Your search keyword '"Bin, Feng"' showing total 27 results

1. Predicting the micromechanics of embedded nerve fibers using a novel three-layered model of mouse distal colon and rectum

Author

Yunmei Zhao, Bin Feng, and David M. Pierce

Subjects

Biomaterials, Mice, Nerve Fibers, Mechanics of Materials, Colon, Biomedical Engineering, Rectum, Animals, Mechanotransduction, Cellular, Article, Pelvis

Abstract

Mechanotransduction plays a central role in evoking pain from the distal colon and rectum (colorectum) where embedded sensory nerve endings convert micromechanical stresses and strains into neural action potentials. The colorectum displays strong through-thickness and longitudinal heterogeneity with collagen concentrated in the submucosa thus indicating the significant load-bearing role of this layer. The density of sensory nerve endings is also significantly the greatest in the submucosa, suggesting a nociceptive function. Thus biomechanical heterogeneity in the colorectum influences the micromechanical stresses and strains surrounding afferent endings embedded within different layers of the colorectum which is critical for the mechanotransduction of various mechanical stimuli. In this study we aimed to: (1) calibrate and validate a three-layered computational model of the colorectum; (2) predict intra-tissue distributions of stresses and strains during mechanical stimulation of the colorectum ex vivo (i.e. circumferential stretching, punctuate probing, and mucosal shearing); and (3) establish a methodology to calculate local micromechanical stresses and strains surrounding afferent nerve endings embedded in the colorectum. We established three-layered FE models that include mucosa, submucosa, and muscular layers, and incorporated residual stretches, to calculate intra-tissue stresses and strains when the colorectum undergoes the mechanical stimuli used to characterize afferent neural encoding ex vivo. Finally, we established a methodology for detailed calculations of the local micromechanical stresses and strains surrounding afferent endings embedded in the colorectum and demonstrated this with a representative example. Our novel methodologies will bridge the existing neurophysiological and biomechanical evidence from experiments to advance our mechanistic understanding of colorectal mechanotransduction.

Published

2021

2. Toward Elucidating the Physiological Impacts of Residual Stresses in the Colorectum

Author

Yunmei Zhao, Saeed Siri, Bin Feng, and David M. Pierce

Subjects

Colon, Finite element software, business.industry, Rectum, Biomedical Engineering, Biomechanics, Visceral pain, Visceral Pain, Neurophysiology, Research Papers, digestive system diseases, Biomechanical Phenomena, Mice, Mechanobiology, Global population, Residual stress, Physiology (medical), medicine, Animals, Stress, Mechanical, medicine.symptom, business, Neuroscience, Colorectal distension

Abstract

Irritable bowel syndrome afflicts 10–20% of the global population, causing visceral pain with increased sensitivity to colorectal distension and normal bowel movements. Understanding and predicting these biomechanics will further advance our understanding of visceral pain and complement the existing literature on visceral neurophysiology. We recently performed a series of experiments at three longitudinal segments (colonic, intermediate, and rectal) of the distal 30 mm of colorectums of mice. We also established and fitted constitutive models addressing mechanical heterogeneity in both the through-thickness and longitudinal directions of the colorectum. Afferent nerve endings, strategically located within the submucosa, are likely nociceptors that detect concentrations of mechanical stresses to evoke the perception of pain from the viscera. In this study, we aim to: (1) establish and validate a method for incorporating residual stresses into models of colorectums, (2) predict the effects of residual stresses on the intratissue mechanics within the colorectum, and (3) establish intratissue distributions of stretches and stresses within the colorectum in vivo. To these ends we developed two-layered, composite finite element models of the colorectum based on our experimental evidence and validated our approaches against independent experimental data. We included layer- and segment-specific residual stretches/stresses in our simulations via the prestrain algorithm built into the finite element software febio. Our models and modeling approaches allow researchers to predict both organ and intratissue biomechanics of the colorectum and may facilitate better understanding of the underlying mechanical mechanisms of visceral pain.

Published

2021

3. Optical clearing reveals TNBS-induced morphological changes of VGLUT2-positive nerve fibers in mouse colorectum

Author

Sharareh Emadi, Bin Feng, Ling Chi, Tiantian Guo, Dhruv Shah, Shivam P Patel, Pablo R. Brumovsky, David M. Pierce, and Martin Han

Subjects

0301 basic medicine, Glycerol, Pathology, medicine.medical_specialty, Tissue Fixation, Sensory Receptor Cells, Physiology, Colon, Channelrhodopsin, Mice, Transgenic, Fructose, 03 medical and health sciences, 0302 clinical medicine, Bacterial Proteins, Channelrhodopsins, Optical clearing, Physiology (medical), Submucosa, Ganglia, Spinal, medicine, Animals, Irritable bowel syndrome, Microscopy, Confocal, Hepatology, Chemistry, Gastroenterology, Rectum, Visceral pain, medicine.disease, Colitis, Immunohistochemistry, digestive system diseases, Mice, Inbred C57BL, Solutions, Disease Models, Animal, Luminescent Proteins, 030104 developmental biology, medicine.anatomical_structure, Nociception, Trinitrobenzenesulfonic Acid, Vesicular Glutamate Transport Protein 2, medicine.symptom, 030217 neurology & neurosurgery, Sensory nerve, Research Article

Abstract

Colorectal hypersensitivity and sensitization of both mechanosensitive and mechanically insensitive afferents develop after intracolonic instillation of 2,4,6-trinitrobenzenesulfonic acid (TNBS) in the mouse, a model of postinfectious irritable bowel syndrome. In mice in which ∼80% of extrinsic colorectal afferents were labeled genetically using the promotor for vesicular glutamate transporter type 2 (VGLUT2), we systematically quantified the morphology of VGLUT2-positive axons in mouse colorectum 7–28 days following intracolonic TNBS treatment. After removal, the colorectum was distended (20 mmHg), fixed with paraformaldehyde, and optically cleared to image VGLUT2-positive axons throughout the colorectal wall thickness. We conducted vector path tracing of individual axons to allow systematic quantification of nerve fiber density and shape. Abundant VGLUT2-positive nerve fibers were present in most layers of the colorectum, except the serosal and longitudinal muscular layers. A small percentage of VGLUT2-positive myenteric plexus neurons was also detected. Intracolonic TNBS treatment significantly reduced the number of VGLUT2-positive nerve fibers in submucosal, myenteric plexus, and mucosal layers at day 7 post-TNBS, which mostly recovered by day 28. We also found that almost all fibers in the submucosa were meandering and curvy, with ∼10% showing pronounced curviness (quantified by the linearity index). TNBS treatment resulted in a significant reduction of the proportions of pronounced curvy fibers in the rectal region at 28 days post-TNBS. Altogether, the present morphological study reveals profound changes in the distribution of VGLUT2-positive fibers in mouse colorectum undergoing TNBS-induced colitis and draws attention to curvy fibers in the submucosa with potential roles in visceral nociception. NEW & NOTEWORTHY We conducted genetic labeling and optical clearing to visualize extrinsic sensory nerve fibers in whole-mount colorectum, which revealed widespread presence of axons in the submucosal layer. Remarkably, axons in the submucosa were meandering and curvy, in contrast to axons in other layers generally aligned with the basal tissues. Intracolonic TNBS treatment led to pronounced changes of nerve fiber density and curviness, suggesting nerve fiber morphologies as potentially contributing factors to sensory sensitization.

