantly limits the independent application opportunities of this type of composition in the range of scaffolding production dedicated for tissue engineering. Collagen hydrogels, unlike gelatin, are characterized by higher bioactivity, dictated by a greater number of ligands that allow for cell adhesion, as well as better stability under physiological conditions. Fish-derived collagen provides a material that may be efficiently extracted without the risk of mammalian prion infection and can be used in all patients without religious restrictions. Considering the numerous advantages of collagen indicating its superiority over gelatin, within the framework of this study, the compositions of hydrogel materials based on sodium alginate and fish collagen in different concentrations were developed. Prepared hydrogel materials were compared with the properties of a typical composition of alginate with the addition of gelatin. The rheological, mechanical, and physicochemical properties of the developed polymer compositions were evaluated. The first trials of 3D printing by extrusion technique using the analyzed polymer solutions were also conducted. The results obtained indicate that replacing gelatin with fish collagen at an analogous concentration leads to obtaining materials with a lower swelling degree, better mechanical properties, higher stability, limited release kinetics of calcium ions cross-linking the alginate matrix, a slowed process of protein release under physiological conditions, and the possibility of extrusion 3D printing. The conducted analysis highlights that the optimization of the applied concentrations of fish collagen additives to composition based on sodium alginate creates the possibility of designing materials with appropriate mechanical and rheological properties and degradation kinetics adjusted to the requirements of specific applications, leading to the prospective opportunity to produce materials capable of mimicking the properties of relevant soft tissues. Thanks to its excellent bioactivity and lower-than-gelatin viscosity of the polymer solution, fish collagen also provides a prospective solution for applications in the field of 3D bioprinting. [ABSTRACT FROM AUTHOR]

Published

2024

13. Integrating Pneumatic and Thermal Control in 3D Bioprinting for Improved Bio-Ink Handling.

Author

Woods, Perrin, Smith, Carter, Clark, Scott, and Habib, Ahasan

Subjects

BIOPRINTING, TISSUE engineering, REQUIREMENTS engineering, PNEUMATIC control, CHEMICAL stability, 3-D printers

Abstract

The rapid advancement of 3D bioprinting has created a need for cost-effective and versatile 3D printers capable of handling bio-inks at various scales. This study introduces a novel framework for a specialized nozzle-holding device designed for an extrusion-based 3D bioprinter, specifically tailored to address the rigorous requirements of tissue engineering applications. The proposed system combines a pneumatically actuated plunger mechanism with an adaptive nozzle system, ensuring the safe inhibition and precise dispensing of bio-inks. Rigorous thermal management strategies are employed to maintain consistently low temperatures, thereby preserving bio-ink integrity without changing chemical stability. A key component of this design is a precision-milled aluminum block, which optimizes thermal characteristics while providing a protective barrier. Additionally, a 3D-printed extruder head bracket, fabricated using a high-precision resin printer, effectively mitigates potential thermal inconsistencies. The integration of these meticulously engineered components results in a modified extrusion-based 3D bioprinter with the potential to significantly advance tissue engineering methodologies. This study not only contributes to the advancement of bioprinting technology but also underscores the crucial role of innovative engineering in addressing tissue engineering challenges. The proposed bioprinter design lays a solid foundation for future research, aiming to develop more accurate, efficient, and reliable bioprinting solutions. [ABSTRACT FROM AUTHOR]

Published

2024

14. Research Progress in the Construction and Application of In Vitro Vascular Models.

Author

He, Zhenyu, Cheng, Pengpeng, Ying, Guoqing, and Ou, Zhimin

Subjects

BIOPRINTING, CARDIOVASCULAR system, BIOMEDICAL materials, SOFT lithography, DRUG stability

Abstract

The vascular system maintains cellular homeostasis by transporting oxygen, nutrients, and metabolic waste products. The vascular system is involved in a variety of fundamental physiological phenomena and is closely associated with human vascular diseases. Additionally, the stability of drugs in the vasculature affects their efficacy. Therefore, researchers have used vascular models to study vascular diseases, assess drug stability, and screen drugs. However, there are many shortcomings in the animal models and in vitro two-dimensional vascular models that have been extensively developed. In this paper, we specifically review the construction methods of in vitro vascular models and classify the specific methods into photolithography, soft lithography, self-assembly, template, 3D bioprinting, and laser degradation/cavitation. The first two are microfluidics-based methods and the last three are non-microfluidics-based methods. The vascular model construction methods reviewed in this paper overcome the shortcomings of traditional models—which cannot accurately reproduce the human vascular microenvironment—and can assist in the construction of in vitro 3D vascular models and tissue engineering vascularization. These models can be reused by perfusion devices, and the cells within the channels reside on biocompatible materials that are used to simulate the microenvironment and 3D cellular organization of the vasculature in vivo. In addition, these models are reproducible in shape and length, allowing experiments to be repeated, which is difficult to do with natural vessels. In vitro vascular models are widely used in research and drug screening for diseases associated with endothelial dysfunction, cancer, and other vascular abnormalities. [ABSTRACT FROM AUTHOR]

Published

2024

15. Mathematical Tools for Simulation of 3D Bioprinting Processes on High-Performance Computing Resources: The State of the Art.

Author

Carracciuolo, Luisa and D'Amora, Ugo

Subjects

BIOPRINTING, COMPUTER systems, PHYSICAL mobility, CELL survival, ENGINEERS

Abstract

Three-dimensional (3D) bioprinting belongs to the wide family of additive manufacturing techniques and employs cell-laden biomaterials. In particular, these materials, named "bioink", are based on cytocompatible hydrogel compositions. To be printable, a bioink must have certain characteristics before, during, and after the printing process. These characteristics include achievable structural resolution, shape fidelity, and cell survival. In previous centuries, scientists have created mathematical models to understand how physical systems function. Only recently, with the quick progress of computational capabilities, high-fidelity and high-efficiency "computational simulation" tools have been developed based on such models and used as a proxy for real-world learning. Computational science, or "in silico" experimentation, is the term for this novel strategy that supplements pure theory and experiment. Moreover, a certain level of complexity characterizes the architecture of contemporary powerful computational resources, known as high-performance computing (HPC) resources, also due to the great heterogeneity of its structure. Lately, scientists and engineers have begun to develop and use computational models more extensively to also better understand the bioprinting process, rather than solely relying on experimental research, due to the large number of possible combinations of geometrical parameters and material properties, as well as the abundance of available bioprinting methods. This requires a new effort in designing and implementing computational tools capable of efficiently and effectively exploiting the potential of new HPC computing systems available in the Exascale Era. The final goal of this work is to offer an overview of the models, methods, and techniques that can be used for "in silico" experimentation of the physicochemical processes underlying the process of 3D bioprinting of cell-laden materials thanks to the use of up-to-date HPC resources. [ABSTRACT FROM AUTHOR]

Published

2024

16. Advanced Hydrogels in Breast Cancer Therapy.

Author

Gao, Xiangyu, Caruso, Benjamin R., and Li, Weimin

Subjects

HYDROGELS in medicine, BREAST cancer treatment, BREAST cancer immunology, CANCER chemotherapy, DRUG delivery systems

Abstract

Breast cancer is the most common malignancy among women and is the second leading cause of cancer-related death for women. Depending on the tumor grade and stage, breast cancer is primarily treated with surgery and antineoplastic therapy. Direct or indirect side effects, emotional trauma, and unpredictable outcomes accompany these traditional therapies, calling for therapies that could improve the overall treatment and recovery experiences of patients. Hydrogels, biomimetic materials with 3D network structures, have shown great promise for augmenting breast cancer therapy. Hydrogel implants can be made with adipogenic and angiogenic properties for tissue integration. 3D organoids of malignant breast tumors grown in hydrogels retain the physical and genetic characteristics of the native tumors, allowing for post-surgery recapitulation of the diseased tissues for precision medicine assessment of the responsiveness of patient-specific cancers to antineoplastic treatment. Hydrogels can also be used as carrier matrices for delivering chemotherapeutics and immunotherapeutics or as post-surgery prosthetic scaffolds. The hydrogel delivery systems could achieve localized and controlled medication release targeting the tumor site, enhancing efficacy and minimizing the adverse effects of therapeutic agents delivered by traditional procedures. This review aims to summarize the most recent advancements in hydrogel utilization for breast cancer post-surgery tissue reconstruction, tumor modeling, and therapy and discuss their limitations in clinical translation. [ABSTRACT FROM AUTHOR]

