SEMPAI: a Self‐Enhancing Multi‐Photon Artificial Intelligence for Prior‐Informed Assessment of Muscle Function and Pathology
Technology
Chemistry, Multidisciplinary
Science
Materials Science
MODELS
Materials Science, Multidisciplinary
BIOMECHATRONICS
CLASSIFICATION
meta-learning
Deep Learning
Artificial Intelligence
ALGORITHM
Nanoscience & Nanotechnology
ULTRASOUND
Research Articles
muscle research
Science & Technology
scientific machine learning
explainable artificial intelligence
Muscles
Q
deep learning
MICROSCOPY
BIOMECHANICS
CANCER
meta‐learning
prior information integration
Chemistry
PATTERN
Physical Sciences
multiphoton microscopy
Science & Technology - Other Topics
SKELETAL-MUSCLE
Neural Networks, Computer
Algorithms
DOI:
10.1002/advs.202206319
Publication Date:
2023-08-19T04:39:42Z
AUTHORS (16)
ABSTRACT
AbstractDeep learning (DL) shows notable success in biomedical studies. However, most DL algorithms work as black boxes, exclude biomedical experts, and need extensive data. This is especially problematic for fundamental research in the laboratory, where often only small and sparse data are available and the objective is knowledge discovery rather than automation. Furthermore, basic research is usually hypothesis‐driven and extensive prior knowledge (priors) exists. To address this, the Self‐Enhancing Multi‐Photon Artificial Intelligence (SEMPAI) that is designed for multiphoton microscopy (MPM)‐based laboratory research is presented. It utilizes meta‐learning to optimize prior (and hypothesis) integration, data representation, and neural network architecture simultaneously. By this, the method allows hypothesis testing with DL and provides interpretable feedback about the origin of biological information in 3D images. SEMPAI performs multi‐task learning of several related tasks to enable prediction for small datasets. SEMPAI is applied on an extensive MPM database of single muscle fibers from a decade of experiments, resulting in the largest joint analysis of pathologies and function for single muscle fibers to date. It outperforms state‐of‐the‐art biomarkers in six of seven prediction tasks, including those with scarce data. SEMPAI's DL models with integrated priors are superior to those without priors and to prior‐only approaches.
SUPPLEMENTAL MATERIAL
Coming soon ....
REFERENCES (81)
CITATIONS (1)
EXTERNAL LINKS
PlumX Metrics
RECOMMENDATIONS
FAIR ASSESSMENT
Coming soon ....
JUPYTER LAB
Coming soon ....