Published

2021

4. The Macro- and Micro-Mechanics of the Colon and Rectum II: Theoretical and Computational Methods

Author

Saeed Siri, Bin Feng, Yunmei Zhao, and David M. Pierce

Subjects

theoretical and computational models, 0206 medical engineering, Rectum, Bioengineering, 02 engineering and technology, Review, Inflammatory bowel disease, lcsh:Technology, biomechanics, 03 medical and health sciences, colorectum, afferent endings, medicine, Mechanotransduction, lcsh:QH301-705.5, Irritable bowel syndrome, 030304 developmental biology, mechanotransduction, 0303 health sciences, business.industry, lcsh:T, Biomechanics, Visceral pain, medicine.disease, 020601 biomedical engineering, digestive system diseases, constitutive modeling, medicine.anatomical_structure, lcsh:Biology (General), Mechanosensitive channels, medicine.symptom, business, Free nerve ending, Neuroscience

Abstract

Abnormal colorectal biomechanics and mechanotransduction associate with an array of gastrointestinal diseases, including inflammatory bowel disease, irritable bowel syndrome, diverticula disease, anorectal disorders, ileus, and chronic constipation. Visceral pain, principally evoked from mechanical distension, has a unique biomechanical component that plays a critical role in mechanotransduction, the process of encoding mechanical stimuli to the colorectum by sensory afferents. To fully understand the underlying mechanisms of visceral mechanical neural encoding demands focused attention on the macro- and micro-mechanics of colon tissue. Motivated by biomechanical experiments on the colon and rectum, increasing efforts focus on developing constitutive frameworks to interpret and predict the anisotropic and nonlinear biomechanical behaviors of the multilayered colorectum. We will review the current literature on computational modeling of the colon and rectum as well as the mechanical neural encoding by stretch sensitive afferent endings, and then highlight our recent advances in these areas. Current models provide insight into organ- and tissue-level biomechanics as well as the stretch-sensitive afferent endings of colorectal tissues yet an important challenge in modeling theory remains. The research community has not connected the biomechanical models to those of mechanosensitive nerve endings to create a cohesive multiscale framework for predicting mechanotransduction from organ-level biomechanics.

Published

2020

5. The Macro- and Micro-Mechanics of the Colon and Rectum I: Experimental Evidence

Author

Saeed Siri, Bin Feng, Franz Maier, David M. Pierce, and Yunmei Zhao

Subjects

Pathology, medicine.medical_specialty, Rectum, Bioengineering, Review, Neural tissues, Distension, lcsh:Technology, 03 medical and health sciences, 0302 clinical medicine, multi-layered, colorectum, Submucosa, Medicine, Large intestine, Mechanotransduction, lcsh:QH301-705.5, 030304 developmental biology, mechanotransduction, 0303 health sciences, business.industry, lcsh:T, Biomechanics, Visceral pain, experiments, digestive system diseases, medicine.anatomical_structure, lcsh:Biology (General), large intestine, 030220 oncology & carcinogenesis, medicine.symptom, business

Abstract

Many lower gastrointestinal diseases are associated with altered mechanical movement and deformation of the large intestine, i.e., the colon and rectum. The leading reason for patients’ visits to gastrointestinal clinics is visceral pain, which is reliably evoked by mechanical distension rather than non-mechanical stimuli such as inflammation or heating. The macroscopic biomechanics of the large intestine were characterized by mechanical tests and the microscopic by imaging the load-bearing constituents, i.e., intestinal collagen and muscle fibers. Regions with high mechanical stresses in the large intestine (submucosa and muscularis propria) coincide with locations of submucosal and myenteric neural plexuses, indicating a functional interaction between intestinal structural biomechanics and enteric neurons. In this review, we systematically summarized experimental evidence on the macro- and micro-scale biomechanics of the colon and rectum in both health and disease. We reviewed the heterogeneous mechanical properties of the colon and rectum and surveyed the imaging methods applied to characterize collagen fibers in the intestinal wall. We also discussed the presence of extrinsic and intrinsic neural tissues within different layers of the colon and rectum. This review provides a foundation for further advancements in intestinal biomechanics by synergistically studying the interplay between tissue biomechanics and enteric neurons.

Published

2020

6. Load-bearing function of the colorectal submucosa and its relevance to visceral nociception elicited by mechanical stretch

Author

Stephany Santos, Bin Feng, David M. Pierce, Franz Maier, and Saeed Siri

Subjects

0301 basic medicine, Male, Nociception, Physiology, Colon, Rectum, Distension, Models, Biological, Load bearing, Weight-Bearing, 03 medical and health sciences, Mice, 0302 clinical medicine, Visceral nociception, Physiology (medical), Submucosa, Medicine, Animals, Mechanotransduction, Hepatology, business.industry, Gastroenterology, Visceral pain, Anatomy, Visceral Pain, digestive system diseases, 030104 developmental biology, medicine.anatomical_structure, 030211 gastroenterology & hepatology, Female, Stress, Mechanical, Distal colon, medicine.symptom, business, Colorectal Neoplasms, Research Article

Abstract

Mechanical distension beyond a particular threshold evokes visceral pain from distal colon and rectum (colorectum), and thus biomechanics plays a central role in visceral nociception. In this study we focused on the layered structure of the colorectum through the wall thickness and determined the biomechanical properties of layer-separated colorectal tissue. We harvested the distal 30 mm of mouse colorectum and dissected this tissue into inner and outer composite layers. The inner composite consists of the mucosa and submucosa, whereas the outer composite includes the muscular layers and serosa. We divided each composite axially into three 10-mm-long segments and conducted biaxial mechanical extension tests and opening-angle measurements for each tissue segment. In addition, we quantified the thickness of the rich collagen network in the submucosa by nonlinear imaging via second-harmonic generation (SHG). Our results reveal that the inner composite is slightly stiffer in the axial direction, whereas the outer composite is stiffer circumferentially. The stiffness of the inner composite in the axial direction is about twice that in the circumferential direction, consistent with the orientations of collagen fibers in the submucosa approximately ±30° to the axial direction. Submucosal thickness measured by SHG showed no difference from proximal to distal colorectum under the load-free condition, which likely contributes to the comparable tension stiffness of the inner composite along the colorectum. This, in turn, strongly indicates the submucosa as the load-bearing structure of the colorectum. This further implies nociceptive roles for the colorectal afferent endings in the submucosa, which likely encode tissue-injurious mechanical distension.NEW & NOTEWORTHY Visceral pain from distal colon and rectum (colorectum) is usually elicited from mechanical distension/stretch, rather than from heating, cutting, or pinching, which usually evoke pain from the skin. We conducted layer-separated biomechanical tests on mouse colorectum and identified an unexpected role of submucosa as the load-bearing structure of the colorectum. Outcomes of this study will focus attention on sensory nerve endings in the submucosa that likely encode tissue-injurious distension/stretch to cause visceral pain.

Published

2019

7. Differential biomechanical properties of mouse distal colon and rectum innervated by the splanchnic and pelvic afferents

Author

Longtu Chen, Saeed Siri, Stephany Santos, Franz Maier, David M. Pierce, and Bin Feng

Subjects

0301 basic medicine, Physiology, Colon, Rectum, Distension, Pelvis, Mouse Distal Colon, Irritable Bowel Syndrome, 03 medical and health sciences, Mice, 0302 clinical medicine, Physiology (medical), Medicine, Animals, Mechanotransduction, Hepatology, business.industry, Gastroenterology, Lumbosacral Region, Visceral pain, Splanchnic Nerves, Anatomy, Visceral Pain, Biaxial test, digestive system diseases, Biomechanical Phenomena, Disease Models, Animal, 030104 developmental biology, medicine.anatomical_structure, Second Harmonic Generation Microscopy, Distal colon, medicine.symptom, business, Splanchnic, Mechanoreceptors, 030217 neurology & neurosurgery, Research Article