Published

2024

17. Silk Fibroin-Enriched Bioink Promotes Cell Proliferation in 3D-Bioprinted Constructs.

Author

Lipari, Sara, Sacco, Pasquale, Marsich, Eleonora, and Donati, Ivan

Subjects

SILK fibroin, HYDROGELS, EXTRACELLULAR matrix, BIOPRINTING, CELL survival

Abstract

Three-dimensional (3D) bioprinting technology enables the controlled deposition of cells and biomaterials (i.e., bioink) to easily create complex 3D biological microenvironments. Silk fibroin (SF) has recently emerged as a compelling bioink component due to its advantageous mechanical and biological properties. This study reports on the development and optimization of a novel bioink for extrusion-based 3D bioprinting and compares different bioink formulations based on mixtures of alginate methacrylate (ALMA), gelatin and SF. The rheological parameters of the bioink were investigated to predict printability and stability, and the optimal concentration of SF was selected. The bioink containing a low amount of SF (0.002% w/V) was found to be the best formulation. Light-assisted gelation of ALMA was exploited to obtain the final hydrogel matrix. Rheological analyses showed that SF-enriched hydrogels exhibited greater elasticity than SF-free hydrogels and were more tolerant to temperature fluctuations. Finally, MG-63 cells were successfully bioprinted and their viability and proliferation over time were analyzed. The SF-enriched bioink represents an excellent biomaterial in terms of printability and allows high cell proliferation over a period of up to 3 weeks. These data confirm the possibility of using the selected formulation for the successful bioprinting of cells into extracellular matrix-like microenvironments. [ABSTRACT FROM AUTHOR]

Published

2024

18. Exploring Synergistic Effects of Bioprinted Extracellular Vesicles for Skin Regeneration.

Author

Taghdi, Manal Hussein, Muttiah, Barathan, Chan, Alvin Man Lung, Fauzi, Mh Busra, Law, Jia Xian, and Lokanathan, Yogeswaran

Subjects

BIOPRINTING, SKIN regeneration, SCIENTIFIC method, TREATMENT effectiveness, EXTRACELLULAR vesicles

Abstract

Regenerative medicine represents a paradigm shift in healthcare, aiming to restore tissue and organ function through innovative therapeutic strategies. Among these, bioprinting and extracellular vesicles (EVs) have emerged as promising techniques for tissue rejuvenation. EVs are small lipid membrane particles secreted by cells, known for their role as potent mediators of intercellular communication through the exchange of proteins, genetic material, and other biological components. The integration of 3D bioprinting technology with EVs offers a novel approach to tissue engineering, enabling the precise deposition of EV-loaded bioinks to construct complex three-dimensional (3D) tissue architectures. Unlike traditional cell-based approaches, bioprinted EVs eliminate the need for live cells, thereby mitigating regulatory and financial obstacles associated with cell therapy. By leveraging the synergistic effects of EVs and bioprinting, researchers aim to enhance the therapeutic outcomes of skin regeneration while addressing current limitations in conventional treatments. This review explores the evolving landscape of bioprinted EVs as a transformative approach for skin regeneration. Furthermore, it discusses the challenges and future directions in harnessing this innovative therapy for clinical applications, emphasizing the need for interdisciplinary collaboration and continued scientific inquiry to unlock its full therapeutic potential. [ABSTRACT FROM AUTHOR]

Published

2024

19. Three-Dimensional Printing in Breast Reconstruction: Current and Promising Applications.

Author

Mayer, Horacio F., Coloccini, Alejandro, and Viñas, José F.

Subjects

*THREE-dimensional printing, *TECHNOLOGICAL innovations, *THREE-dimensional imaging, *HUMAN anatomical models, *TISSUE scaffolds, *MAMMAPLASTY

Abstract

Three-dimensional (3D) printing is dramatically improving breast reconstruction by offering customized and precise interventions at various stages of the surgical process. In preoperative planning, 3D imaging techniques, such as computer-aided design, allow the creation of detailed breast models for surgical simulation, optimizing surgical outcomes and reducing complications. During surgery, 3D printing makes it possible to customize implants and precisely shape autologous tissue flaps with customized molds and scaffolds. This not only improves the aesthetic appearance, but also conforms to the patient's natural anatomy. In addition, 3D printed scaffolds facilitate tissue engineering, potentially favoring the development and integration of autologous adipose tissue, thus avoiding implant-related complications. Postoperatively, 3D imaging allows an accurate assessment of breast volume and symmetry, which is crucial in assessing the success of reconstruction. The technology is also a key educational tool, enhancing surgeon training through realistic anatomical models and surgical simulations. As the field evolves, the integration of 3D printing with emerging technologies such as biodegradable materials and advanced imaging promises to further refine breast reconstruction techniques and outcomes. This study aims to explore the various applications of 3D printing in breast reconstruction, addressing current challenges and future opportunities. [ABSTRACT FROM AUTHOR]

Published

2024

20. (3D) Bioprinting—Next Dimension of the Pharmaceutical Sector.

Author

Mihaylova, Anna, Shopova, Dobromira, Parahuleva, Nikoleta, Yaneva, Antoniya, and Bakova, Desislava

Subjects

*BIOPRINTING, *SCIENTIFIC literature, *CONTROLLED release drugs, *PHARMACEUTICAL industry, *CLINICAL drug trials, *BIOMATERIALS

Abstract

To create a review of the published scientific literature on the benefits and potential perspectives of the use of 3D bio-nitrification in the field of pharmaceutics. This work was performed in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines for reporting meta-analyses and systematic reviews. The scientific databases PubMed, Scopus, Google Scholar, and ScienceDirect were used to search and extract data using the following keywords: 3D bioprinting, drug research and development, personalized medicine, pharmaceutical companies, clinical trials, drug testing. The data points to several aspects of the application of bioprinting in pharmaceutics were reviewed. The main applications of bioprinting are in the development of new drug molecules as well as in the preparation of personalized drugs, but the greatest benefits are in terms of drug screening and testing. Growth in the field of 3D printing has facilitated pharmaceutical applications, enabling the development of personalized drug screening and drug delivery systems for individual patients. Bioprinting presents the opportunity to print drugs on demand according to the individual needs of the patient, making the shape, structure, and dosage suitable for each of the patient's physical conditions, i.e., print specific drugs for controlled release rates; print porous tablets to reduce swallowing difficulties; make transdermal microneedle patches to reduce patient pain; and so on. On the other hand, bioprinting can precisely control the distribution of cells and biomaterials to build organoids, or an Organ-on-a-Chip, for the testing of drugs on printed organs mimicking specified disease characteristics instead of animal testing and clinical trials. The development of bioprinting has the potential to offer customized drug screening platforms and drug delivery systems meeting a range of individualized needs, as well as prospects at different stages of drug development and patient therapy. The role of bioprinting in preclinical and clinical testing of drugs is also of significant importance in terms of shortening the time to launch a medicinal product on the market. [ABSTRACT FROM AUTHOR]

Published

2024

21. Formation of Stable Vascular Networks by 3D Coaxial Printing and Schiff-Based Reaction.

Author

Shan, Jingxin, Kong, Zhiyuan, and Wang, Xiaohong

Subjects

TRANSPLANTATION of organs, tissues, etc., HYDROGELS, BIOCOMPATIBILITY, RESEARCH & development, GELATIN

Abstract

Vascularized organs hold potential for various applications, such as organ transplantation, drug screening, and pathological model establishment. Nevertheless, the in vitro construction of such organs encounters many challenges, including the incorporation of intricate vascular networks, the regulation of blood vessel connectivity, and the degree of endothelialization within the inner cavities. Natural polymeric hydrogels, such as gelatin and alginate, have been widely used in three-dimensional (3D) bioprinting since 2005. However, a significant disparity exists between the mechanical properties of the hydrogel materials and those of human soft tissues, necessitating the enhancement of their mechanical properties through modifications or crosslinking. In this study, we aim to enhance the structural stability of gelatin–alginate hydrogels by crosslinking gelatin molecules with oxidized pullulan (i.e., a polysaccharide) and alginate molecules with calcium chloride (CaCl2). A continuous small-diameter vascular network with an average outer diameter of 1 mm and an endothelialized inner surface is constructed by printing the cell-laden hydrogels as bioinks using a coaxial 3D bioprinter. The findings demonstrate that the single oxidized pullulan crosslinked gelatin and oxidized pullulan/CaCl2 double-crosslinked gelatin–alginate hydrogels both exhibit a superior structural stability compared to their origins and CaCl2 solely crosslinked gelatin–alginate hydrogels. Moreover, the innovative gelatin and gelatin–alginate hydrogels, which have excellent biocompatibilities and very low prices compared with other hydrogels, can be used directly for tissue/organ construction, tissue/organ repairment, and cell/drug transportation. [ABSTRACT FROM AUTHOR]

Published

2024

22. Elasticity Modification of Biomaterials Used in 3D Printing with an Elastin–Silk-like Recombinant Protein.

Author

Cecuda-Adamczewska, Violetta, Romanik-Chruścielewska, Agnieszka, Kosowska, Katarzyna, Sokołowska, Iwona, Łukasiewicz, Natalia, Korycka, Paulina, Florys-Jankowska, Katarzyna, Zakrzewska, Agnieszka, Wszoła, Michał, and Klak, Marta

