{"title":"基于约束的生物墨水前体贝叶斯优化:一种机器学习框架。","authors":"Yihao Xu, Rokeya Sarah, Ahasan Habib, Yongmin Liu, Bashir Khoda","doi":"10.1088/1758-5090/ad716e","DOIUrl":null,"url":null,"abstract":"<p><p>Current research practice for optimizing bioink involves exhaustive experimentation with multi-material composition for determining the printability, shape fidelity and biocompatibility. Predicting bioink properties can be beneficial to the research community but is a challenging task due to the non-Newtonian behavior in complex composition. Existing models such as Cross model become inadequate for predicting the viscosity for heterogeneous composition of bioinks. In this paper, we utilize a machine learning framework to accurately predict the viscosity of heterogeneous bioink compositions, aiming to enhance extrusion-based bioprinting techniques. Utilizing Bayesian optimization (BO), our strategy leverages a limited dataset to inform our model. This is a technique especially useful of the typically sparse data in this domain. Moreover, we have also developed a mask technique that can handle complex constraints, informed by domain expertise, to define the feasible parameter space for the components of the bioink and their interactions. Our proposed method is focused on predicting the intrinsic factor (e.g. viscosity) of the bioink precursor which is tied to the extrinsic property (e.g. cell viability) through the mask function. Through the optimization of the hyperparameter, we strike a balance between exploration of new possibilities and exploitation of known data, a balance crucial for refining our acquisition function. This function then guides the selection of subsequent sampling points within the defined viable space and the process continues until convergence is achieved, indicating that the model has sufficiently explored the parameter space and identified the optimal or near-optimal solutions. Employing this AI-guided BO framework, we have developed, tested, and validated a surrogate model for determining the viscosity of heterogeneous bioink compositions. This data-driven approach significantly reduces the experimental workload required to identify bioink compositions conducive to functional tissue growth. It not only streamlines the process of finding the optimal bioink compositions from a vast array of heterogeneous options but also offers a promising avenue for accelerating advancements in tissue engineering by minimizing the need for extensive experimental trials.</p>","PeriodicalId":8964,"journal":{"name":"Biofabrication","volume":" ","pages":""},"PeriodicalIF":8.2000,"publicationDate":"2024-08-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Constraint based Bayesian optimization of bioink precursor: a machine learning framework.\",\"authors\":\"Yihao Xu, Rokeya Sarah, Ahasan Habib, Yongmin Liu, Bashir Khoda\",\"doi\":\"10.1088/1758-5090/ad716e\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Current research practice for optimizing bioink involves exhaustive experimentation with multi-material composition for determining the printability, shape fidelity and biocompatibility. 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Our proposed method is focused on predicting the intrinsic factor (e.g. viscosity) of the bioink precursor which is tied to the extrinsic property (e.g. cell viability) through the mask function. Through the optimization of the hyperparameter, we strike a balance between exploration of new possibilities and exploitation of known data, a balance crucial for refining our acquisition function. This function then guides the selection of subsequent sampling points within the defined viable space and the process continues until convergence is achieved, indicating that the model has sufficiently explored the parameter space and identified the optimal or near-optimal solutions. Employing this AI-guided BO framework, we have developed, tested, and validated a surrogate model for determining the viscosity of heterogeneous bioink compositions. This data-driven approach significantly reduces the experimental workload required to identify bioink compositions conducive to functional tissue growth. 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引用次数: 0
摘要
目前,优化生物墨水的研究实践包括对多种材料成分进行详尽的实验,以确定其可印刷性、形状保真度和生物相容性。预测生物墨水的特性对研究界大有裨益,但由于复杂成分中的非牛顿行为,预测生物墨水的特性是一项极具挑战性的任务。现有模型(如 Cross 模型)不足以预测生物墨水异质成分的粘度。在本文中,我们利用机器学习框架来准确预测异质生物墨水成分的粘度,旨在提高基于挤压的生物打印技术。利用贝叶斯优化(BO),我们的策略是利用有限的数据集为我们的模型提供信息。这种技术对该领域典型的稀疏数据尤为有用。此外,我们还开发了一种掩膜技术,可以处理复杂的约束条件,并通过领域专业知识来定义生物墨水成分及其相互作用的可行参数空间。我们提出的方法侧重于预测生物墨水前体的内在因素(如粘度),通过掩膜函数将其与外在特性(如细胞活力)联系起来。通过优化超参数,我们在探索新的可能性和利用已知数据之间取得了平衡,这种平衡对于完善我们的采集功能至关重要。然后,该函数将指导在已定义的可行空间内选择后续采样点,这一过程一直持续到收敛为止,表明模型已充分探索了参数空间,并确定了最优或接近最优的解决方案。利用这种人工智能指导的 BO 框架,我们开发、测试并验证了一种用于确定异质生物墨水成分粘度的替代模型。这种数据驱动方法大大减少了确定有利于功能性组织生长的生物墨水成分所需的实验工作量。它不仅简化了从大量异质选择中寻找最佳生物墨水成分的过程,而且通过最大限度地减少对大量实验的需求,为加快组织工程的发展提供了一条大有可为的途径。
Constraint based Bayesian optimization of bioink precursor: a machine learning framework.
Current research practice for optimizing bioink involves exhaustive experimentation with multi-material composition for determining the printability, shape fidelity and biocompatibility. Predicting bioink properties can be beneficial to the research community but is a challenging task due to the non-Newtonian behavior in complex composition. Existing models such as Cross model become inadequate for predicting the viscosity for heterogeneous composition of bioinks. In this paper, we utilize a machine learning framework to accurately predict the viscosity of heterogeneous bioink compositions, aiming to enhance extrusion-based bioprinting techniques. Utilizing Bayesian optimization (BO), our strategy leverages a limited dataset to inform our model. This is a technique especially useful of the typically sparse data in this domain. Moreover, we have also developed a mask technique that can handle complex constraints, informed by domain expertise, to define the feasible parameter space for the components of the bioink and their interactions. Our proposed method is focused on predicting the intrinsic factor (e.g. viscosity) of the bioink precursor which is tied to the extrinsic property (e.g. cell viability) through the mask function. Through the optimization of the hyperparameter, we strike a balance between exploration of new possibilities and exploitation of known data, a balance crucial for refining our acquisition function. This function then guides the selection of subsequent sampling points within the defined viable space and the process continues until convergence is achieved, indicating that the model has sufficiently explored the parameter space and identified the optimal or near-optimal solutions. Employing this AI-guided BO framework, we have developed, tested, and validated a surrogate model for determining the viscosity of heterogeneous bioink compositions. This data-driven approach significantly reduces the experimental workload required to identify bioink compositions conducive to functional tissue growth. It not only streamlines the process of finding the optimal bioink compositions from a vast array of heterogeneous options but also offers a promising avenue for accelerating advancements in tissue engineering by minimizing the need for extensive experimental trials.
期刊介绍:
Biofabrication is dedicated to advancing cutting-edge research on the utilization of cells, proteins, biological materials, and biomaterials as fundamental components for the construction of biological systems and/or therapeutic products. Additionally, it proudly serves as the official journal of the International Society for Biofabrication (ISBF).