研究目的
To accurately reveal 3D distribution of bioluminescent sources from limited boundary measurement by proposing an iterative reconstruction method incorporating adaptive algebraic reconstruction technique (AART) and adaptively shrinking permissible source region.
研究成果
The proposed iterative reconstruction method incorporating AART and adaptively shrinking permissible source region accurately reconstructs the bioluminescent source without the permissible source region and multispectral measurements, improving the stability of the inverse algorithm.
研究不足
The in vivo experiment is not as accurate as the simulations, possibly due to errors in mapping the energy distribution from 2D images to the 3D mouse surface and only main organs being reserved for building a heterogeneous model.
1:Experimental Design and Method Selection:
The study employs an iterative reconstruction method incorporating adaptive algebraic reconstruction technique (AART) and adaptively shrinking permissible source region to solve the inverse problem of BLT.
2:Sample Selection and Data Sources:
A 3D digital mouse model and an in vivo experiment with a luminescent light stick sewn into the abdomen of a mouse are used.
3:List of Experimental Equipment and Materials:
The digital mouse model consists of six organs with specified optical properties. A cylinder with a radius of
4:8 mm and a height of 0 mm is used to simulate the bioluminescent source. Experimental Procedures and Operational Workflow:
The method involves calculating the system matrix, initializing parameters, employing AART for iterative minimization, updating the permissible region based on the solution distribution, and stopping the iteration when the error is smaller than a threshold or the iteration number exceeds a default value.
5:Data Analysis Methods:
The performance is evaluated based on the distance error (DE) and reconstructed power.
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