BACKGROUND/AIMS: Transient receptor potential vanilloid-1 (TRPV1) is a candidate for mediating acid-induced symptoms in the esophagus. We conducted studies to determine if the presence of acid in the mucosa/submucosa and direct activation of TRPV1 by capsaicin elicited symptoms in normal healthy subjects. We also studied the presence of TRPV1 receptors in the esophagus. METHODS: Unsedated endoscopy was performed on healthy subjects with no symptoms. Using a sclerotherapy needle, normal saline (pH 2.0-7.5) was injected into the mucosa/submucosa, 5 cm above the Z line. In a separate group of healthy subjects, injection of capsaicin and vehicle was also studied. Quality of symptoms was reported using the McGill Pain Questionnaire, and symptom intensity using the visual analogue scale (VAS). Immunohistochemistry was performed on 8 surgical esophagus specimens using TRPV1 antibody. RESULTS: Acid injection either did not elicit or elicited mild symptoms in subjects at all pH solutions. Capsaicin but not the vehicle elicited severe heartburn/chest pain in all subjects. Mean VAS for capsaicin was 91 ± 3 and symptoms lasted for 25 ± 1 minutes. Immunohistochemistry revealed a linear TRPV1 staining pattern between the epithelial layer and the submucosa that extended into the papillae. Eighty-five percent of papillae stained positive for TRPV1 with a mean 1.1 positive papillae per high-powered field. CONCLUSIONS: The mechanism of acid-induced heartburn and chest pain is not the simple interaction of hydrogen ions with afferents located in the esophageal mucosa and submucosa. TRPV1 receptors are present in the lamina propria and their activation induces heartburn and chest pain.
Capsaicin* ; Chest Pain ; Endoscopy ; Esophagus ; Healthy Volunteers ; Heartburn ; Hydrogen-Ion Concentration ; Immunohistochemistry ; Mucous Membrane ; Needles ; Negotiating ; Pain Measurement ; Protons ; Sclerotherapy

Muscularis propria of the esophagus is organized into circular and longitudinal muscle layers. Goal of this review is to summarize the role of longitudinal muscle in physiology and pathophysiology of esophageal sensory and motor function. Simultaneous manometry and ultrasound imaging that measure circular and longitudinal muscle contraction respectively reveal that during peristalsis 2 layers of the esophagus contract in perfect synchrony. On the other hand, during transient relaxation of the lower esophageal sphincter (LES), longitudinal muscle contracts independently of circular muscle. Recent studies provide novel insights, i.e., longitudinal muscle contraction of the esophagus induces LES relaxation and possibly descending relaxation of the esophagus. In achalasia esophagus and other motility disorders there is discoordination between the 2 muscle layers. Longitudinal muscle contraction patterns are different in the recently described three types of achalasia identified by high-resolution manometry. Robust contraction of the longitudinal muscle in type II achalasia causes pan-esophageal pressurization and is the mechanism of whatever little esophageal emptying that take place in the absence of peristalsis and impaired LES relaxation. It may be that preserved longitudinal muscle contraction is also the reason for superior outcome to medical/surgical therapy in type II achalasia esophagus. Prolonged contractions of longitudinal muscles of the esophagus is a possible mechanism of heartburn and "angina like" pain seen in esophageal motility disorders and possibly achalasia esophagus. Novel techniques to record longitudinal muscle contraction are on the horizon. Neuro-pharmacologic control of circular and longitudinal muscles is different, which provides an important opportunity for the development of novel pharmacological therapies to treat sensory and motor disorders of the esophagus.
Contracts ; Esophageal Achalasia ; Esophageal Motility Disorders ; Esophageal Sphincter, Lower ; Esophagus ; Hand ; Heartburn ; Hypogonadism ; Manometry ; Mitochondrial Diseases ; Muscle Contraction ; Muscles ; Ophthalmoplegia ; Peristalsis ; Relaxation

BACKGROUND/AIMS: External anal sphincter (EAS) and puborectalis muscle (PRM) play important role in anal continence function. Based on length-tension measurement, we recently reported that the human EAS muscle operates at short sarcomere length under physiological conditions. Goal of our study was to determine if PRM also operates at the short sarcomere length. METHODS: Length-tension relationship of the PRM muscle was studied in vivo in 10 healthy nullipara women. Length was altered by vaginal distension using custom-designed probes of 5, 10, 15, 20, 25 and 30 mm diameters as well as by distending a polyethylene bag with different volumes of water. Probes were equipped with a reverse perfuse sleeve sensor to measure vaginal pressure (surrogate of PRM tension). PRM electromyogram (EMG) was recorded using wire electrodes. Three-dimensional ultra-sound images were obtained to determine effect of vaginal distension on PRM length. RESULTS: Ultrasound images demonstrate distension volume dependent increase in PRM length. Rest and squeeze pressures of vaginal bag increased with the increase in bag volume. Similarly, the change in vaginal pressure, which represents the PRM contraction increased with the increase in the probe size. Increase in probe size was not associated with an increase in EMG activity (a marker of neural drive) of the PRM. CONCLUSIONS: Probe size dependent increase in PRM contraction pressure, in the presence of constant EMG (neural input) proves that the human PRM operates at short sarcomere length. Surgically adjusting the PRM length may represent a novel strategy to improve treat anal continence and possibly other pelvic floor disorders.
Anal Canal ; Electrodes ; Fecal Incontinence* ; Female ; Humans ; Muscles ; Pelvic Floor Disorders* ; Polyethylene ; Sarcomeres ; Ultrasonography ; Water