Subjects

RECOMBINANT proteins, THREE-dimensional printing, PHASE transitions, CYTOSKELETAL proteins, BIOPRINTING

Abstract

The recombinant structural protein described in this study was designed based on sequences derived from elastin and silk. Silk–elastin hybrid copolymers are characterized by high solubility while maintaining high product flexibility. The phase transition temperature from aqueous solution to hydrogel, as well as other physicochemical and mechanical properties of such particles, can differ significantly depending on the number of sequence repeats. We present a preliminary characterization of the EJ17zipR protein obtained in high yield in a prokaryotic expression system and efficiently purified via a multistep process. Its addition significantly improves biomaterial's rheological and mechanical properties, especially elasticity. As a result, EJ17zipR appears to be a promising component for bioinks designed to print spatially complex structures that positively influence both shape retention and the internal transport of body fluids. The results of biological studies indicate that the addition of the studied protein creates a favorable microenvironment for cell adhesion, growth, and migration. [ABSTRACT FROM AUTHOR]

Published

2024

23. Characterization of a Chimeric Resilin-Elastin Structural Protein Dedicated to 3D Bioprinting as a Bioink Component.

Author

Cecuda-Adamczewska, Violetta, Romanik-Chruścielewska, Agnieszka, Kosowska, Katarzyna, Łukasiewicz, Natalia, Sokołowska, Iwona, Korycka, Paulina, Florys-Jankowska, Katarzyna, Zakrzewska, Agnieszka, Wszoła, Michał, and Klak, Marta

Subjects

*BIOPRINTING, *CYTOSKELETAL proteins, *RECOMBINANT proteins, *ESCHERICHIA coli, *PROTEIN structure

Abstract

In this study we propose to use for bioprinting a bioink enriched with a recombinant RE15mR protein with a molecular weight of 26 kDa, containing functional sequences derived from resilin and elastin. The resulting protein also contains RGD sequences in its structure, as well as a metalloproteinase cleavage site, allowing positive interaction with the cells seeded on the construct and remodeling the structure of this protein in situ. The described protein is produced in a prokaryotic expression system using an E. coli bacterial strain and purified by a process using a unique combination of known methods not previously used for recombinant elastin-like proteins. The positive effect of RE15mR on the mechanical, physico-chemical, and biological properties of the print is shown in the attached results. The addition of RE15mR to the bioink resulted in improved mechanical and physicochemical properties and promoted the habitation of the prints by cells of the L-929 line. [ABSTRACT FROM AUTHOR]

Published

2024

24. Replace or Regenerate? Diverse Approaches to Biomaterials for Treating Corneal Lesions.

Author

Bonato, Pietro and Bagno, Andrea

Subjects

*BIOPRINTING, *TISSUES, *BIOMATERIALS, *REGENERATION (Biology), *VISION disorders, *FREE flaps, *CORNEA

Abstract

The inner structures of the eye are protected by the cornea, which is a transparent membrane exposed to the external environment and subjected to the risk of lesions and diseases, sometimes resulting in impaired vision and blindness. Several eye pathologies can be treated with a keratoplasty, a surgical procedure aimed at replacing the cornea with tissues from human donors. Even though the success rate is high (up to 90% for the first graft in low-risk patients at 5-year follow-up), this approach is limited by the insufficient number of donors and several clinically relevant drawbacks. Alternatively, keratoprosthesis can be applied in an attempt to restore minimal functions of the cornea: For this reason, it is used only for high-risk patients. Recently, many biomaterials of both natural and synthetic origin have been developed as corneal substitutes to restore and replace diseased or injured corneas in low-risk patients. After illustrating the traditional clinical approaches, the present paper aims to review the most innovative solutions that have been recently proposed to regenerate the cornea, avoiding the use of donor tissues. Finally, innovative approaches to biological tissue 3D printing and xenotransplantation will be mentioned. [ABSTRACT FROM AUTHOR]

Published

2024

25. Bioengineering Skin Substitutes for Wound Management—Perspectives and Challenges.

Author

Kondej, Karolina, Zawrzykraj, Małgorzata, Czerwiec, Katarzyna, Deptuła, Milena, Tymińska, Agata, and Pikuła, Michał

Subjects

*SKIN injuries, *BIOPRINTING, *DIABETIC foot, *CHRONIC wounds & injuries, *BIOENGINEERING, *SKIN ulcers, *SKIN regeneration

Abstract

Non-healing wounds and skin losses constitute significant challenges for modern medicine and pharmacology. Conventional methods of wound treatment are effective in basic healthcare; however, they are insufficient in managing chronic wound and large skin defects, so novel, alternative methods of therapy are sought. Among the potentially innovative procedures, the use of skin substitutes may be a promising therapeutic method. Skin substitutes are a heterogeneous group of materials that are used to heal and close wounds and temporarily or permanently fulfill the functions of the skin. Classification can be based on the structure or type (biological and synthetic). Simple constructs (class I) have been widely researched over the years, and can be used in burns and ulcers. More complex substitutes (class II and III) are still studied, but these may be utilized in patients with deep skin defects. In addition, 3D bioprinting is a rapidly developing method used to create advanced skin constructs and their appendages. The aforementioned therapies represent an opportunity for treating patients with diabetic foot ulcers or deep skin burns. Despite these significant developments, further clinical trials are needed to allow the use skin substitutes in the personalized treatment of chronic wounds. [ABSTRACT FROM AUTHOR]

Published

2024

26. Recent Advancements in Hydrogel Biomedical Research in Italy.

Author

Zanrè, Eleonora, Dalla Valle, Eva, D'Angelo, Edoardo, Sensi, Francesca, Agostini, Marco, and Cimetta, Elisa

Subjects

MEDICAL research, HYDROGELS in medicine, BIOMATERIALS, DRUG discovery, REGENERATIVE medicine

Abstract

Hydrogels have emerged as versatile biomaterials with remarkable applications in biomedicine and tissue engineering. Here, we present an overview of recent and ongoing research in Italy, focusing on extracellular matrix-derived, natural, and synthetic hydrogels specifically applied to biomedicine and tissue engineering. The analyzed studies highlight the versatile nature and wide range of applicability of hydrogel-based studies. Attention is also given to the integration of hydrogels within bioreactor systems, specialized devices used in biological studies to culture cells under controlled conditions, enhancing their potential for regenerative medicine, drug discovery, and drug delivery. Despite the abundance of literature on this subject, a comprehensive overview of Italian contributions to the field of hydrogels-based biomedical research is still missing and is thus our focus for this review. Consolidating a diverse range of studies, the Italian scientific community presents a complete landscape for hydrogel use, shaping the future directions of biomaterials research. This review aspires to serve as a guide and map for Italian researchers interested in the development and use of hydrogels in biomedicine. [ABSTRACT FROM AUTHOR]

Published

2024

27. Coaxial 3D Bioprinting Process Research and Performance Tests on Vascular Scaffolds.

Author

Sun, Jiarun, Gong, Youping, Xu, Manli, Chen, Huipeng, Shao, Huifeng, and Zhou, Rougang

Subjects

BIOPRINTING, TISSUE scaffolds, UMBILICAL veins, CALCIUM chloride, SODIUM alginate, ENDOTHELIAL cells

Abstract

Three-dimensionally printed vascularized tissue, which is suitable for treating human cardiovascular diseases, should possess excellent biocompatibility, mechanical performance, and the structure of complex vascular networks. In this paper, we propose a method for fabricating vascularized tissue based on coaxial 3D bioprinting technology combined with the mold method. Sodium alginate (SA) solution was chosen as the bioink material, while the cross-linking agent was a calcium chloride (CaCl2) solution. To obtain the optimal parameters for the fabrication of vascular scaffolds, we first formulated theoretical models of a coaxial jet and a vascular network. Subsequently, we conducted a simulation analysis to obtain preliminary process parameters. Based on the aforementioned research, experiments of vascular scaffold fabrication based on the coaxial jet model and experiments of vascular network fabrication were carried out. Finally, we optimized various parameters, such as the flow rate of internal and external solutions, bioink concentration, and cross-linking agent concentration. The performance tests showed that the fabricated vascular scaffolds had levels of satisfactory degradability, water absorption, and mechanical properties that meet the requirements for practical applications. Cellular experiments with stained samples demonstrated satisfactory proliferation of human umbilical vein endothelial cells (HUVECs) within the vascular scaffold over a seven-day period, observed under a fluorescent inverted microscope. The cells showed good biocompatibility with the vascular scaffold. The above results indicate that the fabricated vascular structure initially meet the requirements of vascular scaffolds. [ABSTRACT FROM AUTHOR]