Abstract

Visceral pain is one of the principal complaints of patients with irritable bowel syndrome, and this pain is reliably evoked by mechanical distension and stretch of distal colon and rectum (colorectum). This study focuses on the biomechanics of the colorectum that could play critical roles in mechanical neural encoding. We harvested the distal 30 mm of the colorectum from mice, divided evenly into three 10-mm-long segments (colonic, intermediate and rectal), and conducted biaxial mechanical stretch tests and opening-angle measurements for each tissue segment. In addition, we determined the collagen fiber orientations and contents across the thickness of the colorectal wall by nonlinear imaging via second harmonic generation (SHG). Our results reveal a progressive increase in tissue compliance and prestress from colonic to rectal segments, which supports prior electrophysiological findings of distinct mechanical neural encodings by afferents in the lumbar splanchnic nerves (LSN) and pelvic nerves (PN) that dominate colonic and rectal innervations, respectively. The colorectum is significantly more viscoelastic in the circumferential direction than in the axial direction. In addition, our SHG results reveal a rich collagen network in the submucosa and orients approximately ±30° to the axial direction, consistent with the biaxial test results presenting almost twice the stiffness in axial direction versus the circumferential direction. Results from current biomechanical study strongly indicate the prominent roles of local tissue biomechanics in determining the differential mechanical neural encoding functions in different regions of the colorectum. NEW & NOTEWORTHY Mechanical distension and stretch—not heat, cutting, or pinching—reliably evoke pain from distal colon and rectum. We report different local mechanics along the longitudinal length of the colorectum, which is consistent with the existing literature on distinct mechanotransduction of afferents innervating proximal and distal regions of the colorectum. This study draws attention to local mechanics as a potential determinant factor for mechanical neural encoding of the colorectum, which is crucial in visceral nociception.

Published

2019

8. The heterogeneous morphology of networked collagen in distal colon and rectum of mice quantified via nonlinear microscopy

Author

Longtu Chen, David M. Pierce, Franz Maier, Stephany Santos, Bin Feng, and Saeed Siri

Subjects

Male, Morphology (linguistics), Colon, Biomedical Engineering, Rectum, 02 engineering and technology, Distension, Mechanotransduction, Cellular, Article, law.invention, Biomaterials, Mice, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Confocal microscopy, law, Submucosa, medicine, Animals, Mechanotransduction, Paraformaldehyde, Microscopy, Visceral pain, 030206 dentistry, Anatomy, 021001 nanoscience & nanotechnology, digestive system diseases, Mice, Inbred C57BL, medicine.anatomical_structure, chemistry, Mechanics of Materials, Female, Collagen, medicine.symptom, 0210 nano-technology

Abstract

Visceral pain from the distal colon and rectum (colorectum) is a major complaint of patients with irritable bowel syndrome. Mechanotransduction of colorectal distension/stretch appears to play a critical role in visceral nociception, and further understanding requires improved knowledge of the micromechanical environments at different sub-layers of the colorectum. In this study, we conducted nonlinear imaging via second harmonic generation to quantify the thickness of each distinct through-thickness layer of the colorectum, as well as the principal orientations, corresponding dispersions in orientations, and the distributions of diameters of collagen fibers within each of these layers. From C57BL/6 mice of both sexes (8–16 weeks of age, 25–35g), we dissected the distal 30 mm of the large bowel including the colorectum, divided these into three even segments, and harvested specimens (~8×8 mm(2)) from each segment. We stretched the specimens either by colorectal distension to 20 mmHg (reference) or 80 mmHg (deformed) or by biaxial stretch to 10 mN (reference) or 80 mN (deformed), and fixed them with 4% paraformaldehyde. We then conducted SHG imaging through the wall thickness and analyzed post-hoc using custom-built software to quantify the orientations of collagen fibers in all distinct layers. We also quantified the thickness of each layer of the colorectum, and the corresponding distributions of collagen density and diameters of fibers. We found collagen concentrated in the submucosal layer. The average diameter of collagen fibers was greatest in the submucosal layer, followed by the serosal and muscular layers. Collagen fibers aligned with muscle fibers in the two muscular layers, whereas their orientation varied greatly with location in the serosal layer. In colonic segments, thick collagen fibers in the submucosa presented two major orientations aligned approximately ±30 degrees to the axial direction, and form a patterned network. Our results indicate the submucosa is likely the principal passive load-bearing structure of the colorectum. In addition, afferent endings in those collagen-rich regions present likely candidates of colorectal nociceptors to encode noxious distension/stretch.

Published

2021

9. Computational Modeling of Mouse Colorectum Capturing Longitudinal and Through-thickness Biomechanical Heterogeneity

Author

Bin Feng, David M. Pierce, Yunmei Zhao, and Saeed Siri

Subjects

Materials science, Colon, Constitutive equation, Biomedical Engineering, 02 engineering and technology, Mechanotransduction, Cellular, Article, Biomaterials, Mice, 03 medical and health sciences, 0302 clinical medicine, Tissue biomechanics, Animals, Mechanotransduction, Rectum, Biomechanics, 030206 dentistry, Anatomy, 021001 nanoscience & nanotechnology, Sensory Nerve Endings, digestive system diseases, Finite element method, Biomechanical Phenomena, Mechanics of Materials, Invasive surgery, Stress, Mechanical, Distal colon, 0210 nano-technology

Abstract

Mechanotransduction, the encoding of local mechanical stresses and strains at sensory endings into neural action potentials at the viscera, plays a critical role in evoking visceral pain, e.g., in the distal colon and rectum (colorectum). The wall of the colorectum is structurally heterogeneous, including two major composites: the inner consists of muscular and submucosal layers, and the outer consists of circular muscular, intermuscular, longitudinal muscular, and serosal layers. In fact the colorectum presents biomechanical heterogenity across both the longitudinal and through-thickness directions thus highlighting the differential roles of sensory nerve endings within different regions of the colorectum in visceral mechanotransduction. We determined constitutive models and model parameters for individual layers of the colorectum from three longitudinal locations (colonic, intermediate, and distal) using nonlinear optimization to fit our experimental results from biaxial extension tests on layer-separated colorectal tissues (mouse model, 7 × 7 mm(2), Siri et al., Am. J. Physiol. Gastrointest. Liver Physiol. 316, G473-G481 and 317, G349-G358), and quantified the thicknesses of the layers. In this study we also quantified the residual stretches stemming from separating colorectal specimens into inner and outer composites and we completed new pressure-diameter mechanical testing to provide an additional validation case. We implemented the constitutive equations and created two-layered, 3-D finite element models using FEBio (University of Utah), and incorporated the residual stretches. We validated the modeling framework by comparing FE-predicted results for both biaxial extension testing of bulk specimens of colorectum and pressure-diameter testing of bulk segments against corresponding experimental results independent of those used in our model fitting. We present the first theoretical framework to simulate the biomechanics of distal colorectum, including both longitudinal and through-thickness heterogeneity, based on constitutive modeling of biaxial extension tests of colon tissues from mice. Our constitutive models and modeling framework facilitate analyses of both fundamental questions (e.g., the impact of organ/tissue biomechanics on mechanotransduction of the sensory nerve endings, structure-function relationships, and growth and remodeling in health and disease) and specific applications (e.g., device design, minimally invasive surgery, and biomedical research).

