Computational Methods for Biofabrication in Tissue Engineering and Regenerative Medicine - a literature review

Bardini, Roberta; Carlo, Stefano Di

doi:10.1101/2023.03.03.530995

Cited by 5 publications

(4 citation statements)

References 169 publications

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“…In recent decades, new tools termed “computational methods” have allowed a change in the paradigm of the established “trial and error” by the “rational design” of HGs [ 174 ]. With regard to trial and error, previously only once the HG had been prepared in the laboratory was it possible to evidence the real release efficacy of a specific therapeutic agent [ 175 ].…”

Section: In Silico Modeling To Optimize Hg Designmentioning

confidence: 99%

Delivery Systems in Ocular Retinopathies: The Promising Future of Intravitreal Hydrogels as Sustained-Release Scaffolds

et al. 2023

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Slow-release delivery systems are needed to ensure long-term sustained treatments for retinal diseases such as age-related macular degeneration and diabetic retinopathy, which are currently treated with anti-angiogenic agents that require frequent intraocular injections. These can cause serious co-morbidities for the patients and are far from providing the adequate drug/protein release rates and required pharmacokinetics to sustain prolonged efficacy. This review focuses on the use of hydrogels, particularly on temperature-responsive hydrogels as delivery vehicles for the intravitreal injection of retinal therapies, their advantages and disadvantages for intraocular administration, and the current advances in their use to treat retinal diseases.

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Section: In Silico Modeling To Optimize Hg Designmentioning

confidence: 99%

Delivery Systems in Ocular Retinopathies: The Promising Future of Intravitreal Hydrogels as Sustained-Release Scaffolds

et al. 2023

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“…Computational methods have a key role in the analysis [7], [8], modeling [9], [10], design [1] and optimization [11], [12], [13] of complex biological processes. In particular, for analyzing and predicting the dynamics of multicellular synthetic systems, computational tools must offer instruments for modeling and simulation, accounting for multiple spatial and temporal scales [14].…”

Section: Introductionmentioning

confidence: 99%

Biology System Description Language (BiSDL): a modeling language for the design of multicellular synthetic biological systems

Giannantoni,

Bardini,

Savino

et al. 2024

Preprint

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Background: The Biology System Description Language (BiSDL) is an accessible, easy-to-use computational language for multicellular synthetic biology. It allows synthetic biologists to represent spatiality and multi-level cellular dynamics inherent to multicellular designs, filling a gap in the state of the art. Developed for designing and simulating spatial, multicellular synthetic biological systems, BiSDL integrates high-level conceptual design with detailed low-level modeling, fostering collaboration in the Design-Build-Test-Learn cycle. BiSDL descriptions directly compile into Nets-Within-Nets (NWNs) models, offering a unique approach to spatial and hierarchical modeling in biological systems. Results: BiSDL's effectiveness is showcased through two case studies on complex multicellular systems: a bacterial consortium and a synthetic morphogen system. These studies highlight the BiSDL proficiency in representing spatial interactions and multi-level cellular dynamics. The language facilitates the compilation of conceptual designs into detailed, simulatable models, leveraging the NWNs formalism. This enables intuitive modeling of complex biological systems, making advanced computational tools more accessible to a broader range of researchers. Conclusions: BiSDL represents a significant step forward in computational languages for synthetic biology, providing a sophisticated yet user-friendly tool for the design and simulation of complex biological systems with an emphasis on spatiality and cellular dynamics. Its introduction has the potential to transform research and development in synthetic biology, allowing for deeper insights and novel applications in understanding and manipulating multicellular systems.

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“…In particular, computational modeling and optimization exploit the power of computation to explore system behavior and to conduct systematic DSE, accounting for the relations between complex parameter configurations and process outputs. To impact the biofabrication domain, computational approaches must rely on white-box models of the physical process to explicitly represent the relations between the generated protocols and the biological mechanisms modeled [17]. Nevertheless, most computational approaches to biofabrication overlook biological complexity and primarily focus on the non-living components of the process.…”

Section: Introductionmentioning

confidence: 99%

“…They enable systematic DSE, considering complex parameter interactions and process outputs. Effective computational approaches require white-box models that represent biological processes accurately [14]. However, current models often neglect biological complexity, leading to large state spaces and necessitating metaheuristics for feasibility [15, 16].…”

Section: Introductionmentioning

confidence: 99%

A methodology combining reinforcement learning and simulation to optimize thein silicoculture of epithelial sheets

Castrignanò

Bardini

Savino

et al. 2023

Preprint

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Tissue Engineering and Regenerative Medicine aim to replicate and replace tissues for curing disease. However, full tissue integration and homeostasis are still far from reach. Biofabrication is an emerging field that identifies the processes required for generating biologically functional products with the desired structural organization and functionality and can potentially revolutionize the regenerative medicine domain, which aims to use patients' cells to restore the structure and function of damaged tissues and organs. However, biofabrication still has limitations in the quality of processes and products. Biofabrication processes are often improved empirically, but this is slow, costly, and provides partial results. Computational approaches can tap into biofabrication underused potential, supporting analysis, modeling, design, and optimization of biofabrication processes, speeding up their improvement towards a higher quality of products and subsequent higher clinical relevance. This work proposes a reinforcement learning-based computational design space exploration methodology to generate optimal protocols for the simulated fabrication of epithelial sheets. The optimization strategy relies on a deep reinforcement learning algorithm, the Advantage-Actor Critic, which relies on a neural network model for learning. In contrast, simulations rely on the PalaCell2D simulation framework. Validation demonstrates the proposed approach on two protocol generation targets: maximizing the final number of obtained cells and optimizing the spatial organization of the cell aggregate.Advantage-Actor Critic, which relies on a neural network model for learning. In contrast, simulations rely on the PalaCell2D simulation framework. Validation demonstrates the proposed approach on two protocol generation targets: maximizing the final number of obtained cells and optimizing the spatial organization of the cell aggregate.

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Computational Methods for Biofabrication in Tissue Engineering and Regenerative Medicine - a literature review

Cited by 5 publications

References 169 publications

Delivery Systems in Ocular Retinopathies: The Promising Future of Intravitreal Hydrogels as Sustained-Release Scaffolds

Delivery Systems in Ocular Retinopathies: The Promising Future of Intravitreal Hydrogels as Sustained-Release Scaffolds

Biology System Description Language (BiSDL): a modeling language for the design of multicellular synthetic biological systems

A methodology combining reinforcement learning and simulation to optimize thein silicoculture of epithelial sheets

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