CaltechAUTHORS
Published January 2024 | Published
Journal Article Open

Machine learning‐directed electrical impedance tomography to predict metabolically vulnerable plaques

Chen, Justin1 ORCID icon
Wang, Shaolei1 ORCID icon
Wang, Kaidong1 ORCID icon
Abiri, Parinaz1
Huang, Zi‐Yu2
Yin, Junyi1 ORCID icon
Jabalera, Alejandro M.1
Arianpour, Brian1
Roustaei, Mehrdad1 ORCID icon
Zhu, Enbo1
Zhao, Peng1
Cavallero, Susana1, 3 ORCID icon
Duarte‐Vogel, Sandra1
Stark, Elena1
Luo, Yuan2 ORCID icon
Benharash, Peyman1
Tai, Yu-Chong2 ORCID icon
Cui, Qingyu1
Hsiai, Tzung K.1, 2, 3 ORCID icon
  • 1. ROR icon University of California, Los Angeles
  • 2. ROR icon California Institute of Technology
  • 3. ROR icon VA Greater Los Angeles Healthcare System

Abstract

The characterization of atherosclerotic plaques to predict their vulnerability to rupture remains a diagnostic challenge. Despite existing imaging modalities, none have proven their abilities to identify metabolically active oxidized low-density lipoprotein (oxLDL), a marker of plaque vulnerability. To this end, we developed a machine learning-directed electrochemical impedance spectroscopy (EIS) platform to analyze oxLDL-rich plaques, with immunohistology serving as the ground truth. We fabricated the EIS sensor by affixing a six-point microelectrode configuration onto a silicone balloon catheter and electroplating the surface with platinum black (PtB) to improve the charge transfer efficiency at the electrochemical interface. To demonstrate clinical translation, we deployed the EIS sensor to the coronary arteries of an explanted human heart from a patient undergoing heart transplant and interrogated the atherosclerotic lesions to reconstruct the 3D EIS profiles of oxLDL-rich atherosclerotic plaques in both right coronary and left descending coronary arteries. To establish effective generalization of our methods, we repeated the reconstruction and training process on the common carotid arteries of an unembalmed human cadaver specimen. Our findings indicated that our DenseNet model achieves the most reliable predictions for metabolically vulnerable plaque, yielding an accuracy of 92.59% after 100 epochs of training.

Copyright and License

© 2023 The Authors. Bioengineering & Translational Medicine published by Wiley Periodicals LLC on behalf of American Institute of Chemical Engineers. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

Acknowledgement

This work was supported by the following grants from the National Institutes of Health: R01HL118650 (TKH) and R01HL149808 (TKH), National Institute of General Medical Sciences T32 GM008042 (PA), David Geffen School of Medicine Scholarship (PA), and the VA Greater Los Angeles Healthcare System Merit Award: I01 BX004356 (TKH). The authors wish to thank the UCLA Donated Body Program donors for their generosity in donating their remains to UCLA for education and research. The authors also thank the Donated Body Program staff for their assistance related to the use of the donors' remains in this study.

Contributions

Justin Chen: Conceptualization (lead); investigation (lead); writing – original draft (lead). Shaolei Wang: Data curation (equal); methodology (equal). Kaidong Wang: Methodology (equal). Parinaz Abiri: Investigation (equal); methodology (equal). Zi-Yu Huang: Investigation (equal); visualization (equal). Junyi Yin: Visualization (lead). Alejandro M Jabalera: Formal analysis (equal); writing – review and editing (equal). Brian Arianpour: Validation (equal); writing – review and editing (equal). Mehrdad Roustaei: Visualization (equal). Enbo Zhu: Visualization (supporting). Peng Zhao: Visualization (supporting). Susana Cavallero: Resources (lead). Sandra Duarte-Vogel: Investigation (equal). Elena Stark: Resources (equal). Yuan Luo: Investigation (equal). Peyman Benharash: Resources (equal). Yu-Chong Tai: Supervision (equal). Qingyu Cui: Supervision (equal). Tzung Hsiai: Conceptualization (equal); funding acquisition (lead); supervision (lead); writing – review and editing (lead).

Supplemental Material

Data S1. Supporting Information: btm210616-sup-0001-Supinfo.docx

Files

Bioengineering Transla Med - 2023 - Chen - Machine learning‐directed electrical impedance tomography to predict.pdf

Additional details

Funding Dates Caltech Custom Metadata
Created:
February 5, 2025
Modified:
February 5, 2025