Published

2021

10. Optogenetic activation of mechanically insensitive afferents in mouse colorectum reveals chemosensitivity

Author

Bin Feng, Sonali Joyce, and Gerald F. Gebhart

Subjects

Male, 0301 basic medicine, Rhodopsin, Light Signal Transduction, endocrine system diseases, Colon, Physiology, Single fiber, Neurogastroenterology and Motility, Sensory system, Optogenetics, Mechanotransduction, Cellular, Bile Acids and Salts, Mice, 03 medical and health sciences, Osmotic Pressure, Physiology (medical), medicine, Animals, Neurons, Afferent, Irritable bowel syndrome, Hepatology, biology, business.industry, Rectum, Gastroenterology, Anatomy, medicine.disease, digestive system diseases, Mice, Inbred C57BL, 030104 developmental biology, biology.protein, Female, business, Neuroscience

Abstract

The sensory innervation of the distal colorectum includes mechanically insensitive afferents (MIAs; ∼25%), which acquire mechanosensitivity in persistent visceral hypersensitivity and thus generate de novo input to the central nervous system. We utilized an optogenetic approach to bypass the process of transduction (generator potential) and focus on transformation (spike initiation) at colorectal MIA sensory terminals, which is otherwise not possible in typical functional studies. From channelrhodopsin2-expressing mice (driven by Advillin-Cre), the distal colorectum with attached pelvic nerve was harvested for ex vivo single-fiber recordings. Afferent receptive fields (RFs) were identified by electrical stimulation and tested for response to mechanical stimuli (probing, stroking, and stretch), and afferents were classified as either MIAs or mechanosensitive afferents (MSAs). All MIA and MSA RFs were subsequently stimulated optically and MIAs were also tested for activation/sensitization with inflammatory soup (IS), acidic hypertonic solution (AHS), and/or bile salts (BS). Responses to pulsed optical stimuli (1–10 Hz) were comparable between MSAs and MIAs whereas 43% of MIAs compared with 86% of MSAs responded tonically to stepped optical stimuli. Tonic-spiking MIAs responded preferentially to AHS (an osmotic stimulus) whereas non-tonic-spiking MIAs responded to IS (an inflammatory stimulus). A significant proportion of MIAs were also sensitized by BS. These results reveal transformation as a critical factor underlying the differences between MIAs (osmosensors vs. inflammatory sensors), revealing a previously unappreciated heterogeneity of MIA endings. The current study draws attention to the sensory encoding of MIA nerve endings that likely contribute to afferent sensitization and thus have important roles in visceral pain.

Published

2016

11. SPARC: Determine the topology and function of DRG neurons innervating mouse colon and rectum

Author

Zichao Bian, Tiantian Guo, Longtu Chen, Guoan Zheng, and Bin Feng

Subjects

medicine.anatomical_structure, Mouse Colon, Genetics, medicine, Rectum, Topology (electrical circuits), Biology, Molecular Biology, Biochemistry, Function (biology), Biotechnology, Cell biology

Published

2020

12. The Macro- and Micro-Mechanics of the Colon and Rectum II: Theoretical and Computational Methods.

Author

Yunmei Zhao, Siri, Saeed, Bin Feng, and Pierce, David M.

Subjects

INFLAMMATORY bowel diseases, RECTUM, DIVERTICULUM, IRRITABLE colon, MICROMECHANICS, COLON (Anatomy), NERVE endings

Abstract

Abnormal colorectal biomechanics and mechanotransduction associate with an array of gastrointestinal diseases, including inflammatory bowel disease, irritable bowel syndrome, diverticula disease, anorectal disorders, ileus, and chronic constipation. Visceral pain, principally evoked from mechanical distension, has a unique biomechanical component that plays a critical role in mechanotransduction, the process of encoding mechanical stimuli to the colorectum by sensory afferents. To fully understand the underlying mechanisms of visceral mechanical neural encoding demands focused attention on the macro- and micro-mechanics of colon tissue. Motivated by biomechanical experiments on the colon and rectum, increasing efforts focus on developing constitutive frameworks to interpret and predict the anisotropic and nonlinear biomechanical behaviors of the multilayered colorectum. We will review the current literature on computational modeling of the colon and rectum as well as the mechanical neural encoding by stretch sensitive afferent endings, and then highlight our recent advances in these areas. Current models provide insight into organ- and tissue-level biomechanics as well as the stretch-sensitive afferent endings of colorectal tissues yet an important challenge in modeling theory remains. The research community has not connected the biomechanical models to those of mechanosensitive nerve endings to create a cohesive multiscale framework for predicting mechanotransduction from organ-level biomechanics. [ABSTRACT FROM AUTHOR]

Published

2020

13. The Macro- and Micro-Mechanics of the Colon and Rectum I: Experimental Evidence.

Author

Siri, Saeed, Yunmei Zhao, Maier, Franz, Pierce, David M., and Bin Feng

Subjects

SUBMUCOUS plexus, LARGE intestine, COLON (Anatomy), RECTUM, MICROMECHANICS, TISSUE mechanics

Abstract

Many lower gastrointestinal diseases are associated with altered mechanical movement and deformation of the large intestine, i.e., the colon and rectum. The leading reason for patients’ visits to gastrointestinal clinics is visceral pain, which is reliably evoked by mechanical distension rather than non-mechanical stimuli such as inflammation or heating. The macroscopic biomechanics of the large intestine were characterized by mechanical tests and the microscopic by imaging the load-bearing constituents, i.e., intestinal collagen and muscle fibers. Regions with high mechanical stresses in the large intestine (submucosa and muscularis propria) coincide with locations of submucosal and myenteric neural plexuses, indicating a functional interaction between intestinal structural biomechanics and enteric neurons. In this review, we systematically summarized experimental evidence on the macro- and micro-scale biomechanics of the colon and rectum in both health and disease. We reviewed the heterogeneous mechanical properties of the colon and rectum and surveyed the imaging methods applied to characterize collagen fibers in the intestinal wall. We also discussed the presence of extrinsic and intrinsic neural tissues within different layers of the colon and rectum. This review provides a foundation for further advancements in intestinal biomechanics by synergistically studying the interplay between tissue biomechanics and enteric neurons. [ABSTRACT FROM AUTHOR]

Published

2020

14. Combined genetic and pharmacological inhibition of TRPV1 and P2X3 attenuates colorectal hypersensitivity and afferent sensitization

Author

Gerald F. Gebhart, Michael E. Kiyatkin, Bin Feng, and Erica S. Schwartz

Subjects

Male, Colon, Physiology, TRPV1, TRPV Cation Channels, Pain, Pharmacology, Neuroregulation and Motility, Mice, Transient receptor potential channel, Physiology (medical), Afferent, Hypersensitivity, medicine, Animals, Sensitization, Mice, Knockout, Behavior, Animal, Hepatology, business.industry, Purinergic receptor, Rectum, Gastroenterology, Visceral pain, Mice, Inbred C57BL, medicine.anatomical_structure, Anesthesia, Afferent neuron, medicine.symptom, business, Receptors, Purinergic P2X3

Abstract

The ligand-gated channels transient receptor potential vanilloid 1 (TRPV1) and P2X3 have been reported to facilitate colorectal afferent neuron sensitization, thus contributing to organ hypersensitivity and pain. In the present study, we hypothesized that TRPV1 and P2X3 cooperate to modulate colorectal nociception and afferent sensitivity. To test this hypothesis, we employed TRPV1-P2X3 double knockout (TPDKO) mice and channel-selective pharmacological antagonists and evaluated combined channel contributions to behavioral responses to colorectal distension (CRD) and afferent fiber responses to colorectal stretch. Baseline responses to CRD were unexpectedly greater in TPDKO compared with control mice, but zymosan-produced CRD hypersensitivity was absent in TPDKO mice. Relative to control mice, proportions of mechanosensitive and -insensitive pelvic nerve afferent classes were not different in TPDKO mice. Responses of mucosal and serosal class afferents to mechanical probing were unaffected, whereas responses of muscular (but not muscular/mucosal) afferents to stretch were significantly attenuated in TPDKO mice; sensitization of both muscular and muscular/mucosal afferents by inflammatory soup was also significantly attenuated. In pharmacological studies, the TRPV1 antagonist A889425 and P2X3 antagonist TNP-ATP, alone and in combination, applied onto stretch-sensitive afferent endings attenuated responses to stretch; combined antagonism produced greater attenuation. In the aggregate, these observations suggest that 1) genetic manipulation of TRPV1 and P2X3 leads to reduction in colorectal mechanosensation peripherally and compensatory changes and/or disinhibition of other channels centrally, 2) combined pharmacological antagonism produces more robust attenuation of mechanosensation peripherally than does antagonism of either channel alone, and 3) the relative importance of these channels appears to be enhanced in colorectal hypersensitivity.