Published

2024

28. Graphene in 3D Bioprinting.

Author

Patil, Rahul and Alimperti, Stella

Subjects

BIOPRINTING, THREE-dimensional printing, GRAPHENE, REGENERATIVE medicine, TISSUE engineering, GRAPHENE oxide

Abstract

Three-dimensional (3D) bioprinting is a fast prototyping fabrication approach that allows the development of new implants for tissue restoration. Although various materials have been utilized for this process, they lack mechanical, electrical, chemical, and biological properties. To overcome those limitations, graphene-based materials demonstrate unique mechanical and electrical properties, morphology, and impermeability, making them excellent candidates for 3D bioprinting. This review summarizes the latest developments in graphene-based materials in 3D printing and their application in tissue engineering and regenerative medicine. Over the years, different 3D printing approaches have utilized graphene-based materials, such as graphene, graphene oxide (GO), reduced GO (rGO), and functional GO (fGO). This process involves controlling multiple factors, such as graphene dispersion, viscosity, and post-curing, which impact the properties of the 3D-printed graphene-based constructs. To this end, those materials combined with 3D printing approaches have demonstrated prominent regeneration potential for bone, neural, cardiac, and skin tissues. Overall, graphene in 3D bioprinting may pave the way for new regenerative strategies with translational implications in orthopedics, neurology, and cardiovascular areas. [ABSTRACT FROM AUTHOR]

Published

2024

29. Biomimetic Scaffolds—A Novel Approach to Three Dimensional Cell Culture Techniques for Potential Implementation in Tissue Engineering.

Author

Górnicki, Tomasz, Lambrinow, Jakub, Golkar-Narenji, Afsaneh, Data, Krzysztof, Domagała, Dominika, Niebora, Julia, Farzaneh, Maryam, Mozdziak, Paul, Zabel, Maciej, Antosik, Paweł, Bukowska, Dorota, Ratajczak, Kornel, Podhorska-Okołów, Marzenna, Dzięgiel, Piotr, and Kempisty, Bartosz

Subjects

*TISSUE scaffolds, *BIOMIMETIC materials, *BIOPRINTING, *TISSUE engineering, *CELL culture, *SKIN regeneration, *MUSCULOSKELETAL system, *INDIVIDUALIZED medicine

Abstract

Biomimetic scaffolds imitate native tissue and can take a multidimensional form. They are biocompatible and can influence cellular metabolism, making them attractive bioengineering platforms. The use of biomimetic scaffolds adds complexity to traditional cell cultivation methods. The most commonly used technique involves cultivating cells on a flat surface in a two-dimensional format due to its simplicity. A three-dimensional (3D) format can provide a microenvironment for surrounding cells. There are two main techniques for obtaining 3D structures based on the presence of scaffolding. Scaffold-free techniques consist of spheroid technologies. Meanwhile, scaffold techniques contain organoids and all constructs that use various types of scaffolds, ranging from decellularized extracellular matrix (dECM) through hydrogels that are one of the most extensively studied forms of potential scaffolds for 3D culture up to 4D bioprinted biomaterials. 3D bioprinting is one of the most important techniques used to create biomimetic scaffolds. The versatility of this technique allows the use of many different types of inks, mainly hydrogels, as well as cells and inorganic substances. Increasing amounts of data provide evidence of vast potential of biomimetic scaffolds usage in tissue engineering and personalized medicine, with the main area of potential application being the regeneration of skin and musculoskeletal systems. Recent papers also indicate increasing amounts of in vivo tests of products based on biomimetic scaffolds, which further strengthen the importance of this branch of tissue engineering and emphasize the need for extensive research to provide safe for humansbiomimetic tissues and organs. In this review article, we provide a review of the recent advancements in the field of biomimetic scaffolds preceded by an overview of cell culture technologies that led to the development of biomimetic scaffold techniques as the most complex type of cell culture. [ABSTRACT FROM AUTHOR]

Published

2024

30. Suitability of Gelatin Methacrylate and Hydroxyapatite Hydrogels for 3D-Bioprinted Bone Tissue.

Author

Stolarov, Paul, de Vries, Jonathan, Stapleton, Sean, Morris, Lauren, Martyniak, Kari, and Kean, Thomas J.

Subjects

*HYDROXYAPATITE, *BIOPRINTING, *GELATIN, *METHACRYLATES, *CELLULAR mechanics, *HYDROGELS, *CELL survival, *FACTORIAL experiment designs

Abstract

Background: Complex bone defects are challenging to treat. Autografting is the gold standard for regenerating bone defects; however, its limitations include donor-site morbidity and increased surgical complexity. Advancements in 3D bioprinting (3DBP) offer a promising alternative for viable bone grafts. In this experiment, gels composed of varying levels of gelatin methacrylate (GelMA) and hydroxyapatite (HA) and gelatin concentrations are explored. The objective was to increase the hydroxyapatite content and find the upper limit before the printability was compromised and determine its effect on the mechanical properties and cell viability. Methods: Design of Experiments (DoE) was used to design 13 hydrogel bioinks of various GelMA/HA concentrations. These bioinks were assessed in terms of their pipettability and equilibrium modulus. An optimal bioink was designed using the DoE data to produce the greatest stiffness while still being pipettable. Three bioinks, one with the DoE-designed maximal stiffness, one with the experimentally defined maximal stiffness, and a literature-based control, were then printed using a 3D bioprinter and assessed for print fidelity. The resulting hydrogels were combined with human bone-marrow-derived mesenchymal stromal cells (hMSCs) and evaluated for cell viability. Results: The DoE ANOVA analysis indicated that the augmented three-level factorial design model used was a good fit (p < 0.0001). Using the model, DoE correctly predicted that a composite hydrogel consisting of 12.3% GelMA, 15.7% HA, and 2% gelatin would produce the maximum equilibrium modulus while still being pipettable. The hydrogel with the most optimal print fidelity was 10% GelMA, 2% HA, and 5% gelatin. There were no significant differences in the cell viability within the hydrogels from day 2 to day 7 (p > 0.05). There was, however, a significantly lower cell viability in the gel composed of 12.3% GelMA, 15.7% HA, and 2% gelatin compared to the other gels with a lower HA concentration (p < 0.05), showing that a higher HA content or print pressure may be cytotoxic within hydrogels. Conclusions: Extrusion-based 3DBP offers significant advantages for bone–tissue implants due to its high customizability. This study demonstrates that it is possible to create printable bone-like grafts from GelMA and HA with an increased HA content, favorable mechanical properties (145 kPa), and a greater than 80% cell viability. [ABSTRACT FROM AUTHOR]

Published

2024

31. Recent Developments in Bio-Ink Formulations Using Marine-Derived Biomaterials for Three-Dimensional (3D) Bioprinting.

Author

Khiari, Zied

Abstract

3D bioprinting is a disruptive, computer-aided, and additive manufacturing technology that allows the obtention, layer-by-layer, of 3D complex structures. This technology is believed to offer tremendous opportunities in several fields including biomedical, pharmaceutical, and food industries. Several bioprinting processes and bio-ink materials have emerged recently. However, there is still a pressing need to develop low-cost sustainable bio-ink materials with superior qualities (excellent mechanical, viscoelastic and thermal properties, biocompatibility, and biodegradability). Marine-derived biomaterials, including polysaccharides and proteins, represent a viable and renewable source for bio-ink formulations. Therefore, the focus of this review centers around the use of marine-derived biomaterials in the formulations of bio-ink. It starts with a general overview of 3D bioprinting processes followed by a description of the most commonly used marine-derived biomaterials for 3D bioprinting, with a special attention paid to chitosan, glycosaminoglycans, alginate, carrageenan, collagen, and gelatin. The challenges facing the application of marine-derived biomaterials in 3D bioprinting within the biomedical and pharmaceutical fields along with future directions are also discussed. [ABSTRACT FROM AUTHOR]

Published

2024

32. High Hopes for the Biofabrication of Articular Cartilage—What Lies beyond the Horizon of Tissue Engineering and 3D Bioprinting?

Author

Sbirkov, Yordan, Redzheb, Murad, Forraz, Nico, McGuckin, Colin, and Sarafian, Victoria

Subjects

BIOPRINTING, ARTICULAR cartilage, TISSUE engineering, REGENERATIVE medicine, BIOLOGISTS

Abstract

Technologies and biomaterials for 3D bioprinting have been developing extremely quickly in the past decade as they hold great potential in tissue engineering. This, together with the possibility to differentiate stem cells of different origin into any cell type, raises the hopes in regenerative medicine once again after the initial breakthrough with stem cells in the 1980s. Nevertheless, three decades of 3D bioprinting experiments have shown that the production of functional tissues would take a longer time than anticipated. Cartilage, one of the simplest tissues in the body, consists of only one cell type. It is not vascularised and innervated and does not have lymphatic vessels either, which makes it a perfect target tissue for successful implantation. The tremendous amount of work since the beginning of this century, combining the efforts of bioengineers, material scientists, biologists, and physicians, has culminated in multiple proof-of-concept constructs that have been implanted in animals. However, there is no single reproducible, standardised, widely accessible and accepted strategy that can be readily applied in the clinic. In this review, we focus on the current progress in the field of the 3D biofabrication of articular cartilage and critically assess failures and future challenges. [ABSTRACT FROM AUTHOR]

Published

2024

33. Three-Dimensional Bioprinting of Strontium-Modified Controlled Assembly of Collagen Polylactic Acid Composite Scaffold for Bone Repair.