Background/Aims: The esophageal hiatus is formed by the right crus of the diaphragm in the majority of subjects. Contraction of the hiatus exerts a sphincter-like action on the lower esophageal sphincter (LES). The aim is to study the hiatal anatomy (using CT scan imaging) and function (using high-resolution manometry [HRM]), and esophageal motor function in patients with sliding and paraesophageal hiatal hernia. Methods: We assessed normal subjects (n = 20), patients with sliding type 1 hernia (n = 18), paraesophageal type 2 hernia (n = 19), and mixed type 3 hernia (n = 19). Hernia diagnosis was confirmed on the upper gastrointestinal series. The hiatal morphology was constructed from the CT scan images. The LES pressure and relaxation, percent peristalsis, bolus pressure, and hiatal squeeze pressure were assessed by HRM. Results: The CT images revealed that the esophageal hiatus is formed by the right crus of the diaphragm in all normal subjects and 86% of hernia patients. The hiatus is elliptical in shape with a surface area of 1037 mm2 in normal subjects. The hiatal dimensions were larger in patients compared to normal subjects. The HRM revealed impaired LES relaxation and higher bolus pressure in patients with paraesophageal compared to the sliding hernia. The hiatal pinch on HRM was recognized in significantly higher number of patients with sliding as compared to paraesophageal hernia. Conclusions Using a novel approach, we provide details of the esophageal hiatus in patients with various kinds of hiatal hernia. Impaired LES relaxation in paraesophageal hernia may play a role in its pathophysiology and genesis of symptoms.

Background/Aims: Pharyngeal pump, esophageal peristalsis, and phrenic ampulla emptying play important roles in the propulsion of bolus from the mouth to the stomach. There is limited information available on the mechanism of normal and abnormal phrenic ampulla emptying.The goal of our study is to describe the relationship between bolus flow and esophageal pressure profiles during the phrenic ampulla emptying in normal subjects and patient with phrenic ampulla dysfunction. Methods: Pressure (using topography) and bolus flow (using changes in impedance) relationship through the esophagus and phrenic ampulla were determined in 15 normal subjects and 15 patients with retrograde escape of bolus from the phrenic ampulla into esophagus during primary peristalsis. Results: During the phrenic ampulla phase, 2 high pressure peaks (proximal, related to lower esophageal sphincter and distal, related to crural diaphragm) were observed in normal subjects and patients during the phrenic ampulla emptying phase. The proximal was always higher than the distal one in normal subjects; in contrast, reverse was the case in patients with the retrograde escape of bolus from the phrenic ampulla into the esophagus. Conclusions We propose that a strong after-contraction of the lower esophageal sphincter plays an important role in the normal phrenic ampullary emptying. A defective lower esophageal after-contraction, along with high crural diaphragm pressure are responsible for the phrenic ampulla emptying dysfunction.

Background/Aims: Pharyngeal pump, esophageal peristalsis, and phrenic ampulla emptying play important roles in the propulsion of bolus from the mouth to the stomach. There is limited information available on the mechanism of normal and abnormal phrenic ampulla emptying.The goal of our study is to describe the relationship between bolus flow and esophageal pressure profiles during the phrenic ampulla emptying in normal subjects and patient with phrenic ampulla dysfunction. Methods: Pressure (using topography) and bolus flow (using changes in impedance) relationship through the esophagus and phrenic ampulla were determined in 15 normal subjects and 15 patients with retrograde escape of bolus from the phrenic ampulla into esophagus during primary peristalsis. Results: During the phrenic ampulla phase, 2 high pressure peaks (proximal, related to lower esophageal sphincter and distal, related to crural diaphragm) were observed in normal subjects and patients during the phrenic ampulla emptying phase. The proximal was always higher than the distal one in normal subjects; in contrast, reverse was the case in patients with the retrograde escape of bolus from the phrenic ampulla into the esophagus. Conclusions We propose that a strong after-contraction of the lower esophageal sphincter plays an important role in the normal phrenic ampullary emptying. A defective lower esophageal after-contraction, along with high crural diaphragm pressure are responsible for the phrenic ampulla emptying dysfunction.

Background/Aims: Pharyngeal pump, esophageal peristalsis, and phrenic ampulla emptying play important roles in the propulsion of bolus from the mouth to the stomach. There is limited information available on the mechanism of normal and abnormal phrenic ampulla emptying.The goal of our study is to describe the relationship between bolus flow and esophageal pressure profiles during the phrenic ampulla emptying in normal subjects and patient with phrenic ampulla dysfunction. Methods: Pressure (using topography) and bolus flow (using changes in impedance) relationship through the esophagus and phrenic ampulla were determined in 15 normal subjects and 15 patients with retrograde escape of bolus from the phrenic ampulla into esophagus during primary peristalsis. Results: During the phrenic ampulla phase, 2 high pressure peaks (proximal, related to lower esophageal sphincter and distal, related to crural diaphragm) were observed in normal subjects and patients during the phrenic ampulla emptying phase. The proximal was always higher than the distal one in normal subjects; in contrast, reverse was the case in patients with the retrograde escape of bolus from the phrenic ampulla into the esophagus. Conclusions We propose that a strong after-contraction of the lower esophageal sphincter plays an important role in the normal phrenic ampullary emptying. A defective lower esophageal after-contraction, along with high crural diaphragm pressure are responsible for the phrenic ampulla emptying dysfunction.