Published

2013

15. Activation of Guanylate Cyclase-C Attenuates Stretch Responses and Sensitization of Mouse Colorectal Afferents

Author

Jun-Ho La, Gerald F. Gebhart, Inmaculada Silos-Santiago, Michael E. Kiyatkin, Robert Solinga, Pei Ge, and Bin Feng

Subjects

Male, medicine.medical_specialty, Colon, Article, Mice, chemistry.chemical_compound, Cell Line, Tumor, Internal medicine, medicine, Animals, Humans, Cyclic guanosine monophosphate, Linaclotide, Irritable bowel syndrome, Sensitization, Afferent Pathways, General Neuroscience, Rectum, medicine.disease, In vitro, Enzyme Activation, Mice, Inbred C57BL, Endocrinology, medicine.anatomical_structure, chemistry, Guanylate Cyclase, Mechanosensitive channels, Mechanoreceptors, Endogenous agonist, Uroguanylin

Abstract

Irritable bowel syndrome (IBS) is characterized by altered bowel habits, persistent pain and discomfort, and typically colorectal hypersensitivity. Linaclotide, a peripherally-restricted 14-amino acid peptide approved for the treatment of IBS with constipation, relieves constipation and reduces IBS-associated pain in these patients presumably by activation of guanylate cyclase-C (GC-C), which stimulates production and release of cyclic guanosine monophosphate (cGMP) from intestinal epithelial cells. We investigated whether activation of GC-C by the endogenous agonist uroguanylin or the primary downstream effector of that activation, cGMP, directly modulates responses and sensitization of mechanosensitive colorectal primary afferents. The distal 2 cm of mouse colorectum with attached pelvic nerve was harvested, pinned flat mucosal side up for in vitro single-fiber recordings and the encoding properties of mechanosensitive afferents (serosal, mucosal, muscular and muscular-mucosal) to probing and circumferential stretch studied. Both cGMP (10–300μM) and uroguanylin (1–1000nM) applied directly to colorectal receptive endings significantly reduced responses of muscular and muscular-mucosal afferents to stretch; serosal and mucosal afferents were not affected. Sensitized responses (i.e., increased responses to stretch) of muscular and muscular-mucosal afferents were reversed by cGMP, returning responses to stretch to control. Blocking the transport of cGMP from colorectal epithelia by probenecid, a mechanism validated by studies in cultured intestinal T84 cells, abolished the inhibitory effect of uroguanylin on muscular-mucosal afferents. These results suggest that GC-C agonists like linaclotide alleviate colorectal pain and hypersensitivity by dampening stretch-sensitive afferent mechanosensitivity and normalizing afferent sensitization.

Published

2013

16. Altered colorectal afferent function associated with TNBS-induced visceral hypersensitivity in mice

Author

Timothy P McMurray, Erica S. Schwartz, Jun-Ho La, Bin Feng, Gerald F. Gebhart, and Takahiro Tanaka

Subjects

Abdominal pain, Time Factors, Colon, Physiology, Visceral Afferents, animal diseases, Rectum, Inflammation, Mechanotransduction, Cellular, digestive system, Neuroregulation and Motility, Immunoenzyme Techniques, Mice, Administration, Rectal, Physical Stimulation, Physiology (medical), Afferent, Hypersensitivity, medicine, Animals, Colitis, Saline Solution, Hypertonic, Hepatology, business.industry, Gastroenterology, Visceral pain, medicine.disease, Immunohistochemistry, digestive system diseases, Mice, Inbred C57BL, Disease Models, Animal, medicine.anatomical_structure, Trinitrobenzenesulfonic Acid, Immunology, medicine.symptom, business, Mechanoreceptors, Function (biology)

Abstract

Inflammation of the distal bowel is often associated with abdominal pain and hypersensitivity, but whether and which colorectal afferents contribute to the hypersensitivity is unknown. Using a mouse model of 2,4,6-trinitrobenzene sulfonic acid (TNBS)-induced colitis, we investigated colorectal hypersensitivity following intracolonic TNBS and associated changes in colorectum and afferent functions. C57BL/6 mice were treated intracolonically with TNBS or saline. Visceromotor responses to colorectal distension (15–60 mmHg) were recorded over 8 wk in TNBS- and saline-treated (control) mice. In other mice treated with TNBS or saline, colorectal inflammation was assessed by myeloperoxidase assay and immunohistological staining. In vitro single-fiber recordings were conducted on both TNBS and saline-treated mice to assess colorectal afferent function. Mice exhibited significant colorectal hypersensitivity through day 14 after TNBS treatment that resolved by day 28 with no resensitization through day 56. TNBS induced a neutrophil- and macrophage-based colorectal inflammation as well as loss of nerve fibers, all of which resolved by days 14–28. Single-fiber recordings revealed a net increase in afferent drive from stretch-sensitive colorectal afferents at day 14 post-TNBS and reduced proportions of mechanically insensitive afferents (MIAs) at days 14–28. Intracolonic TNBS-induced colorectal inflammation was associated with the development and recovery of hypersensitivity in mice, which correlated with a transient increase and recovery of sensitization of stretch-sensitive colorectal afferents and MIAs. These results indicate that the development and maintenance of colorectal hypersensitivity following inflammation are mediated by peripheral drive from stretch-sensitive colorectal afferents and a potential contribution from MIAs.

Published

2012

17. Luminal hypertonicity and acidity modulate colorectal afferents and induce persistent visceral hypersensitivity

Author

Gerald F. Gebhart, Bin Feng, Erica S. Schwartz, Pablo Brumovsky, and Jun-Ho La

Subjects

medicine.medical_specialty, Abdominal pain, Malabsorption, Colon, Physiology, Visceral Afferents, Rectum, Mechanotransduction, Cellular, Gastroenterology, Neuroregulation and Motility, Intracolonic, Mice, Lactose Intolerance, Administration, Rectal, Physical Stimulation, Physiology (medical), Internal medicine, Digestive disorder, Hypersensitivity, medicine, Animals, Saline Solution, Hypertonic, Lactose intolerance, Behavior, Animal, Hepatology, Osmotic concentration, business.industry, Carbohydrate, medicine.disease, Dilatation, Surgery, Mice, Inbred C57BL, medicine.anatomical_structure, medicine.symptom, business, Mechanoreceptors

Abstract

Carbohydrate malabsorption such as in lactose intolerance or enteric infection causes symptoms that include abdominal pain. Because this digestive disorder increases intracolonic osmolarity and acidity by accumulation of undigested carbohydrates and fermented products, we tested whether these two factors (hypertonicity and acidity) would modulate colorectal afferents in association with colorectal nociception and hypersensitivity. In mouse colorectum-pelvic nerve preparations in vitro, afferent activities were monitored after application of acidic hypertonic saline (AHS; pH 6.0, 800 mosM). In other experiments, AHS was instilled intracolonically to mice and behavioral responses to colorectal distension (CRD) measured. Application of AHS in vitro excited 80% of serosal and 42% of mechanically-insensitive colorectal afferents (MIAs), sensitizing a proportion of MIAs to become mechanically sensitive and reversibly inhibiting stretch-sensitive afferents. Acute intracolonic AHS significantly increased expression of the neuronal activation marker pERK in colon sensory neurons and augmented noxious CRD-induced behavioral responses. After three consecutive daily intracolonic AHS treatments, mice were hypersensitive to CRD 4–15 days after the first treatment. In complementary single fiber recordings in vitro, the proportion of serosal class afferents increased at day 4; the proportion of MIAs decreased, and muscular class stretch-sensitive afferents were sensitized at days 11–15 in mice receiving AHS. These results indicate that luminal hypertonicity and acidity, two outcomes of carbohydrate malabsorption, can induce colorectal hypersensitivity to distension by altering the excitability and relative proportions of colorectal afferents, suggesting the potential involvement of these factors in the development of abdominal pain.