Author

Sun, Weiwei, Xie, Wenyu, Hu, Kun, Yang, Zongwen, Han, Lu, Li, Luhai, Qi, Yuansheng, and Wei, Yen

Subjects

*POLYLACTIC acid, *BIOPRINTING, *COLLAGEN, *BONE grafting, *TISSUE engineering, *BONE regeneration, *REPAIRING

Abstract

In recent years, the incidence of bone defects has been increasing year by year. Bone transplantation has become the most needed surgery after a blood transfusion and shows a rising trend. Three-dimensional-printed implants can be arbitrarily shaped according to the defects of tissues and organs to achieve perfect morphological repair, opening a new way for non-traumatic repair and functional reconstruction. In this paper, strontium-doped mineralized collagen was first prepared by an in vitro biomimetic mineralization method and then polylactic acid was homogeneously blended with the mineralized collagen to produce a comprehensive bone repair scaffold by a gas extrusion 3D printing method. Characterization through scanning electron microscopy, X-ray diffraction, and mechanical testing revealed that the strontium-functionalized composite scaffold exhibits an inorganic composition and nanostructure akin to those of human bone tissue. The scaffold possesses uniformly distributed and interconnected pores, with a compressive strength reaching 21.04 MPa. The strontium doping in the mineralized collagen improved the biocompatibility of the scaffold and inhibited the differentiation of osteoclasts to promote bone regeneration. This innovative composite scaffold holds significant promise in the field of bone tissue engineering, providing a forward-thinking solution for prospective bone injury repair. [ABSTRACT FROM AUTHOR]

Published

2024

34. Calcium Phosphate Biomaterials for 3D Bioprinting in Bone Tissue Engineering.

Author

Tolmacheva, Nelli, Bhattacharyya, Amitava, and Noh, Insup

Subjects

*BIOPRINTING, *TISSUE engineering, *CALCIUM phosphate, *TISSUE scaffolds, *BIOMATERIALS, *BONE products, *EXTRACELLULAR matrix, *HYDROGELS

Abstract

Three-dimensional bioprinting is a promising technology for bone tissue engineering. However, most hydrogel bioinks lack the mechanical and post-printing fidelity properties suitable for such hard tissue regeneration. To overcome these weak properties, calcium phosphates can be employed in a bioink to compensate for the lack of certain characteristics. Further, the extracellular matrix of natural bone contains this mineral, resulting in its structural robustness. Thus, calcium phosphates are necessary components of bioink for bone tissue engineering. This review paper examines different recently explored calcium phosphates, as a component of potential bioinks, for the biological, mechanical and structural properties required of 3D bioprinted scaffolds, exploring their distinctive properties that render them favorable biomaterials for bone tissue engineering. The discussion encompasses recent applications and adaptations of 3D-printed scaffolds built with calcium phosphates, delving into the scientific reasons behind the prevalence of certain types of calcium phosphates over others. Additionally, this paper elucidates their interactions with polymer hydrogels for 3D bioprinting applications. Overall, the current status of calcium phosphate/hydrogel bioinks for 3D bioprinting in bone tissue engineering has been investigated. [ABSTRACT FROM AUTHOR]

Published

2024

35. The 3D-McMap Guidelines: Three-Dimensional Multicomposite Microsphere Adaptive Printing.

Author

Klar, Roland M., Cox, James, Raja, Naren, and Lohfeld, Stefan

Subjects

*BIOPOLYMERS, *BIOPRINTING, *EXTRUSION process, *GROWTH factors, *TISSUE engineering, *TISSUE scaffolds, *MICROSPHERES, *PLATELET-rich plasma

Abstract

Microspheres, synthesized from diverse natural or synthetic polymers, are readily utilized in biomedical tissue engineering to improve the healing of various tissues. Their ability to encapsulate growth factors, therapeutics, and natural biomolecules, which can aid tissue regeneration, makes microspheres invaluable for future clinical therapies. While microsphere-supplemented scaffolds have been investigated, a pure microsphere scaffold with an optimized architecture has been challenging to create via 3D printing methods due to issues that prevent consistent deposition of microsphere-based materials and their ability to maintain the shape of the 3D-printed structure. Utilizing the extrusion printing process, we established a methodology that not only allows the creation of large microsphere scaffolds but also multicomposite matrices into which cells, growth factors, and therapeutics encapsulated in microspheres can be directly deposited during the printing process. Our 3D-McMap method provides some critical guidelines for issues with scaffold shape fidelity during and after printing. Carefully timed breaks, minuscule drying steps, and adjustments to extrusion parameters generated an evenly layered large microsphere scaffold that retained its internal architecture. Such scaffolds are superior to other microsphere-containing scaffolds, as they can release biomolecules in a highly controlled spatiotemporal manner. This capability permits us to study cell responses to the delivered signals to develop scaffolds that precisely modulate new tissue formation. [ABSTRACT FROM AUTHOR]

Published

2024

36. Fabrication of Fish Scale-Based Gelatin Methacryloyl for 3D Bioprinting Application.

Author

Pasanaphong, Kitipong, Pukasamsombut, Danai, Boonyagul, Sani, Pengpanich, Sukanya, Tawonsawatruk, Tulyapruek, Wilairatanarporn, Danuphat, Jantanasakulwong, Kittisak, Rachtanapun, Pornchai, Hemstapat, Ruedee, Wangtueai, Sutee, and Tanadchangsaeng, Nuttapol

Subjects

*BIOPRINTING, *GELATIN, *SCALES (Fishes), *CELLULAR mechanics, *CELL nuclei, *INFECTIOUS disease transmission, *CELL survival

Abstract

Gelatin methacryloyl (GelMA) is an ideal bioink that is commonly used in bioprinting. GelMA is primarily acquired from mammalian sources; however, the required amount makes the market price extremely high. Since garbage overflow is currently a global issue, we hypothesized that fish scales left over from the seafood industry could be used to synthesize GelMA. Clinically, the utilization of fish products is more advantageous than those derived from mammals as they lower the possibility of disease transmission from mammals to humans and are permissible for practitioners of all major religions. In this study, we used gelatin extracted from fish scales and conventional GelMA synthesis methods to synthesize GelMA, then tested it at different concentrations in order to evaluated and compared the mechanical properties and cell responses. The fish scale GelMA had a printing accuracy of 97%, a swelling ratio of 482%, and a compressive strength of about 85 kPa at a 10% w/v GelMA concentration. Keratinocyte cells (HaCaT cells) were bioprinted with the GelMA bioink to assess cell viability and proliferation. After 72 h of culture, the number of cells increased by almost three-fold compared to 24 h, as indicated by many fluorescent cell nuclei. Based on this finding, it is possible to use fish scale GelMA bioink as a scaffold to support and enhance cell viability and proliferation. Therefore, we conclude that fish scale-based GelMA has the potential to be used as an alternative biomaterial for a wide range of biomedical applications. [ABSTRACT FROM AUTHOR]

Published

2024

37. Xeno-Free 3D Bioprinted Liver Model for Hepatotoxicity Assessment.

Author

Ali, Ahmed S. M., Berg, Johanna, Roehrs, Viola, Wu, Dongwei, Hackethal, Johannes, Braeuning, Albert, Woelken, Lisa, Rauh, Cornelia, and Kurreck, Jens

Subjects

*BIOPRINTING, *LIVER, *TOXICITY testing, *HEPATOTOXICOLOGY, *ANIMAL experimentation, *CELL culture

Abstract

Three-dimensional (3D) bioprinting is one of the most promising methodologies that are currently in development for the replacement of animal experiments. Bioprinting and most alternative technologies rely on animal-derived materials, which compromises the intent of animal welfare and results in the generation of chimeric systems of limited value. The current study therefore presents the first bioprinted liver model that is entirely void of animal-derived constituents. Initially, HuH-7 cells underwent adaptation to a chemically defined medium (CDM). The adapted cells exhibited high survival rates (85–92%) after cryopreservation in chemically defined freezing media, comparable to those preserved in standard medium (86–92%). Xeno-free bioink for 3D bioprinting yielded liver models with high relative cell viability (97–101%), akin to a Matrigel-based liver model (83–102%) after 15 days of culture. The established xeno-free model was used for toxicity testing of a marine biotoxin, okadaic acid (OA). In 2D culture, OA toxicity was virtually identical for cells cultured under standard conditions and in CDM. In the xeno-free bioprinted liver model, 3-fold higher concentrations of OA than in the respective monolayer culture were needed to induce cytotoxicity. In conclusion, this study describes for the first time the development of a xeno-free 3D bioprinted liver model and its applicability for research purposes. [ABSTRACT FROM AUTHOR]

