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M-Denoiser: Unsupervised image denoising for real-world optical and electron microscopy data.

Xiaoya Chong1, Min Cheng2, Wenqi Fan3

  • 1Department of Computer Science, City University of Hong Kong, Hong Kong, China.

Computers in Biology and Medicine
|August 10, 2023
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Summary

M-Denoiser effectively removes noise from real-world microscopy images using an unsupervised approach. This method addresses limitations of existing algorithms by handling signal-dependent and spatially correlated noise, improving image quality.

Keywords:
Deep learningPoisson–Gaussian noiseReal-world microscopyUnsupervised denoising

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Area of Science:

  • Microscopy imaging
  • Computer vision
  • Image processing

Background:

  • Real-world microscopy images suffer from significant noise, including signal-dependent shot noise and signal-independent read noise, often modeled by Poisson-Gaussian distributions.
  • Noise in microscopy data is frequently spatially correlated due to the image acquisition process.
  • Existing unsupervised and self-supervised denoising methods often assume signal-independent or pixel-wise independent noise, which is unsuitable for real-world microscopy data.

Purpose of the Study:

  • To develop an unsupervised denoising method, M-Denoiser, specifically designed for real-world microscopy data.
  • To overcome the limitations of current denoising algorithms that fail to account for signal-dependent and spatially correlated noise.

Main Methods:

  • The proposed M-Denoiser utilizes a 'shatter module' to decorrelate noise before the denoising process.
  • A novel unsupervised training loss function is introduced, specifically designed for pairs of noisy microscopy images.
  • The model was trained and evaluated on both optical and electron microscopy datasets.

Main Results:

  • M-Denoiser demonstrated superior performance in denoising real-world microscopy images compared to existing baseline methods.
  • Quantitative and qualitative evaluations confirmed the effectiveness of the proposed method.
  • The shatter module and novel loss function contribute to improved denoising accuracy.

Conclusions:

  • M-Denoiser offers an effective unsupervised solution for denoising real-world microscopy images.
  • The method successfully addresses the challenges posed by signal-dependent and spatially correlated noise.
  • This advancement has the potential to improve the quality and utility of microscopy data in scientific research.