Daniel A Carson1, Greg O'Grady1,2, Peng Du2,3, Armen A Gharibans1,2, Christopher N Andrews4. 1. Department of Surgery, University of Auckland, Auckland, New Zealand. 2. Auckland Bioengineering Institute, University of Auckland, Auckland, New Zealand. 3. Department of Engineering Science, University of Auckland, Auckland, New Zealand. 4. Department of Medicine, University of Calgary, Calgary, AB, Canada.
Abstract
BACKGROUND: Gastric motility disorders, which include both functional and organic etiologies, are highly prevalent. However, there remains a critical lack of objective biomarkers to guide efficient diagnostics and personalized therapies. Bioelectrical activity plays a fundamental role in coordinating gastric function and has been investigated as a contributing mechanism to gastric dysmotility and sensory dysfunction for a century. However, conventional electrogastrography (EGG) has not achieved common clinical adoption due to its perceived limited diagnostic capability and inability to impact clinical care. The last decade has seen the emergence of novel high-resolution methods for invasively mapping human gastric electrical activity in health and disease, providing important new insights into gastric physiology. The limitations of EGG have also now become clearer, including the finding that slow-wave frequency alone is not a reliable discriminator of gastric dysrhythmia, shifting focus instead toward altered spatial patterns. Recently, advances in bioinstrumentation, signal processing, and computational modeling have aligned to allow non-invasive body surface mapping of the stomach to detect spatiotemporal gastric dysrhythmias. The clinical relevance of this emerging strategy to improve diagnostics now awaits determination. PURPOSE: This review evaluates these recent advances in clinical gastric electrophysiology, together with promising emerging data suggesting that novel gastric electrical signatures recorded at the body surface (termed "body surface mapping") may correlate with symptoms. Further technological progress and validation data are now awaited to determine whether these advances will deliver on the promise of clinical gastric electrophysiology diagnostics.
BACKGROUND: Gastric motility disorders, which include both functional and organic etiologies, are highly prevalent. However, there remains a critical lack of objective biomarkers to guide efficient diagnostics and personalized therapies. Bioelectrical activity plays a fundamental role in coordinating gastric function and has been investigated as a contributing mechanism to gastric dysmotility and sensory dysfunction for a century. However, conventional electrogastrography (EGG) has not achieved common clinical adoption due to its perceived limited diagnostic capability and inability to impact clinical care. The last decade has seen the emergence of novel high-resolution methods for invasively mapping human gastric electrical activity in health and disease, providing important new insights into gastric physiology. The limitations of EGG have also now become clearer, including the finding that slow-wave frequency alone is not a reliable discriminator of gastric dysrhythmia, shifting focus instead toward altered spatial patterns. Recently, advances in bioinstrumentation, signal processing, and computational modeling have aligned to allow non-invasive body surface mapping of the stomach to detect spatiotemporal gastric dysrhythmias. The clinical relevance of this emerging strategy to improve diagnostics now awaits determination. PURPOSE: This review evaluates these recent advances in clinical gastric electrophysiology, together with promising emerging data suggesting that novel gastric electrical signatures recorded at the body surface (termed "body surface mapping") may correlate with symptoms. Further technological progress and validation data are now awaited to determine whether these advances will deliver on the promise of clinical gastric electrophysiology diagnostics.
Authors: Michael Camilleri; Braden Kuo; Linda Nguyen; Vida M Vaughn; Jessica Petrey; Katarina Greer; Rena Yadlapati; Thomas L Abell Journal: Am J Gastroenterol Date: 2022-06-03 Impact factor: 12.045
Authors: Sameer Bhat; Chris Varghese; Daniel A Carson; Tommy C L Hayes; Armen A Gharibans; Christopher N Andrews; Gregory O'Grady Journal: Esophagus Date: 2021-02-16 Impact factor: 4.230
Authors: Khaled Ammar; Chris Varghese; Thejasvin K; Viswakumar Prabakaran; Stuart Robinson; Samir Pathak; Bobby V M Dasari; Sanjay Pandanaboyana Journal: BJS Open Date: 2021-11-09
Authors: Gabrielle Sebaratnam; Nikita Karulkar; Stefan Calder; Jonathan S T Woodhead; Celia Keane; Daniel A Carson; Chris Varghese; Peng Du; Stephen J Waite; Jan Tack; Christopher N Andrews; Elizabeth Broadbent; Armen A Gharibans; Greg O'Grady Journal: Neurogastroenterol Motil Date: 2022-02-13 Impact factor: 3.960