Published

2024

38. Recent Developments in 3D-(Bio)printed Hydrogels as Wound Dressings.

Author

Kammona, Olga, Tsanaktsidou, Evgenia, and Kiparissides, Costas

Subjects

HYDROGELS in medicine, SURGICAL dressings, THREE-dimensional printing, WOUND healing, SKIN diseases

Abstract

Wound healing is a physiological process occurring after the onset of a skin lesion aiming to reconstruct the dermal barrier between the external environment and the body. Depending on the nature and duration of the healing process, wounds are classified as acute (e.g., trauma, surgical wounds) and chronic (e.g., diabetic ulcers) wounds. The latter take several months to heal or do not heal (non-healing chronic wounds), are usually prone to microbial infection and represent an important source of morbidity since they affect millions of people worldwide. Typical wound treatments comprise surgical (e.g., debridement, skin grafts/flaps) and non-surgical (e.g., topical formulations, wound dressings) methods. Modern experimental approaches include among others three dimensional (3D)-(bio)printed wound dressings. The present paper reviews recently developed 3D (bio)printed hydrogels for wound healing applications, especially focusing on the results of their in vitro and in vivo assessment. The advanced hydrogel constructs were printed using different types of bioinks (e.g., natural and/or synthetic polymers and their mixtures with biological materials) and printing methods (e.g., extrusion, digital light processing, coaxial microfluidic bioprinting, etc.) and incorporated various bioactive agents (e.g., growth factors, antibiotics, antibacterial agents, nanoparticles, etc.) and/or cells (e.g., dermal fibroblasts, keratinocytes, mesenchymal stem cells, endothelial cells, etc.). [ABSTRACT FROM AUTHOR]

Published

2024

39. An Anti-Oxidative Bioink for Cartilage Tissue Engineering Applications.

Author

Chen, Xin, Yang, Mengni, Zhou, Zheng, Sun, Jingjing, Meng, Xiaolin, Huang, Yuting, Zhu, Wenxiang, Zhu, Shuai, He, Ning, Zhu, Xiaolong, Han, Xiaoxiao, and Liu, Hairong

Subjects

BIOPRINTING, CARTILAGE, GLYCIDYL methacrylate, CARTILAGE regeneration, BIOACTIVE compounds, SILK fibroin, TISSUE engineering

Abstract

Since chondrocytes are highly vulnerable to oxidative stress, an anti-oxidative bioink combined with 3D bioprinting may facilitate its applications in cartilage tissue engineering. We developed an anti-oxidative bioink with methacrylate-modified rutin (RTMA) as an additional bioactive component and glycidyl methacrylate silk fibroin as a biomaterial component. Bioink containing 0% RTMA was used as the control sample. Compared with hydrogel samples produced with the control bioink, solidified anti-oxidative bioinks displayed a similar porous microstructure, which is suitable for cell adhesion and migration, and the transportation of nutrients and wastes. Among photo-cured samples prepared with anti-oxidative bioinks and the control bioink, the sample containing 1 mg/mL of RTMA (RTMA-1) showed good degradation, promising mechanical properties, and the best cytocompatibility, and it was selected for further investigation. Based on the results of 3D bioprinting tests, the RTMA-1 bioink exhibited good printability and high shape fidelity. The results demonstrated that RTMA-1 reduced intracellular oxidative stress in encapsulated chondrocytes under H2O2 stimulation, which results from upregulation of COLII and AGG and downregulation of MMP13 and MMP1. By using in vitro and in vivo tests, our data suggest that the RTMA-1 bioink significantly enhanced the regeneration and maturation of cartilage tissue compared to the control bioink, indicating that this anti-oxidative bioink can be used for 3D bioprinting and cartilage tissue engineering applications in the future. [ABSTRACT FROM AUTHOR]

Published

2024

40. In Vitro Three-Dimensional (3D) Models for Melanoma Immunotherapy.

Author

Nomdedeu-Sancho, Gemma, Gorkun, Anastasiya, Mahajan, Naresh, Willson, Kelsey, Schaaf, Cecilia R., Votanopoulos, Konstantinos I., Atala, Anthony, and Soker, Shay

Subjects

*BIOLOGICAL models, *IN vitro studies, *MELANOMA, *CELL physiology, *INDIVIDUALIZED medicine, *TISSUE engineering, *MICROFLUIDICS, *IMMUNOTHERAPY

Abstract

Simple Summary: Melanoma treatment has progressed through the use of immune checkpoint inhibitors, significantly boosting patient survival rates. However, many tumors do not respond to these drugs or develop resistance, partly due to the tumor microenvironment influencing cancer cell growth and immune cell behavior. To gain insights into therapy outcomes, researchers have focused on developing cell-based ex vivo models of melanomas. These models include tumor organoids, engineered tissues, and microfluidic devices designed to replicate melanoma in its natural skin environment. Yet, integrating the tumor microenvironment and immune factors remains challenging. This review explores the creation of in vitro 3D models for normal skin and melanoma, focusing on methods to include immune components. These models hold promise for testing immunotherapies and uncovering resistance mechanisms. By faithfully replicating the tumor microenvironment and its interactions with the immune system, these models can enhance our understanding of immunotherapy resistance and ultimately improve personalized melanoma treatment. Melanoma is responsible for the majority of skin cancer-related fatalities. Immune checkpoint inhibitor (ICI) treatments have revolutionized the management of the disease by significantly increasing patient survival rates. However, a considerable number of tumors treated with these drugs fail to respond or may develop resistance over time. Tumor growth and its response to therapies are critically influenced by the tumor microenvironment (TME); it directly supports cancer cell growth and influences the behavior of surrounding immune cells, which can become tumor-permissive, thereby rendering immunotherapies ineffective. Ex vivo modeling of melanomas and their response to treatment could significantly advance our understanding and predictions of therapy outcomes. Efforts have been directed toward developing reliable models that accurately mimic melanoma in its appropriate tissue environment, including tumor organoids, bioprinted tissue constructs, and microfluidic devices. However, incorporating and modeling the melanoma TME and immune component remains a significant challenge. Here, we review recent literature regarding the generation of in vitro 3D models of normal skin and melanoma and the approaches used to incorporate the immune compartment in such models. We discuss how these constructs could be combined and used to test immunotherapies and elucidate treatment resistance mechanisms. The development of 3D in vitro melanoma models that faithfully replicate the complexity of the TME and its interaction with the immune system will provide us with the technical tools to better understand ICI resistance and increase its efficacy, thereby improving personalized melanoma therapy. [ABSTRACT FROM AUTHOR]

Published

2023

41. Trends and Technological Challenges of 3D Bioprinting in Cultured Meat: Technological Prospection.

Author

Barbosa, Willams, Correia, Paulo, Vieira, Jaqueline, Leal, Ingrid, Rodrigues, Letícia, Nery, Tatiana, Barbosa, Josiane, and Soares, Milena

Subjects

BIOPRINTING, MEAT alternatives, SCIENTIFIC literature, NUTRITIONAL value, IN vitro meat, RESEARCH personnel, MEAT

Abstract

Cultured meat presents a possible alternative to conventional meat products and may be used to address growing food demands attributable to global population growth. Thus, a comprehensive technological prospection of the scientific literature related to cultured meat produced by 3D bioprinting is of great interest to researchers. The purpose of this article is to review and analyze published studies related to the biofabrication of cultured meat using 3D bioprinting techniques. The growing number of related publications in recent years highlights that cultured meat has gained traction in the scientific community. Furthermore, private companies and startups have contributed to advancements in the biofabrication of cultured meat for consumption, illustrating that cultured meat as a conventional meat substitute is already becoming reality. However, like any scientific advance, 3D bioprinting of cultured meat faces challenges involving regulation, acceptance, the selection of ideal biomaterials and cell lines, the replacement of fetal bovine serum (FBS), and attaining a texture and nutritional value similar to those of conventional meat. [ABSTRACT FROM AUTHOR]

Published

2023

42. The Evolution of Current Concept of the Reconstructive Ladder in Plastic Surgery: The Emerging Role of Translational Medicine.

