IMFSegNet

The amount of fat in muscle tissue affects how well a muscle works. To distinguish fat from muscle tissue, ORO staining is utilized, as fat yields in a highly saturated red tone with the surrounding muscle tissue in a purple-blue to pale pink tone. Additionally, experts can distinguish fat areas, as well as fatless holes and cracks, from an easy-to-apply and cost-effective standard H&E-stained muscle section.

In this project, quantitative imaging with deep learning is employed to evaluate histological muscle samples with regard to their fat amount.

Stained muscle tissue. (A) Oil Red O (ORO) and (B) hematoxylin and eosin (H&E) stained muscle section. ORO (A) was performed on tissue sections from the adjacent H&E stained (B) tissue sections. The orange arrows indicate a crack. The blue and green arrow denotes the intramuscular fat. The red arrow indicates staining-related bleeding.

In order to know exactly what is really fat, our experimental collaborators manually annotated the H&E images of the muscle sections in ImageJ with the help of adjacent samples stained with ORO serving as additional references for a precise annotation. The quality of these manual annotations must be of the highest standard, which typically requires a workload of several hours to days.

Method comparison of segmentation of whole muscle tissue. Left: A) Stained tissue section. B) Intensity-based thresholding. C) Closing of perforated structures with a subsequent morphological closing operator. D) Manual annotation from experts. E) k-means clustering tends to over-detect fat. F) ilastik detects fat predominantly at the boundary of fat tissue and ruptures. G) Cellpose yielded more false-positive errors. H) IMFSegNet overlaps the most with the manual annotations. Right: For all metrics, SegNet retrained (IMFSegNet) on all available samples produced the significantly best results compared to all other methods. Stars correspond to: *=p-value < 0.05, ** =p-value < 0.01, ***=p-value < 0.001.

A variety of automated image analysis approaches were evaluated for the purpose of segmenting intramuscular fat (IMF), including intensity-based k-means clustering, the machine learning-based segmentation tool ilastik, the deep learning-based tool Cellpose, the convolutional neural network SegNet in the scope of a cross-validation, and the SegNet model retrained on all the available data. These techniques were compared to manual annotations from experts in order to assess their efficacy. The key performance indicators employed for this analysis included the Dice coefficient, precision, recall, Pearson’s correlation coefficient, and Hausdorff distance.
The results demonstrated that traditional methods such as k-means clustering and ilastik exhibited limitations in terms of accuracy. In contrast, deep learning approaches, particularly the retrained SegNet model (IMFSegNet), demonstrated superior performance, achieving balanced precision and recall, high correlation with manual annotations, and lower Hausdorff distances. Furthermore, IMFSegNet exhibited robustness across varied staining intensities, making it a cost-effective and reliable tool for analysing IMF in muscle tissues.

Comparison of K-means clustering and IMFSegNet. Left: Examples of muscle tissue sections with two different treatments. k-means clustering tends to over-detect fat. Right: The measured fat amount differs significantly between k-means and IMFSegNet in both groups. While the IMFSegNet has no significant differences k-means clustering differs significantly. White dots denote mean values (with dot) and black lines denote the median (middle line). Stars correspond to: *=p-value < 0.05

To demonstrate the strength of IMFSegNet, the method was tested with a real data set and compared to k-means clustering. The standard deviation of the k-means clustering was found to be significantly larger, indicating greater variation and lower accuracy compared to the IMFSegNet method. The mean fat amount was found to be significantly higher with k-means clustering than with IMFSegNet, which demonstrates the tendency of k-means to overdetection. The use of IMFSegNet for automated analysis was found to be faster and more accurate than manual annotation and k-means clustering. This approach provides a reliable method for large-scale quantitative imaging, supporting the development and clinical implementation of such techniques.

Experimental Collaborators

Publications

Impact of functional electrical stimulation on nerve-damaged muscles by quantifying fat infiltration using deep learning

Walluks, K.*, Praetorius*, JP., Arnold, D. #, Figge, M. T.# *contributed equally and #contributed equally

Quantitative imaging in life sciences has evolved into a powerful approach combining advanced microscopy acquisition and automated analysis of image data. The focus of the present study is on the imaging-based evaluation of the posterior cricoarytenoid muscle (PCA) influenced by long-term functional electrical stimulation (FES), which may assist the inspiration of patients with bilateral vocal […]
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IMFSegNet: Cost-effective and objective quantification of intramuscular fat in histological sections by deep learning.

Praetorius JP, Walluks K, Svensson CM, Arnold D, Figge MT#

The assessment of muscle condition is of great importance in various research areas. In particular, evaluating the degree of intramuscular fat (IMF) in tissue sections is a challenging task, which today is still mostly performed qualitatively or quantitatively by a highly subjective and error-prone manual analysis. We here realize the mission to make automated IMF […]
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JIPipe: Visual batch processing for ImageJ.

Gerst R*, Cseresnyés Z*, Figge MT#

The continuous development of new microscopy techniques requires the parallel evolution of image analysis workflows. ImageJ provides a high level of accessibility to bioimage processing, which is still impeded by the necessity of developing scripts to achieve reproducibility, and to comply to the FAIR principles. We provide a visual language termed JIPipe that allows the […]
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Posters

JIPipe: Designing automated image analysispipelines without programming

JIPipe: Designing automated image analysis
pipelines without programming
JIPipe: Designing automated image analysis pipelines without programming

JIPipe: Designing automated image analysis pipelines without programming
JIPipe: Designing automated image analysis pipelines without programming

JIPipe: Designing automated image analysis pipelines without programming
12335 Next

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