Published

2012

18. Irritable Bowel Syndrome: Methods, Mechanisms, and Pathophysiology. Neural and neuro-immune mechanisms of visceral hypersensitivity in irritable bowel syndrome

Author

Bin Feng, Jun-Ho La, Gerald F. Gebhart, and Erica S. Schwartz

Subjects

Male, Colon, Physiology, Pain, Reviews, Enteroendocrine cell, Irritable Bowel Syndrome, Mice, Immune system, Physiology (medical), Fibromyalgia, medicine, Animals, Humans, Lymphocytes, Mast Cells, Irritable bowel syndrome, Neurogenic inflammation, Hepatology, business.industry, Macrophages, Rectum, Gastroenterology, Visceral pain, medicine.disease, Pathophysiology, Rats, Chronic Disease, Neuropathic pain, Immunology, Cytokines, Female, Neurogenic Inflammation, medicine.symptom, business

Abstract

Irritable bowel syndrome (IBS) is characterized as functional because a pathobiological cause is not readily apparent. Considerable evidence, however, documents that sensitizing proinflammatory and lipotoxic lipids, mast cells and their products, tryptases, enteroendocrine cells, and mononuclear phagocytes and their receptors are increased in tissues of IBS patients with colorectal hypersensitivity. It is also clear from recordings in animals of the colorectal afferent innervation that afferents exhibit long-term changes in models of persistent colorectal hypersensitivity. Such changes in afferent excitability and responses to mechanical stimuli are consistent with relief of discomfort and pain in IBS patients, including relief of referred abdominal hypersensitivity, upon intra-rectal instillation of local anesthetic. In the aggregate, these experimental outcomes establish the importance of afferent drive in IBS, consistent with a larger literature with respect to other chronic conditions in which pain is a principal complaint (e.g., neuropathic pain, painful bladder syndrome, fibromyalgia). Accordingly, colorectal afferents and the environment in which these receptive endings reside constitute the focus of this review. That environment includes understudied and incompletely understood contributions from immune-competent cells resident in and recruited into the colorectum. We close this review by highlighting deficiencies in existing knowledge and identifying several areas for further investigation, resolution of which we anticipate would significantly advance our understanding of neural and neuro-immune contributions to IBS pain and hypersensitivity.

Published

2012

19. Differential roles of stretch-sensitive pelvic nerve afferents innervating mouse distal colon and rectum

Author

Pablo Brumovsky, Bin Feng, and Gerald F. Gebhart

Subjects

Male, Pathology, medicine.medical_specialty, Colon, Physiology, Ratón, Neural Conduction, Action Potentials, Hormones and Signaling, Rectum, Stimulus (physiology), Pelvis, Mouse Distal Colon, Mice, Intestinal mucosa, Physical Stimulation, Physiology (medical), Sensory threshold, medicine, Animals, Neurons, Afferent, Intestinal Mucosa, Neuronal Plasticity, Hepatology, business.industry, Gastroenterology, Muscle, Smooth, Anatomy, Mice, Inbred C57BL, medicine.anatomical_structure, Sensory Thresholds, business, Mechanoreceptors, Colorectal distension, Pelvic nerve

Abstract

Information about colorectal distension (i.e., colorectal dilation by increased intraluminal pressure) is primarily encoded by stretch-sensitive colorectal afferents in the pelvic nerve (PN). Despite anatomic differences between rectum and distal colon, little is known about the functional roles of colonic vs. rectal afferents in the PN pathway or the quantitative nature of mechanosensory encoding. We utilized an in vitro mouse colorectum-PN preparation to investigate pressure-encoding characteristics of colorectal afferents. The colorectum with PN attached was dissected, opened longitudinally, and pinned flat in a Sylgard-lined chamber. Action potentials of afferent fibers evoked by circumferential stretch (servo-controlled force actuator) were recorded from the PN. Stretch-sensitive fibers were categorized into the following four groups: colonic muscular, colonic muscular/mucosal, rectal muscular, and rectal muscular/mucosal. Seventy-nine stretch-sensitive PN afferents evenly distributed into the above four groups were studied. Rectal muscular afferents had significantly greater stretch-responses than the other three groups. Virtually all rectal afferents (98%) had low thresholds for response and encoded stimulus intensity into the noxious range without obvious saturation. Most colonic afferents (72%) also had low thresholds (18 mmHg) for response. These high-threshold colonic afferents were sensitized to stretch by inflammatory soup; response threshold was significantly reduced (from 23 to 12 mmHg), and response magnitude significantly increased. These results suggest that the encoding of mechanosensory information differs between colonic and rectal stretch-sensitive PN afferents. Rectal afferents have a wide response range to stretch, whereas high-threshold colonic afferents likely contribute to visceral nociception.

Published

2010

20. Cystitis increases colorectal afferent sensitivity in the mouse

Author

Bin Feng, Carly McCarthy, Pablo Brumovsky, Linjing Xu, and Gerald F. Gebhart

Subjects

Male, Pathology, medicine.medical_specialty, Time Factors, Cyclophosphamide, Colon, Physiology, Ratón, Urinary Bladder, Action Potentials, Inflammation, urologic and male genital diseases, Mechanotransduction, Cellular, Neuroregulation and Motility, Mice, Physiology (medical), Edema, Cystitis, Hypersensitivity, medicine, Animals, Sensitization, Afferent Pathways, Urinary bladder, Hepatology, business.industry, Rectum, Gastroenterology, Hydrogen-Ion Concentration, Peripheral, Mice, Inbred C57BL, Disease Models, Animal, medicine.anatomical_structure, Mechanosensitive channels, Inflammation Mediators, medicine.symptom, business, medicine.drug

Abstract

Studies in humans and rodents suggest that colon inflammation promotes urinary bladder hypersensitivity and, conversely, that cystitis contributes to colon hypersensitivity, events referred to as cross-organ sensitization. To investigate a potential peripheral mechanism, we examined whether cystitis alters the sensitivity of pelvic nerve colorectal afferents. Male C57BL/6 mice were treated with cyclophosphamide (CYP) or saline, and the mechanosensitive properties of single afferent fibers innervating the colorectum were studied with an in vitro preparation. In addition, mechanosensitive receptive endings were exposed to an inflammatory soup (IS) to study sensitization. Urinary bladder mechanosensitive afferents were also tested. We found that baseline responses of stretch-sensitive colorectal afferents did not differ between treatment groups. Whereas IS excited a proportion of colorectal afferents CYP treatment did not alter the magnitude of this response. However, the number of stretch-sensitive fibers excited by IS was increased relative to saline-treated mice. Responses to IS were not altered by CYP treatment, but the proportion of IS-responsive fibers was increased relative to saline-treated mice. In bladder, IS application increased responses of muscular afferents to stretch, although no differences were detected between saline- and CYP-treated mice. In contrast, their chemosensitivity to IS was decreased in the CYP-treated group. Histological examination revealed no changes in colorectum and modest edema and infiltration in the urinary bladder of CYP-treated mice. In conclusion, CYP treatment increased mechanical sensitivity of colorectal muscular afferents and increased the proportion of chemosensitive colorectal afferents. These data support a peripheral contribution to cross-organ sensitization of pelvic organs.

Published

2009

21. Load-bearing function of the colorectal submucosa and its relevance to visceral nociception elicited by mechanical stretch.

