T R Angeli1, G O'Grady1,2, R Vather2, I P Bissett2, L K Cheng1,3. 1. Auckland Bioengineering Institute, University of Auckland, Auckland, New Zealand. 2. Department of Surgery, University of Auckland, Auckland, New Zealand. 3. Department of Surgery, Vanderbilt University, Nashville, TN, USA.
Abstract
BACKGROUND: Bioelectrical slow waves are a coordinating mechanism of small intestine motility, but extracellular human studies have been restricted to a limited number of sparse electrode recordings. High-resolution (HR) mapping has offered substantial insights into spatiotemporal intestinal slow wave dynamics, but has been limited to animal studies to date. This study aimed to translate intra-operative HR mapping to define pacemaking and conduction profiles in the human small intestine. METHODS: Immediately following laparotomy, flexible-printed-circuit arrays were applied around the serosa of the proximal jejunum (128-256 electrodes; 4-5.2 mm spacing; 28-59 cm2 ). Slow wave propagation patterns were mapped, and frequencies, amplitudes, downstroke widths, and velocities were calculated. Pacemaking and propagation patterns were defined. KEY RESULTS: Analysis comprised nine patients with mean recording duration of 7.6 ± 2.8 minutes. Slow waves occurred at a frequency of 9.8 ± 0.4 cpm, amplitude 0.3 ± 0.04 mV, downstroke width 0.5 ± 0.1 seconds, and with faster circumferential velocity than longitudinal (10.1 ± 0.8 vs 9.0 ± 0.7 mm/s; P = .001). Focal pacemakers were identified and mapped (n = 4; mean frequency 9.9 ± 0.2 cpm). Disordered slow wave propagation was observed, including wavefront collisions, conduction blocks, and breakout and entrainment of pacemakers. CONCLUSIONS & INFERENCES: This study introduces HR mapping of human intestinal slow waves, and provides first descriptions of intestinal pacemaker sites and velocity anisotropy. Future translation to other intestinal regions, disease states, and postsurgical dysmotility holds potential for improving the basic and clinical understanding of small intestine pathophysiology.
BACKGROUND: Bioelectrical slow waves are a coordinating mechanism of small intestine motility, but extracellular human studies have been restricted to a limited number of sparse electrode recordings. High-resolution (HR) mapping has offered substantial insights into spatiotemporal intestinal slow wave dynamics, but has been limited to animal studies to date. This study aimed to translate intra-operative HR mapping to define pacemaking and conduction profiles in the human small intestine. METHODS: Immediately following laparotomy, flexible-printed-circuit arrays were applied around the serosa of the proximal jejunum (128-256 electrodes; 4-5.2 mm spacing; 28-59 cm2 ). Slow wave propagation patterns were mapped, and frequencies, amplitudes, downstroke widths, and velocities were calculated. Pacemaking and propagation patterns were defined. KEY RESULTS: Analysis comprised nine patients with mean recording duration of 7.6 ± 2.8 minutes. Slow waves occurred at a frequency of 9.8 ± 0.4 cpm, amplitude 0.3 ± 0.04 mV, downstroke width 0.5 ± 0.1 seconds, and with faster circumferential velocity than longitudinal (10.1 ± 0.8 vs 9.0 ± 0.7 mm/s; P = .001). Focal pacemakers were identified and mapped (n = 4; mean frequency 9.9 ± 0.2 cpm). Disordered slow wave propagation was observed, including wavefront collisions, conduction blocks, and breakout and entrainment of pacemakers. CONCLUSIONS & INFERENCES: This study introduces HR mapping of human intestinal slow waves, and provides first descriptions of intestinal pacemaker sites and velocity anisotropy. Future translation to other intestinal regions, disease states, and postsurgical dysmotility holds potential for improving the basic and clinical understanding of small intestine pathophysiology.
Authors: Tim H-H Wang; Timothy R Angeli; Grant Beban; Peng Du; Francesca Bianco; Simon J Gibbons; John A Windsor; Leo K Cheng; Gregory O'Grady Journal: Am J Physiol Gastrointest Liver Physiol Date: 2019-06-06 Impact factor: 4.052
Authors: Anthony Y Lin; Chris Varghese; Peng Du; Cameron I Wells; Niranchan Paskaranandavadivel; Armen A Gharibans; Jonathan C Erickson; Ian P Bissett; Greg O'Grady Journal: Biomed Eng Online Date: 2021-10-16 Impact factor: 2.819
Authors: Zahra Aghababaie; Niranchan Paskaranandavadivel; Satya Amirapu; Chih-Hsiang Alexander Chan; Peng Du; Samuel J Asirvatham; Gianrico Farrugia; Arthur Beyder; Gregory O'Grady; Leo K Cheng; Timothy R Angeli-Gordon Journal: Am J Physiol Gastrointest Liver Physiol Date: 2021-01-20 Impact factor: 4.052