BlenderPhotonics：一个用于复杂组织三维网格划分和光子模拟的集成开源软件环境。

BlenderPhotonics: an integrated open-source software environment for three-dimensional meshing and photon simulations in complex tissues.

作者信息

Zhang Yuxuang, Fang Qianqian

机构信息

Northeastern University, Department of Bioengineering, Boston, Massachusetts, United States.

Northeastern University, Department of Electrical and Computer Engineering, Boston, Massachusetts, United States.

出版信息

J Biomed Opt. 2022 Apr;27(8). doi: 10.1117/1.JBO.27.8.083014.

DOI:10.1117/1.JBO.27.8.083014

PMID:35429155

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9010662/

Abstract

SIGNIFICANCE

Rapid advances in biophotonics techniques require quantitative, model-based computational approaches to obtain functional and structural information from increasingly complex and multiscaled anatomies. The lack of efficient tools to accurately model tissue structures and subsequently perform quantitative multiphysics modeling greatly impedes the clinical translation of these modalities.

AIM

Although the mesh-based Monte Carlo (MMC) method expands our capabilities in simulating complex tissues using tetrahedral meshes, the generation of such domains often requires specialized meshing tools, such as Iso2Mesh. Creating a simplified and intuitive interface for tissue anatomical modeling and optical simulations is essential toward making these advanced modeling techniques broadly accessible to the user community.

APPROACH

We responded to the above challenge by combining the powerful, open-source three-dimensional (3D) modeling software, Blender, with state-of-the-art 3D mesh generation and MC simulation tools, utilizing the interactive graphical user interface in Blender as the front-end to allow users to create complex tissue mesh models and subsequently launch MMC light simulations.

RESULTS

Here, we present a tutorial to our Python-based Blender add-on-BlenderPhotonics-to interface with Iso2Mesh and MMC, which allows users to create, configure and refine complex simulation domains and run hardware-accelerated 3D light simulations with only a few clicks. We provide a comprehensive introduction to this tool and walk readers through five examples, ranging from simple shapes to sophisticated realistic tissue models.

CONCLUSIONS

BlenderPhotonics is user friendly and open source, and it leverages the vastly rich ecosystem of Blender. It wraps advanced modeling capabilities within an easy-to-use and interactive interface. The latest software can be downloaded at http://mcx.space/bp.

摘要

意义

生物光子学技术的快速发展需要基于模型的定量计算方法，以便从日益复杂和多尺度的解剖结构中获取功能和结构信息。缺乏能够准确模拟组织结构并随后进行定量多物理场建模的有效工具，极大地阻碍了这些技术的临床转化。

目的

尽管基于网格的蒙特卡罗（MMC）方法扩展了我们使用四面体网格模拟复杂组织的能力，但生成这样的区域通常需要专门的网格划分工具，如Iso2Mesh。为组织解剖建模和光学模拟创建一个简化且直观的界面，对于使这些先进的建模技术能够被广大用户群体广泛使用至关重要。

方法

我们通过将功能强大的开源三维（3D）建模软件Blender与最先进的3D网格生成和MC模拟工具相结合，应对上述挑战，利用Blender中的交互式图形用户界面作为前端，允许用户创建复杂的组织网格模型并随后启动MMC光模拟。

结果

在此，我们展示了一个基于Python的Blender插件——BlenderPhotonics的教程，它可与Iso2Mesh和MMC接口，允许用户只需点击几下就能创建、配置和优化复杂的模拟区域，并运行硬件加速的3D光模拟。我们对该工具进行了全面介绍，并引导读者了解五个示例，从简单形状到复杂的逼真组织模型。

结论

BlenderPhotonics用户友好且开源，它利用了Blender极为丰富的生态系统。它将先进的建模功能封装在一个易于使用的交互式界面中。最新软件可从http://mcx.space/bp下载。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e646/9010662/60f3819ba0ce/JBO-027-083014-g001.jpg

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BlenderPhotonics：一个用于复杂组织三维网格划分和光子模拟的集成开源软件环境。

BlenderPhotonics: an integrated open-source software environment for three-dimensional meshing and photon simulations in complex tissues.

作者信息

机构信息

出版信息

SIGNIFICANCE

AIM

APPROACH

RESULTS

CONCLUSIONS

意义

目的

方法

结果

结论

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