Author

Siri, Saeed, Maier, Franz, Santos, Stephany, Pierce, David M., and Bin Feng

Subjects

VISCERAL pain, HARVESTING, RECTUM, COLON (Anatomy), BIOMECHANICS

Abstract

Mechanical distension beyond a particular threshold evokes visceral pain from distal colon and rectum (colorectum), and thus biomechanics plays a central role in visceral nociception. In this study we focused on the layered structure of the colorectum through the wall thickness and determined the biomechanical properties of layer-separated colorectal tissue. We harvested the distal 30 mm of mouse colorectum and dissected this tissue into inner and outer composite layers. The inner composite consists of the mucosa and submucosa, whereas the outer composite includes the muscular layers and serosa. We divided each composite axially into three 10-mm-long segments and conducted biaxial mechanical extension tests and opening-angle measurements for each tissue segment. In addition, we quantified the thickness of the rich collagen network in the submucosa by nonlinear imaging via second-harmonic generation (SHG). Our results reveal that the inner composite is slightly stiffer in the axial direction, whereas the outer composite is stiffer circumferentially. The stiffness of the inner composite in the axial direction is about twice that in the circumferential direction, consistent with the orientations of collagen fibers in the submucosa approximately ±30° to the axial direction. Submucosal thickness measured by SHG showed no difference from proximal to distal colorectum under the load-free condition, which likely contributes to the comparable tension stiffness of the inner composite along the colorectum. This, in turn, strongly indicates the submucosa as the load-bearing structure of the colorectum. This further implies nociceptive roles for the colorectal afferent endings in the submucosa, which likely encode tissue-injurious mechanical distension. [ABSTRACT FROM AUTHOR]

Published

2019

22. Differential biomechanical properties of mouse distal colon and rectum innervated by the splanchnic and pelvic afferents.

Author

Siri, Saeed, Maier, Franz, Chen, Longtu, Santos, Stephany, Pierce, David M., and Bin Feng

Subjects

SECOND harmonic generation, RECTUM, IRRITABLE colon, SPLANCHNIC nerves, VISCERAL pain

Abstract

Visceral pain is one of the principal complaints of patients with irritable bowel syndrome, and this pain is reliably evoked by mechanical distension and stretch of distal colon and rectum (colorectum). This study focuses on the biomechanics of the colorectum that could play critical roles in mechanical neural encoding. We harvested the distal 30 mm of the colorectum from mice, divided evenly into three 10-mm-long segments (colonic, intermediate and rectal), and conducted biaxial mechanical stretch tests and opening-angle measurements for each tissue segment. In addition, we determined the collagen fiber orientations and contents across the thickness of the colorectal wall by nonlinear imaging via second harmonic generation (SHG). Our results reveal a progressive increase in tissue compliance and prestress from colonic to rectal segments, which supports prior electrophysiological findings of distinct mechanical neural encodings by afferents in the lumbar splanchnic nerves (LSN) and pelvic nerves (PN) that dominate colonic and rectal innervations, respectively. The colorectum is significantly more viscoelastic in the circumferential direction than in the axial direction. In addition, our SHG results reveal a rich collagen network in the submucosa and orients approximately 30° to the axial direction, consistent with the biaxial test results presenting almost twice the stiffness in axial direction versus the circumferential direction. Results from current biomechanical study strongly indicate the prominent roles of local tissue biomechanics in determining the differential mechanical neural encoding functions in different regions of the colorectum. [ABSTRACT FROM AUTHOR]

Published

2019

23. Experimental and computational evidence for an essential role of NaV1.6 in spike initiation at stretch-sensitive colorectal afferent endings

Author

Yi Zhu, Jun-Ho La, Gerald F. Gebhart, Zachary P. Wills, and Bin Feng

Subjects

Male, Physiology, Colon, Rectum, Action Potentials, Sensory Processing, Membrane Potentials, NAV1.8 Voltage-Gated Sodium Channel, Mice, Afferent, Ganglia, Spinal, Physical Stimulation, medicine, Animals, Membrane potential, business.industry, General Neuroscience, Sodium channel, NAV1.7 Voltage-Gated Sodium Channel, Visceral pain, Mice, Inbred C57BL, medicine.anatomical_structure, NAV1.6 Voltage-Gated Sodium Channel, NAV1, medicine.symptom, business, Neuroscience, Mechanoreceptors, Pelvic nerve

Abstract

Stretch-sensitive afferents comprise ∼33% of the pelvic nerve innervation of mouse colorectum, which are activated by colorectal distension and encode visceral nociception. Stretch-sensitive colorectal afferent endings respond tonically to stepped or ramped colorectal stretch, whereas dissociated colorectal dorsal root ganglion neurons generally fail to spike repetitively upon stepped current stimulation. The present study investigated this difference in the neural encoding characteristics between the soma and afferent ending using pharmacological approaches in an in vitro mouse colon-nerve preparation and complementary computational simulations. Immunohistological staining and Western blots revealed the presence of voltage-gated sodium channel (NaV) 1.6 and NaV1.7 at sensory neuronal endings in mouse colorectal tissue. Responses of stretch-sensitive colorectal afferent endings were significantly reduced by targeting NaV1.6 using selective antagonists (μ-conotoxin GIIIa and μ-conotoxin PIIIa) or tetrodotoxin. In contrast, neither selective NaV1.8 (A803467) nor NaV1.7 (ProTX-II) antagonists attenuated afferent responses to stretch. Computational simulation of a colorectal afferent ending that incorporated independent Markov models for NaV1.6 and NaV1.7, respectively, recapitulated the experimental findings, suggesting a necessary role for NaV1.6 in encoding tonic spiking by stretch-sensitive afferents. In addition, computational simulation of a dorsal root ganglion soma showed that, by adding a NaV1.6 conductance, a single-spiking neuron was converted into a tonic spiking one. These results suggest a mechanism/channel to explain the difference in neural encoding characteristics between afferent somata and sensory endings, likely caused by differential expression of ion channels (e.g., NaV1.6) at different parts of the neuron.

Published

2014

24. Long-term sensitization of mechanosensitive and -insensitive afferents in mice with persistent colorectal hypersensitivity

Author

Jun-Ho La, Bin Feng, Gerald F. Gebhart, Timothy P McMurray, Takahiro Tanaka, and Erica S. Schwartz

Subjects

Pathology, medicine.medical_specialty, Physiology, Colon, Inflammation, Stimulation, Nerve fiber, Colonic Diseases, Functional, Mechanotransduction, Cellular, Neuroregulation and Motility, Intracolonic, chemistry.chemical_compound, Mice, Physiology (medical), Physical Stimulation, medicine, Animals, Neurons, Afferent, Irritable bowel syndrome, Sensitization, Hepatology, business.industry, Zymosan, Gastroenterology, Rectum, medicine.disease, medicine.anatomical_structure, Rectal Diseases, chemistry, Mechanosensitive channels, medicine.symptom, business, Mechanoreceptors

Abstract

Afferent input contributes significantly to the pain and colorectal hypersensitivity that characterize irritable bowel syndrome. In the present study, we investigated the contributions of mechanically sensitive and mechanically insensitive afferents (MIAs; or silent afferents) to colorectal hypersensitivity. The visceromotor response to colorectal distension (CRD; 15–60 mmHg) was recorded in mice before and for weeks after intracolonic treatment with zymosan or saline. After CRD tests, the distal colorectum with the pelvic nerve attached was removed for single-fiber electrophysiological recordings. Colorectal afferent endings were located by electrical stimulation and characterized as mechanosensitive or not by blunt probing, mucosal stroking, and circumferential stretch. Intracolonic zymosan produced persistent colorectal hypersensitivity (>24 days) associated with brief colorectal inflammation. Pelvic nerve muscular-mucosal but not muscular mechanosensitive afferents recorded from mice with colorectal hypersensitivity exhibited persistent sensitization. In addition, the proportion of MIAs (relative to control) was significantly reduced from 27% to 13%, whereas the proportion of serosal afferents was significantly increased from 34% to 53%, suggesting that MIAs acquired mechanosensitivity. PGP9.5 immunostaining revealed no significant loss of colorectal nerve fiber density, suggesting that the reduction in MIAs is not due to peripheral fiber loss after intracolonic zymosan. These results indicate that colorectal MIAs and sensitized muscular-mucosal afferents that respond to stretch contribute significantly to the afferent input that sustains hypersensitivity to CRD, suggesting that targeted management of colorectal afferent input could significantly reduce patients' complaints of pain and hypersensitivity.

