Microscale Bioreactors for in situ characterization of GI epithelial cell physiology

The development of in vitro artificial small intestines that realistically mimic in vivo systems will enable vast improvement of our understanding of the human gut and its impact on human health. Synthetic in vitro models can control specific parameters, including (but not limited to) cell types, fluid flow, nutrient profiles and gaseous exchange. They are also “open” systems, enabling access to chemical and physiological information. In this work, we demonstrate the importance of gut surface topography and fluid flow dynamics which are shown to impact epithelial cell growth, proliferation and intestinal cell function. We have constructed a small intestinal bioreactor using 3-D printing and polymeric scaffolds that mimic the 3-D topography of the intestine and its fluid flow. Our results indicate that TEER measurements, which are typically high in static 2-D Transwell apparatuses, is lower in the presence of liquid sheer and 3-D topography compared to a flat scaffold and static conditions. There was also increased cell proliferation and discovered localized regions of elevated apoptosis, specifically at the tips of the villi, where there is highest sheer. Similarly, glucose was actively transported (as opposed to passive) and at higher rates under flow.

[1]  F. Sepúlveda,et al.  A rabbit jejunal isolated enterocyte preparation suitable for transport studies. , 1985, The Journal of physiology.

[2]  Robert C. Wolpert,et al.  A Review of the , 1985 .

[3]  K. Whaley,et al.  Controlled vaginal delivery of antibodies in the mouse. , 1992, Biology of reproduction.

[4]  G. Brierley,et al.  Transmembrane gradients of free Na+ in isolated heart mitochondria estimated using a fluorescent probe. , 1992, The American journal of physiology.

[5]  J. Diamond,et al.  Regulation of brush-border enzyme activities and enterocyte migration rates in mouse small intestine. , 1992, The American journal of physiology.

[6]  E. Chang,et al.  Regional expression and regulation of intestinal sucrase-isomaltase , 1993 .

[7]  J. Furness,et al.  The enteric nervous system and regulation of intestinal motility. , 1999, Annual review of physiology.

[8]  G L Amidon,et al.  Caco-2 versus Caco-2/HT29-MTX co-cultured cell lines: permeabilities via diffusion, inside- and outside-directed carrier-mediated transport. , 2000, Journal of pharmaceutical sciences.

[9]  Kenneth M. Yamada,et al.  Taking Cell-Matrix Adhesions to the Third Dimension , 2001, Science.

[10]  Mina J Bissell,et al.  Modeling tissue-specific signaling and organ function in three dimensions , 2003, Journal of Cell Science.

[11]  M. Basson Paradigms for Mechanical Signal Transduction in the Intestinal Epithelium , 2004, Digestion.

[12]  B. Sumpio,et al.  Regulation of the intestinal epithelial response to cyclic strain by extracellular matrix proteins , 2003, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[13]  Krishnendu Roy,et al.  Biomimetic three-dimensional cultures significantly increase hematopoietic differentiation efficacy of embryonic stem cells. , 2005, Tissue engineering.

[14]  A. Stammati,et al.  The Caco-2 cell line as a model of the intestinal barrier: influence of cell and culture-related factors on Caco-2 cell functional characteristics , 2005, Cell Biology and Toxicology.

[15]  L. Griffith,et al.  Capturing complex 3D tissue physiology in vitro , 2006, Nature Reviews Molecular Cell Biology.

[16]  Duolao Wang,et al.  The nocturnal jejunal migrating motor complex: defining normal ranges by study of 51 healthy adult volunteers and meta‐analysis , 2006, Neurogastroenterology and motility : the official journal of the European Gastrointestinal Motility Society.

[17]  A. Thomson,et al.  Intestinal sugar transport. , 2006, World journal of gastroenterology.

[18]  Fiona Campbell,et al.  Characterization of epithelial cell shedding from human small intestine , 2006, Laboratory Investigation.

[19]  P. Artursson,et al.  Determination of drug permeability and prediction of drug absorption in Caco-2 monolayers , 2007, Nature Protocols.

[20]  R. Lentle,et al.  Physical characteristics of digesta and their influence on flow and mixing in the mammalian intestine: a review , 2008, Journal of Comparative Physiology B.

[21]  A. Leturque,et al.  Sugar absorption in the intestine: the role of GLUT2. , 2008, Annual review of nutrition.

[22]  A. S. Luyt,et al.  Morphology and properties of polypropylene/ethylene vinyl acetate copolymer/wood powder blend composites , 2009 .

[23]  Marc D Basson,et al.  The effects of mechanical forces on intestinal physiology and pathology. , 2009, Cellular signalling.

[24]  Luca Cucullo,et al.  The role of shear stress in Blood-Brain Barrier endothelial physiology , 2011, BMC Neuroscience.

[25]  Glenn D Prestwich,et al.  The generation of 3-D tissue models based on hyaluronan hydrogel-coated microcarriers within a rotating wall vessel bioreactor. , 2010, Biomaterials.