Author

De Francesco, Francesco, Zingaretti, Nicola, Parodi, Pier Camillo, and Riccio, Michele

Subjects

*FREE flaps, *PLASTIC surgery, *REGENERATIVE medicine, *TRANSLATIONAL research, *TECHNOLOGICAL innovations, *BIOMATERIALS, *BIOPRINTING, *ARACHNOID cysts

Abstract

Plastic surgeons have used the reconstructive ladder for many decades as a standard directory for complex trauma reconstruction with the goal of repairing body structures and restoring functionality. This consists of different surgical maneuvers, such as secondary intention and direct tissue closure, as well as more complex methods such as local tissue transfer and free flap. The reconstructive ladder represents widely known options achievable for tissue reconstruction and wound closure that puts at the bottom rung the simplest methods of reconstruction and strengthens the complexity by moving upward. Regenerative medicine and surgery constitute a quickly spreading area of translational research that can be employed by minimally invasive surgical strategies, with the aim of regenerating cells and tissues in vivo in order to reestablish normal function through the intrinsic potential of cells, in combination with biomaterials and appropriate biochemical stimuli. These translational procedures have the aim of creating an appropriate microenvironment capable of supporting the physiological cellular function to generate the desired cells or tissues and to generate parenchymal, stromal, and vascular components on demand, and above all to produce intelligent materials capable of determining the fate of cells. Smart technologies have been grown that give extra "rungs" on the classic reconstructive ladder to integrate a more holistic, patient-based approach with improved outcomes. This commentary presents the evolution of the traditional concept of the reconstructive ladder in the field of plastic surgery into a new course with the aim of achieving excellent results for soft tissue reconstruction by applying innovative technologies and biologically active molecules for a wide range of surgical diseases. [ABSTRACT FROM AUTHOR]

Published

2023

43. Nanocrystalline Cellulose as a Versatile Engineering Material for Extrusion-Based Bioprinting.

Author

Read, Sophia A., Go, Chee Shuen, Ferreira, Miguel J. S., Ligorio, Cosimo, Kimber, Susan J., Dumanli, Ahu G., and Domingos, Marco A. N.

Subjects

*BIOPRINTING, *CELLULOSE nanocrystals, *RHEOLOGY, *CELLULOSE, *ENGINEERING

Abstract

Naturally derived polysaccharide-based hydrogels, such as alginate, are frequently used in the design of bioinks for 3D bioprinting. Traditionally, the formulation of such bioinks requires the use of pre-reticulated materials with low viscosities, which favour cell viability but can negatively influence the resolution and shape fidelity of the printed constructs. In this work, we propose the use of cellulose nanocrystals (CNCs) as a rheological modifier to improve the printability of alginate-based bioinks whilst ensuring a high viability of encapsulated cells. Through rheological analysis, we demonstrate that the addition of CNCs (1% and 2% (w/v)) to alginate hydrogels (1% (w/v)) improves shear-thinning behaviour and mechanical stability, resulting in the high-fidelity printing of constructs with superior resolution. Importantly, LIVE/DEAD results confirm that the presence of CNCs does not seem to affect the health of immortalised chondrocytes (TC28a2) that remain viable over a period of seven days post-encapsulation. Taken together, our results indicate a favourable effect of the CNCs on the rheological and biocompatibility properties of alginate hydrogels, opening up new perspectives for the application of CNCs in the formulation of bioinks for extrusion-based bioprinting. [ABSTRACT FROM AUTHOR]

Published

2023

44. Three-Dimensional Bioprinting in Soft Tissue Engineering for Plastic and Reconstructive Surgery.

Author

Bülow, Astrid, Schäfer, Benedikt, and Beier, Justus P.

Subjects

*BIOPRINTING, *TISSUE engineering, *PLASTICS engineering, *ENGINEERING plastics, *TISSUE scaffolds, *SKELETAL muscle

Abstract

Skeletal muscle tissue engineering (TE) and adipose tissue engineering have undergone significant progress in recent years. This review focuses on the key findings in these areas, particularly highlighting the integration of 3D bioprinting techniques to overcome challenges and enhance tissue regeneration. In skeletal muscle TE, 3D bioprinting enables the precise replication of muscle architecture. This addresses the need for the parallel alignment of cells and proper innervation. Satellite cells (SCs) and mesenchymal stem cells (MSCs) have been utilized, along with co-cultivation strategies for vascularization and innervation. Therefore, various printing methods and materials, including decellularized extracellular matrix (dECM), have been explored. Similarly, in adipose tissue engineering, 3D bioprinting has been employed to overcome the challenge of vascularization; addressing this challenge is vital for graft survival. Decellularized adipose tissue and biomimetic scaffolds have been used as biological inks, along with adipose-derived stem cells (ADSCs), to enhance graft survival. The integration of dECM and alginate bioinks has demonstrated improved adipocyte maturation and differentiation. These findings highlight the potential of 3D bioprinting techniques in skeletal muscle and adipose tissue engineering. By integrating specific cell types, biomaterials, and printing methods, significant progress has been made in tissue regeneration. However, challenges such as fabricating larger constructs, translating findings to human models, and obtaining regulatory approvals for cellular therapies remain to be addressed. Nonetheless, these advancements underscore the transformative impact of 3D bioprinting in tissue engineering research and its potential for future clinical applications. [ABSTRACT FROM AUTHOR]

Published

2023

45. World's First Long-Term Colorectal Cancer Model by 3D Bioprinting as a Mechanism for Screening Oncolytic Viruses.

Author

McGuckin, Colin, Forraz, Nico, Milet, Clément, Lacroix, Mathieu, Sbirkov, Yordan, Sarafian, Victoria, Ebel, Caroline, Spindler, Anita, Koerper, Véronique, Balloul, Jean-Marc, Quéméneur, Eric, and Zaupa, Cécile

Subjects

*THREE-dimensional imaging, *STRUCTURAL models, *CELLULAR therapy, *BIOMEDICAL engineering, *EARLY detection of cancer, *COLORECTAL cancer, *DESCRIPTIVE statistics, *RESEARCH funding, *ONCOLYTIC virotherapy, *LONGITUDINAL method

Abstract

Simple Summary: Although many new cancer drugs look like they are working in the laboratory, they fail when tested on real people. This is often because the cancer cell models they are tested on are short-term, but cancer grows in people over a longer period, and things change over time. This is not a criticism of cancer laboratories, but more a realism of the limits of scientific research. This is why we developed this longer-lasting model of colorectal cancer that has moved around the body. At the same time, we used this model to test next-generation delivery of chemotherapy drugs to tumors with an advanced targeting virus. All levels of cancer research have value, both short-term and long-term, but the longer strategies need to catch up, so this study demonstrates what can be achieved with 3D bioprinting tumor models and testing viruses transformed for good. Long-term modelization of cancer as it changes in the human body is a difficult goal, particularly when designing and testing new therapeutic strategies. This becomes even more difficult with metastasis modeling to show chemotherapeutic molecule delivery directly to tumoral cells. Advanced therapeutics, including oncolytic viruses, antibody-based and cell-based therapies are increasing. The question is, are screening tests also evolving? Next-generation therapeutics need equally advanced screening tests, which whilst difficult to achieve, are the goal of our work here, creating models of micro- and macrotumors using 3D bioprinting. We developed advanced colorectal cancer tumor processing techniques to provide options for cellular expansion, microtumor printing, and long-term models, which allow for the evaluation of the kinetics of penetration testing, therapeutic success, targeted therapies, and personalized medicine. We describe how we tested tumors from a primary colorectal patient and, applying 3D bioprinting, matured long-term models for oncolytic metastatic screening. Three-dimensional microtumors were kept alive for the longest time ever recorded in vitro, allowing longitudinal studies, screening of oncolytic viruses and realistic modelization of colorectal cancer. These 3D bioprinted models were maintained for around 6 months and were able to demonstrate the effective delivery of a product to the tumoral environment and represent a step forward in therapeutic screening. [ABSTRACT FROM AUTHOR]

Published

2023

46. Recent Advances in the Development of Biomimetic Materials.

Author

Ciulla, Maria G., Massironi, Alessio, Sugni, Michela, Ensign, Matthew A., Marzorati, Stefania, and Forouharshad, Mahdi

Subjects

BIOMIMETIC materials, TISSUE engineering, EXTRACELLULAR matrix, BIOENGINEERING, COLLAGEN

Abstract

In this review, we focused on recent efforts in the design and development of materials with biomimetic properties. Innovative methods promise to emulate cell microenvironments and tissue functions, but many aspects regarding cellular communication, motility, and responsiveness remain to be explained. We photographed the state-of-the-art advancements in biomimetics, and discussed the complexity of a "bottom-up" artificial construction of living systems, with particular highlights on hydrogels, collagen-based composites, surface modifications, and three-dimensional (3D) bioprinting applications. Fast-paced 3D printing and artificial intelligence, nevertheless, collide with reality: How difficult can it be to build reproducible biomimetic materials at a real scale in line with the complexity of living systems? Nowadays, science is in urgent need of bioengineering technologies for the practical use of bioinspired and biomimetics for medicine and clinics. [ABSTRACT FROM AUTHOR]

