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Abstract

The human stomach breaks down and transports food by coordinated radial contractions of the gastric walls. The radial contractions periodically propagate through the stomach and constitute the peristaltic contractions, also called the gastric motility. The force, amplitude, and frequency of peristaltic contractions are relevant to massaging and transporting the food contents in the gastric lumen. However, existing gastric simulators have not faithfully replicated gastric motility. Herein, we report a soft robotic gastric simulator (SoGut) that emulates peristaltic contractions in an anatomically realistic way. SoGut incorporates an array of circular air chambers that generate radial contractions. The design and fabrication of SoGut leverages principles from the soft robotics field, which features compliance and adaptability. We studied the force and amplitude of the contractions when the lumen of SoGut was empty or filled with contents of different viscosity. We examined the contracting force using manometry. SoGut exhibited a similar range of contracting force as the human stomach reported in the literature. Besides, we investigated the amplitude of the contractions through videofluoroscopy where the contraction ratio was derived. The contraction ratio as a function of inflation pressure is found to match the observations of in vivo situations. We demonstrated that SoGut can achieve in vitro peristaltic contractions by coordinating the inflation sequence of multiple air chambers. It exhibited the functions to massage and transport the food contents. SoGut can simulate the physiological motions of the human stomach to advance research of digestion.

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References

Whitesides

. Soft robotics. Angew Chem Int Ed, 2018; 57:4258–4273.

Rus

, Tolley

. Design, fabrication and control of soft robots. Nature, 2015; 521:467–475.

Verl

, Albu-Schäffer

, Brock

, et al. Soft Robotics: Transferring Theory to Application. Berlin, Germany: Springer-Verlag, 2015.

Deimel

, Brock

. A novel type of compliant and underactuated robotic hand for dexterous grasping. Int J Rob Res, 2015; 35:161–185.

Polygerinos

, Wang

, Galloway

, et al. Soft robotic glove for combined assistance and at-home rehabilitation. Rob Auton Syst, 2015; 73:135–143.

Awad

, Bae

, O'Donnell

, et al. A soft robotic exosuit improves walking in patients after stroke. Sci Transl Med, 2017; 9:eaai9084.

Ding

, Kim

, Kuindersma

, et al. Human-in-the-loop optimization of hip assistance with a soft exosuit during walking. Sci Robot, 2018; 3:eaar5438.

Roche

, Horvath

, Wamala

, et al. Soft robotic sleeve supports heart function. Sci Transl Med, 2017; 9:eaaf3925.

Payne

, Wamala

, Bautista-Salinas

, et al. Soft robotic ventricular assist device with septal bracing for therapy of heart failure. Sci Robot, 2017; 2:eaan6736.

10.

Guerra

, Etienne-Mesmin

, Livrelli

, et al. Relevance and challenges in modeling human gastric and small intestinal digestion. Trends Biotechnol, 2012; 30:591–600.

11.

Schulze

. Imaging and modelling of digestion in the stomach and the duodenum. Neurogastroenterol Motil, 2006; 18:172–183.

12.

Kong

, Singh

. Disintegration of solid foods in human stomach. J Food Sci, 2008; 73:R67–R80.

13.

Pal

, Indireshkumar

, Schwizer

, et al. Gastric flow and mixing studied using computer simulation. Proc R Soc Lond B Biol Sci, 2004; 271:2587–2594.

14.

Alminger

, Aura

A-M

, Bohn

, et al. In vitro models for studying secondary plant metabolite digestion and bioaccessibility. Compr Rev Food Sci F, 2014; 13:413–436.

15.

Dupont

, Alric

, Blanquet-Diot

, et al. Can dynamic in vitro digestion systems mimic the physiological reality?. Crit Rev Food Sci Nutr, 2019; 59:1546–1562.

16.

Brouwers

, Anneveld

, Goudappel

G-J

, et al. Food-dependent disintegration of immediate release fosamprenavir tablets: in vitro evaluation using magnetic resonance imaging and a dynamic gastrointestinal system. Eur J Pharm Biopharm, 2011; 77:313–319.