[26]  A. Piekna,et al.  Bioluminescent high‐throughput assay for the bacteria adherence to the tissue culture cells , 2011, Biotechnology and bioengineering.

[27]  W. Verstraete,et al.  Adherence and viability of intestinal bacteria to differentiated Caco-2 cells quantified by flow cytometry. , 2011, Journal of microbiological methods.

[28]  Katja Schenke-Layland,et al.  The physiological performance of a three-dimensional model that mimics the microenvironment of the small intestine. , 2011, Biomaterials.

[29]  Jiajie Yu,et al.  Microscale 3-D hydrogel scaffold for biomimetic gastrointestinal (GI) tract model. , 2011, Lab on a chip.

[30]  Christine Jérôme,et al.  In vivo biocompatibility of three potential intraperitoneal implants. , 2011, Macromolecular bioscience.

[31]  P. Ramesh,et al.  Porous composites of hydroxyapatite-filled poly[ethylene-co-(vinyl acetate)] for tissue engineering , 2011 .

[32]  Jan Tack,et al.  The migrating motor complex: control mechanisms and its role in health and disease , 2012, Nature Reviews Gastroenterology &Hepatology.

[33]  M. Sarr,et al.  Mechanisms of glucose uptake in intestinal cell lines: role of GLUT2. , 2012, Surgery.

[34]  D. Ingber,et al.  Human gut-on-a-chip inhabited by microbial flora that experiences intestinal peristalsis-like motions and flow. , 2012, Lab on a chip.

[35]  Jiajie Yu,et al.  In vitro 3D human small intestinal villous model for drug permeability determination. , 2012, Biotechnology and bioengineering.

[36]  Toku Takahashi,et al.  Mechanism of Interdigestive Migrating Motor Complex , 2012, Journal of neurogastroenterology and motility.

[37]  Daisuke Nakai,et al.  Human small intestinal and colonic tissue mounted in the Ussing chamber as a tool for characterizing the intestinal absorption of drugs. , 2012, European journal of pharmaceutical sciences : official journal of the European Federation for Pharmaceutical Sciences.

[38]  I. Modlin,et al.  The role of mechanical forces and adenosine in the regulation of intestinal enterochromaffin cell serotonin secretion. , 2012, American journal of physiology. Gastrointestinal and liver physiology.

[39]  J. Beaulieu,et al.  Integrin/Fak/Src-mediated regulation of cell survival and anoikis in human intestinal epithelial crypt cells: selective engagement and roles of PI3-K isoform complexes , 2012, Apoptosis.

[40]  Sandro Carrara,et al.  NutriChip: nutrition analysis meets microfluidics. , 2013, Lab on a chip.

[41]  Christer Tannergren,et al.  Comprehensive study on regional human intestinal permeability and prediction of fraction absorbed of drugs using the Ussing chamber technique. , 2013, European journal of pharmaceutical sciences : official journal of the European Federation for Pharmaceutical Sciences.

[42]  D. Stange Intestinal Stem Cells , 2013, Digestive Diseases.

[43]  Suppression of anoikis in human intestinal epithelial cells: differentiation state-selective roles of α2β1, α3β1, α5β1, and α6β4 integrins , 2013, BMC Cell Biology.

[44]  Simon C Watkins,et al.  In vitro and in vivo growth of intestinal stem cells using a novel scaffold in the generation of an artificial intestine , 2013 .

[45]  Claudio Domenici,et al.  A novel dual‐flow bioreactor simulates increased fluorescein permeability in epithelial tissue barriers , 2014, Biotechnology journal.

[46]  J. March,et al.  Synthetic small intestinal scaffolds for improved studies of intestinal differentiation , 2014, Biotechnology and bioengineering.

[47]  H. Daniel,et al.  The Role of SGLT1 and GLUT2 in Intestinal Glucose Transport and Sensing , 2014, PloS one.

[48]  Valeria Chiono,et al.  An Overview of Poly(lactic-co-glycolic) Acid (PLGA)-Based Biomaterials for Bone Tissue Engineering , 2014, International journal of molecular sciences.

[49]  S. Takeuchi,et al.  Fluid shear triggers microvilli formation via mechanosensitive activation of TRPV6 , 2015, Nature Communications.

[50]  N Verdonschot,et al.  A medium throughput device to study the effects of combinations of surface strains and fluid-flow shear stresses on cells. , 2015, Lab on a chip.

[51]  Majid Ebrahimi Warkiani,et al.  Flow-induced stress on adherent cells in microfluidic devices. , 2015, Lab on a chip.

[52]  Jenna L. Dziki,et al.  Intestinal stem cell growth and differentiation on a tubular scaffold with evaluation in small and large animals. , 2016, Regenerative medicine.

[53]  Qasem Ramadan,et al.  Characterization of tight junction disruption and immune response modulation in a miniaturized Caco-2/U937 coculture-based in vitro model of the human intestinal barrier , 2016, Biomedical microdevices.

[54]  Paul Wilmes,et al.  A microfluidics-based in vitro model of the gastrointestinal human–microbe interface , 2016, Nature Communications.