Published

2012

25. RhoE is associated with relapse and prognosis of patients with colorectal cancer

Author

Kai Li, Yongzhan Nie, Bin Feng, Xin Wang, Jinfeng Zhou, Jianjun Yang, Ping Mo, and Daiming Fan

Subjects

Oncology, rho GTP-Binding Proteins, medicine.medical_specialty, Colorectal cancer, Colon, Vimentin, Kaplan-Meier Estimate, Matrix metalloproteinase, Disease-Free Survival, Metastasis, Surgical oncology, Internal medicine, Cell Line, Tumor, medicine, Confidence Intervals, Gene silencing, Humans, Neoplasm Invasiveness, Gene Silencing, biology, business.industry, Carcinoma, Rectum, Cancer, medicine.disease, Cadherins, Immunohistochemistry, Up-Regulation, Matrix Metalloproteinase 9, Lymphatic Metastasis, biology.protein, Surgery, business, Colorectal Neoplasms

Abstract

RhoE, an atypical Rho protein, is differently deregulated in some solid tumors, and there are conflicting data describing the role of RhoE in tumor cell migration and invasion. This study aimed to investigate RhoE expression in human colorectal cancer and its relationship with clinicopathological features and prognosis. Colorectal cancer and adjacent normal tissues from 202 patients were examined by immunohistochemistry. Staining evaluation results were analyzed statistically in relation to various clinicopathological parameters, disease-free survival, and overall survival. RhoE expression was also investigated by immunohistochemistry in 80 node metastases and the corresponding primary lesions, and by Western blot test in six cancer and adjacent normal tissues. The relationship between RhoE and invasion was examined by transwell assay and Western blot test. The positive rate for RhoE in colorectal cancer was significantly higher than that of normal colorectal tissues. In colorectal cancer, RhoE expression was significantly correlated with depth of invasion, lymph node metastasis, and distant metastasis. Consistently, overexpression of RhoE in SW620 cells up-regulated vimentin, down-regulated E-cadherin, increased the expression of matrix metalloproteinase (MMP) 9, and enhanced cell invasion in vitro; in contrast, silencing of RhoE by a specific siRNA caused opposite effects. Most importantly, disease-free and overall survivals were significantly poorer for patients with RhoE-positive tumors than for those with RhoE-negative tumors. These findings emphasize the positive role of RhoE in invasion and metastasis in human colorectal cancer. It could also serve as an independent prognostic marker in addition to the tumor, node, metastasis staging system.

Published

2011

26. Modulation of visceral hypersensitivity by glial cell line-derived neurotrophic factor family receptoralpha;-3 in colorectal afferents

Author

Gerald F. Gebhart, Bin Feng, Masamichi Shinoda, Kathryn M. Albers, and Takahiro Tanaka

Subjects

medicine.medical_specialty, Pathology, Glial Cell Line-Derived Neurotrophic Factor Receptors, Time Factors, Physiology, Colon, medicine.medical_treatment, Nerve Tissue Proteins, Mechanotransduction, Cellular, Neuroregulation and Motility, Mice, Dorsal root ganglion, Neurotrophic factors, Physiology (medical), Internal medicine, Ganglia, Spinal, medicine, Glial cell line-derived neurotrophic factor, Pressure, Animals, Neurons, Afferent, Receptor, Evoked Potentials, Irritable bowel syndrome, Mice, Knockout, Hepatology, biology, business.industry, Electromyography, Growth factor, Gastroenterology, Rectum, Visceral pain, medicine.disease, Colitis, Pathophysiology, Mice, Inbred C57BL, Disease Models, Animal, medicine.anatomical_structure, Endocrinology, Trinitrobenzenesulfonic Acid, Hyperalgesia, biology.protein, medicine.symptom, business

Abstract

Irritable bowel syndrome is characterized by colorectal hypersensitivity and contributed to by sensitized mechanosensitive primary afferents and recruitment of mechanoinsensitive (silent) afferents. Neurotrophic factors are well known to orchestrate dynamic changes in the properties of sensory neurons. Although pain modulation by proteins in the glial cell line-derived neurotrophic factor (GDNF) family has been documented in various pathophysiological states, their role in colorectal hypersensitivity remains unexplored. Therefore, we investigated the involvement of the GDNF family receptor α-3 (GFRα3) signaling in visceral hypersensitivity by quantifying visceromotor responses (VMR) to colorectal distension before and after intracolonic treatment with 2,4,6-trinitrobenzene sulfonic acid (TNBS). Baseline responses to colorectal distension did not differ between C57BL/6 and GFRα3 knockout (KO) mice. Relative to intracolonic saline treatment, TNBS significantly enhanced the VMR to colorectal distension in C57BL/6 mice 2, 7, 10, and 14 days posttreatment, whereas TNBS-induced visceral hypersensitivity was significantly suppressed in GFRα3 KO mice. The proportion of GFRα3 immunopositive thoracolumbar and lumbosacral colorectal dorsal root ganglion neurons was significantly elevated 2 days after TNBS treatment. In single fiber recordings, responses to circumferential stretch of colorectal afferent endings in C57BL/6 mice were significantly increased (sensitized) after exposure to an inflammatory soup, whereas responses to stretch did not sensitize in GFRα3 KO mice. These findings suggest that enhanced GFRα3 signaling in visceral afferents may contribute to development of colorectal hypersensitivity.

Published

2011

27. Characterization of silent afferents in the pelvic and splanchnic innervations of the mouse colorectum.

Author

Bin Feng and Gebhart, G. F.

Subjects

*ALLERGIES, *IRRITABLE colon, *SPLANCHNIC nerves, *RECTUM, *INNERVATION

Abstract

Hypersensitivity in inflammatory/irritable bowel syndrome is contributed to in part by changes in the receptive properties of colorectal afferent endings, likely including mechanically insensitive afferents (MIAs; silent afferents) that have the ability to acquire mechanosensitivity. The proportion and attributes of colorectal MIAs, however, have not previously been characterized. The distal ~3 cm of colorectum with either pelvic (PN) or lumbar splanchnic (LSN) nerve attached was removed, opened longitudinally, pinned flat in a recording chamber, and perfused with oxygenated Krebs solution. Colorectal receptive endings were located by electrical stimulation and characterized as mechanosensitive or not by blunt probing, mucosal stroking, and circumferential stretch. MIA endings were tested for response to and acquisition of mechanosensitivity by localized exposure to an inflammatory soup (IS). Colorectal afferents were also tested with twin-pulse and repetitive electrical stimulation paradigms. PN MIAs represented 23% of 211 afferents studied, 71% (30/42) of which acquired mechanosensitivity after application of IS to their receptive ending. LSN MIAs represented 33% of 156 afferents studied, only 23% (11/48) of which acquired mechanosensitivity after IS exposure. Mechanosensitive PN endings uniformly exhibited significant twin-pulse slowing whereas LSN endings showed no significant twin-pulse difference. PN MIAs displayed significantly greater activity-dependent slowing than LSN MIAs. In conclusion, significant proportions of MIAs are present in the colorectal innervation; significantly more in the PN than LSN acquire mechanosensitivity in an inflammatory environment. This knowledge contributes to our understanding of the possible roles of MIAs in colon-related disorders like inflammatory/irritable bowel syndrome. [ABSTRACT FROM AUTHOR]

Published

2011