Published

2023

47. Injectable In Situ Crosslinking Hydrogel for Autologous Fat Grafting.

Author

Oskarsdotter, Kristin, Nordgård, Catherine T., Apelgren, Peter, Säljö, Karin, Solbu, Anita A., Eliasson, Edwin, Sämfors, Sanna, Sætrang, Henriette E. M., Asdahl, Lise Cathrine, Thompson, Eric M., Troedsson, Christofer, Simonsson, Stina, Strand, Berit L., Gatenholm, Paul, and Kölby, Lars

Subjects

CROSSLINKING (Polymerization), HYDROGELS, ADIPOSE tissues, SKIN grafting, CELLULOSE

Abstract

Autologous fat grafting is hampered by unpredictable outcomes due to high tissue resorption. Hydrogels based on enzymatically pretreated tunicate nanocellulose (ETC) and alginate (ALG) are biocompatible, safe, and present physiochemical properties capable of promoting cell survival. Here, we compared in situ and ex situ crosslinking of ETC/ALG hydrogels combined with lipoaspirate human adipose tissue (LAT) to generate an injectable formulation capable of retaining dimensional stability in vivo. We performed in situ crosslinking using two different approaches; inducing Ca2+ release from CaCO3 microparticles (CMPs) and physiologically available Ca2+ in vivo. Additionally, we generated ex situ-crosslinked, 3D-bioprinted hydrogel-fat grafts. We found that in vitro optimization generated a CMP-crosslinking system with comparable stiffness to ex situ-crosslinked gels. Comparison of outcomes following in vivo injection of each respective crosslinked hydrogel revealed that after 30 days, in situ crosslinking generated fat grafts with less shape retention than 3D-bioprinted constructs that had undergone ex situ crosslinking. However, CMP addition improved fat-cell distribution and cell survival relative to grafts dependent on physiological Ca2+ alone. These findings suggested that in situ crosslinking using CMP might promote the dimensional stability of injectable fat-hydrogel grafts, although 3D bioprinting with ex situ crosslinking more effectively ensured proper shape stability in vivo. [ABSTRACT FROM AUTHOR]

Published

2023

48. Preclinical Testing Techniques: Paving the Way for New Oncology Screening Approaches.

Author

van Rijt, Antonia, Stefanek, Evan, and Valente, Karolina

Subjects

*DRUG efficacy, *STRUCTURAL models, *MEDICAL screening, *CELL physiology, *DRUG development, *DRUG toxicity

Abstract

Simple Summary: Traditional preclinical testing, including 2D cell culture and animal models, often fails to accurately predict drug efficacy in humans, especially for oncology drugs, where drug candidates that enter clinical trials have very high failure rates. Advancements in biology and tissue engineering techniques allow researchers to evaluate drug candidates before human trials using 3D cell culture models that more closely resemble human tissues than 2D culture methods. These techniques can better mimic the patterns of drug diffusion, cell–cell signalling, and the presence of vasculature in tumours in vivo. Furthermore, the FDA Modernization Act 2.0 promotes the use of higher complexity in vitro models such as 3D cell cultures. By offering more accurate representations of human tissue, 3D culture platforms have the potential to enhance preclinical drug development and lead to safer and more effective cancer treatments. Prior to clinical trials, preclinical testing of oncology drug candidates is performed by evaluating drug candidates with in vitro and in vivo platforms. For in vivo testing, animal models are used to evaluate the toxicity and efficacy of drug candidates. However, animal models often display poor translational results as many drugs that pass preclinical testing fail when tested with humans, with oncology drugs exhibiting especially poor acceptance rates. The FDA Modernization Act 2.0 promotes alternative preclinical testing techniques, presenting the opportunity to use higher complexity in vitro models as an alternative to in vivo testing, including three-dimensional (3D) cell culture models. Three-dimensional tissue cultures address many of the shortcomings of 2D cultures by more closely replicating the tumour microenvironment through a combination of physiologically relevant drug diffusion, paracrine signalling, cellular phenotype, and vascularization that can better mimic native human tissue. This review will discuss the common forms of 3D cell culture, including cell spheroids, organoids, organs-on-a-chip, and 3D bioprinted tissues. Their advantages and limitations will be presented, aiming to discuss the use of these 3D models to accurately represent human tissue and as an alternative to animal testing. The use of 3D culture platforms for preclinical drug development is expected to accelerate as these platforms continue to improve in complexity, reliability, and translational predictivity. [ABSTRACT FROM AUTHOR]

Published

2023

49. Design and Implementation of an Accessible 3D Bioprinter: Benchmarking the Performance of a Home-Made Bioprinter against a Professional Bioprinter.

Author

D'Atanasio, Paolo, Fiaschini, Noemi, Rinaldi, Antonio, Zambotti, Alessandro, Cantini, Lorenzo, Mancuso, Mariateresa, and Antonelli, Francesca

Subjects

BIOPRINTING, 3-D printers, CELL growth, CELL survival, PROFESSIONAL employees, CELL culture

Abstract

The tremendous application potential of 3D bioprinting in the biomedical field is witnessed by the ever-increasing interest in this technology over the past few years. In particular, the possibility of obtaining 3D cellular models that mimic tissues with precision and reproducibility represents a definitive advance for in vitro studies dealing with the biological mechanisms of cell growth, death and proliferation and is at the basis of the responses of healthy and pathological tissues to drugs and therapies. However, the impact of 3D bioprinting on research is limited by the high costs of professional 3D bioprinters, which represent an obstacle to the widespread access and usability of this technology. In this work, we present a 3D bioprinter that was developed in-house by modifying a low-cost commercial 3D printer by replacing the default extruder used to print plastic filaments with a custom-made syringe extruder that is suitable for printing bioinks. The modifications made to the 3D printer include adjusting the size of the extruder to accommodate a 1 mL syringe and reducing the extruder's size above the printer. To validate the performance of the home-made bioprinter, some main printing characteristics, the cell vitality and the possibility of bioprinting CAD-designed constructs were benchmarked against a renowned professional 3D bioprinter by RegenHu. According to our findings, our in-house 3D bioprinter was mostly successful in printing a complex glioblastoma tumor model with good performances, and it managed to maintain a cell viability that was comparable to that achieved by a professional bioprinter. This suggests that an accessible open-source 3D bioprinter could be a viable option for research and development (R&D) laboratories interested in pre-commercial 3D bioprinting advancements. [ABSTRACT FROM AUTHOR]

Published

2023

50. Sustainable Biomass Lignin-Based Hydrogels: A Review on Properties, Formulation, and Biomedical Applications.

Author

Hachimi Alaoui, Chaymaa, Réthoré, Gildas, Weiss, Pierre, and Fatimi, Ahmed

Subjects

*POLYMER networks, *LIGNINS, *POLYMERS, *IONIC bonds, *HYDROGELS, *BIOPRINTING, *LIGNOCELLULOSE

Abstract

Different techniques have been developed to overcome the recalcitrant nature of lignocellulosic biomass and extract lignin biopolymer. Lignin has gained considerable interest owing to its attractive properties. These properties may be more beneficial when including lignin in the preparation of highly desired value-added products, including hydrogels. Lignin biopolymer, as one of the three major components of lignocellulosic biomaterials, has attracted significant interest in the biomedical field due to its biocompatibility, biodegradability, and antioxidant and antimicrobial activities. Its valorization by developing new hydrogels has increased in recent years. Furthermore, lignin-based hydrogels have shown great potential for various biomedical applications, and their copolymerization with other polymers and biopolymers further expands their possibilities. In this regard, lignin-based hydrogels can be synthesized by a variety of methods, including but not limited to interpenetrating polymer networks and polymerization, crosslinking copolymerization, crosslinking grafted lignin and monomers, atom transfer radical polymerization, and reversible addition–fragmentation transfer polymerization. As an example, the crosslinking mechanism of lignin–chitosan–poly(vinyl alcohol) (PVA) hydrogel involves active groups of lignin such as hydroxyl, carboxyl, and sulfonic groups that can form hydrogen bonds (with groups in the chemical structures of chitosan and/or PVA) and ionic bonds (with groups in the chemical structures of chitosan and/or PVA). The aim of this review paper is to provide a comprehensive overview of lignin-based hydrogels and their applications, focusing on the preparation and properties of lignin-based hydrogels and the biomedical applications of these hydrogels. In addition, we explore their potential in wound healing, drug delivery systems, and 3D bioprinting, showcasing the unique properties of lignin-based hydrogels that enable their successful utilization in these areas. Finally, we discuss future trends in the field and draw conclusions based on the findings presented. [ABSTRACT FROM AUTHOR]

Published

2023