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Deep image prior for undersampling high-speed photoacoustic microscopy.

Tri Vu1, Anthony DiSpirito1, Daiwei Li1

  • 1Photoacoustic Imaging Lab, Duke University, Durham, NC, 27708, USA.

Photoacoustics
|April 26, 2021
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Summary

Deep image prior (DIP) enhances undersampled photoacoustic microscopy (PAM) images without extensive training. This fast, flexible deep learning method significantly improves image quality using minimal data, outperforming traditional techniques.

Keywords:
Convolutional neural networkDeep image priorDeep learningHigh-speed imagingPhotoacoustic microscopyRaster scanningUndersampling

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Area of Science:

  • Biomedical Imaging
  • Optics and Photonics
  • Machine Learning Applications

Background:

  • Photoacoustic microscopy (PAM) combines light and ultrasound for imaging.
  • High-speed PAM often undersamples data to increase imaging speed.
  • Existing deep learning (DL) methods for sparse PAM require extensive training data and time.

Purpose of the Study:

  • To introduce deep image prior (DIP) for improving image quality in undersampled PAM.
  • To demonstrate a DL approach that bypasses the need for pre-training and ground truth data.
  • To enable fast and flexible image enhancement for high-speed imaging.

Main Methods:

  • Implementation of deep image prior (DIP) for image reconstruction.
  • Application of DIP to sparsely sampled, high-speed photoacoustic microscopy data.
  • Evaluation of DIP performance against interpolation and supervised DL methods.

Main Results:

  • Substantial improvement in PAM image quality was achieved with only 1.4% of fully sampled pixels.
  • The DIP approach significantly outperformed traditional interpolation methods.
  • DIP demonstrated competitive performance compared to pre-trained supervised DL models.

Conclusions:

  • Deep image prior (DIP) offers an efficient and effective solution for enhancing undersampled PAM images.
  • DIP's ability to work without pre-training or ground truth makes it highly adaptable.
  • The proposed method shows promise for various high-speed, undersampling imaging modalities.