17.

Blanquet-Diot

, Denis

, Chalancon

, et al. Use of artificial digestive systems to investigate the biopharmaceutical factors influencing the survival of probiotic yeast during gastrointestinal transit in humans. Pharm Res, 2012; 29:1444–1453.

18.

Alighaleh

, Cheng

, Angeli

, et al. A novel gastric pacing device to modulate slow waves and assessment by high-resolution mapping. IEEE Trans Biomed Eng, 2019; 66:2823–2830.

19.

Mintchev

, Sanmiguel

, Otto

, et al. Microprocessor controlled movement of liquid gastric content using sequential neural electrical stimulation. Gut, 1998; 43:607–611.

20.

Sitti

. Voyage of the microrobots. Nature, 2009; 458:1121–1122.

21.

, Lum

, Mastrangeli

, et al. Small-scale soft-bodied robot with multimodal locomotion. Nature, 2018; 554:81–85.

22.

Mercuri

, Passalacqua

, Wickham

MSJ

, et al. The effect of composition and gastric conditions on the self-emulsification process of Ibuprofen-loaded self-emulsifying drug delivery systems: a microscopic and dynamic gastric model study. Pharm Res, 2011; 28:1540–1551.

23.

Vardakou

, Mercuri

, Barker

, et al. Achieving antral grinding forces in biorelevant in vitro models: comparing the USP dissolution apparatus II and the dynamic gastric model with human in vivo data. AAPS PharmSciTech, 2011; 12:620–626.

24.

Barker

, Abrahamsson

, Kruusmägi

. Application and validation of an advanced gastrointestinal in vitro model for the evaluation of drug product performance in pharmaceutical development. J Pharm Sci, 2014; 103:3704–3712.

25.

Blanquet

, Zeijdner

, Beyssac

, et al. A dynamic artificial gastrointestinal system for studying the behavior of orally administered drug dosage forms under various physiological conditions. Pharm Res, 2004; 21:585–591.

26.

Kong

, Singh

. A human gastric simulator (HGS) to study food digestion in human stomach. J Food Sci, 2010; 75:E627–E635.

27.

Condino

, Harada

, Pak

, et al. Stomach simulator for analysis and validation of surgical endoluminal robots. Appl Bionics Biomech, 2011; 8:267–277.

28.

Dang

, Cheng

, Stommel

, et al. Technical requirements and conceptualization of a soft pneumatic actuator inspired by human gastric motility. In: 2016 IEEE International Conference on Mechatronics and Machine Vision in Practice (M2VIP), Nanjing, China, 28–30 November, 2016, pp. 1–6. IEEE.

29.

Dang

, Martin

, Cheng

, et al. A soft ring-shaped actuator for radial contracting deformation: design and modelling. Soft Robot, 2019; 6:444–454.

30.

Paternò

, Tortora

, Menciassi

. Hybrid soft–rigid actuators for minimally invasive surgery. Soft Robot, 2018; 5:783–799.

31.

American Dietetic Association. National Dysphagia Diet: Standardization for Optimal Care. Chicago, IL: American Dietetic Association, 2002.

32.

Vassallo

, Camilleri

, Prather

, et al. Measurement of axial forces during emptying from the human stomach. Gastrointest Liver Physiol, 1992; 263:G230–G239.

33.

Marciani

, Gowland

, Fillery-Travis

, et al. Assessment of antral grinding of a model solid meal with echo-planar imaging. Gastrointest Liver Physiol, 2001; 280:G844–G849.

34.

Ferrua

, Singh

. Computational modelling of gastric digestion: current challenges and future directions. Curr Opin Food Sci, 2015; 4:116–123.

35.

Singh

, Singh

. Gastric digestion of foods: mathematical modeling of flow field in a human stomach. In: Aguilera J, Simpson R, Welti-Chanes J, Bermudez-Aguirre D, Barbosa-Canovas G. (Eds). Food Engineering Interfaces. New York, NY: Springer, 2010, pp. 99–117.

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SoGut: A Soft Robotic Gastric Simulator

Abstract

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