Pioglitazone improves visceral sensation and colonic permeability in a rat model of irritable bowel syndrome

Visceral hypersensitivity and impaired gut barrier with minor inflammation are considered to play an important role in the pathophysiology of irritable bowel syndrome (IBS). Since pioglitazone is known to have anti-inflammatory property, we hypothesized that pioglitazone is beneficial for treating IBS. In this study, the effect was tested in rat IBS models such as lipopolysaccharide or repeated water avoidance stress-induced visceral allodynia and increased colonic permeability. Pioglitazone blocked these visceral changes, and GW9662, a peroxisome proliferator-activated receptor gamma (PPAR-γ) antagonist fully reversed the effect by pioglitazone. These results suggest that PPAR-γ activation by pioglitazone may be useful for IBS treatment.     

Review article: evaluation of drugs in experimental gut distension models

Distension of the gastrointestinal tract elicits abdominal pain, as well as sensations such as discomfort or fullness. Many patients with irritable bowel syndrome have been reported to show a reduced threshold to the pain or discomfort due to experimental rectal distension. This hypersensitivity of the gut may be characteristic of the irritable bowel, as well as other functional gastrointestinal disorders. Intestinal distension in animals induces a range of responses which have been used as indexes of visceral nociception. This paper reviews a recently introduced canine model used to assess the antinociceptive properties of a novel 5-HT₃ receptor antagonist, alosetron.     

Gastrointestinal afferents as targets of novel drugs for the treatment of functional bowel disorders and visceral pain.

An intricate surveillance network consisting of enteroendocrine cells, immune cells and sensory nerve fibres monitors the luminal and interstitial environment in the alimentary canal. Functional bowel disorders are characterized by persistent alterations in digestive regulation and gastrointestinal discomfort and pain. Visceral hyperalgesia may arise from an exaggerated sensitivity of peripheral afferent nerve fibres and/or a distorted processing and representation of gut signals in the brain. Novel strategies to treat these sensory bowel disorders are therefore targeted at primary afferent nerve fibres. These neurons express a number of molecular traits including transmitters, receptors and ion channels that are specific to them and whose number and/or behaviour may be altered in chronic visceral pain. The targets under consideration comprise vanilloid receptor ion channels, acid-sensing ion channels, sensory neuron-specific Na(+) channels, P2X(3) purinoceptors, 5-hydroxytryptamine (5-HT), 5-HT(3) and 5-HT(4) receptors, cholecystokinin CCK(1) receptors, bradykinin and prostaglandin receptors, glutamate receptors, tachykinin and calcitonin gene-related peptide receptors as well as peripheral opioid and cannabinoid receptors. The utility of sensory neuron-targeting drugs in functional bowel disorders will critically depend on the compounds' selectivity of action for afferent versus enteric or central neurons.     

Antidepressants in the treatment of irritable bowel syndrome and visceral pain syndromes

Irritable bowel syndrome (IBS) is characterized by abdominal pain associated with disordered defecation, which may include urgency and altered stool frequency. Visceral pain syndromes, including IBS, may be effectively treated by a variety of therapies that modulate the interactions between the central and enteric nervous systems. Clinical observations and preliminary data suggest that antidepressants may be efficacious for the treatment of these syndromes. The tricyclic antidepressants (TCAs) have been utilized most extensively in this area, but there is a need for more rigorous efficacy data. Serotonin, an important neurotransmitter in both the central and enteric nervous systems, modifies both motility and sensation in the gut. Recognition of the importance of serotonin in digestive motility and sensation has sparked interest in the use of agents that modify serotonergic transmission in visceral pain syndromes. Pharmacological therapeutics that modulate the biological amines (serotonin, norepinephrine, dopamine and catecholamines) both peripherally and within the central nervous system may offer more effective therapies for these disorders. The selective serotonin reuptake inhibitors are commonly used in clinical practice, but more rigorous, controlled studies are needed to determine their effects beyond the treatment of psychiatric comorbidity. The newer generation antidepressants may provide additional insight into the pathophysiology of the brain-gut interactions and their relationship to functional bowel disorders, providing new therapeutic interventions.     

Review article: gastrointestinal sensory and motor disturbances in inflammatory bowel disease - clinical relevance and pathophysiological mechanisms

Background It is well known that inflammation has a profound impact on the neuromuscular apparatus of the gastrointestinal tract during the inflammatory insult and in periods of remission, at the site of inflammation and at distance from this site. The importance of this interaction is illustrated by the higher prevalence of functional gut disorders in patients with inflammatory bowel disease. Aims To document the epidemiological and clinical significance of functional alterations of gut motility and sensitivity in patients with inflammatory bowel disease and to formulate potential pathophysiological mechanisms. Results and conclusions Functional gut disorders occur frequently in patients with inflammatory bowel disease, both during inflammatory episodes and in periods of remission, and have a major impact on their quality of life. The clinical manifestations of these motility and sensitivity disorders vary and are often difficult to treat, mainly because therapeutic guidelines and specific diagnostic tests to distinguish inflammatory bowel disease from functional gut disorders are lacking. Chronic bowel inflammation results in a complicated interaction between neuroendocrine serotonin‐predominant cells of the mucosa, inflammatory cells (particularly mast cells) in the submucosa, the intrinsic and extrinsic innervation and the muscular apparatus including the interstitial cells of Cajal. The outcome of this interaction is a perturbation of gastrointestinal motor function, both locally and at distance from the site of inflammation and during both acute inflammation and remission.     

Disturbed upper gastrointestinal sensation: an important abnormality?

The relationship between disturbed upper gastro-intestinal motility and symptoms of heartburn and dyspepsia varies. For example, in some symptomatic patients abnormal motor events are not detected, whereas, conversely, impaired motor patterns may be recorded in patients who are asymptomatic. Nociceptive visceral afferents arising in the gut transmit peripheral sensations to the brain. It has been postulated that variations in sensory afferent activity are responsible for the inconsistent expression of disturbed upper gastrointestinal motility. Several studies have demonstrated that patients with so-called functional symptoms, which appear to arise from normal gut regions, exhibit a lower perception threshold to stimuli that distend the gut. Such visceral hypersensitivity could explain the occurrence of symptoms in the absence of demonstrable physiological or morphological abnormalities. Evidence that variations in visceral sensory afferent activity constitute an important disease mechanism is not conclusive. In certain conditions such as non-cardiac chest pain and functional dyspepsia, visceral hypersensitivity provides a useful hypothetical framework. Not only has this framework established a basis for previously unexplained symptoms, but perhaps more importantly it has stimulated research to develop novel pharmacological agents to modulate nociception. The challenge is now to establish putative pathogenetic links between aberrant sensory activity and disturbed upper gastrointestinal motility, and also to locate the neural abnormalities along the gut-brain axis.     

Immunology of hypersensitivity pneumonitis

Hypersensitivity pneumonitis (extrinsic allergic alveolitis) represents a spectrum of granulomatous, interstitial, and alveolar-filling lung disorders of which farmer's lung is a classic example. A major source of offending antigens in these diseases are thermophilic actinomycetes growing in moldy vegetable matter especially Micropolyspora faeni, and members of the Thermoactinomyces genus. Acutely, hypersensitivity pneumonitis presents as cough, dyspnea and fever, with crepitant rales, leucocytosis, diffuse interstitial and alveolar pulmonary infiltrates and a restrictive-type pulmonary functional deficit. Symptoms usually begin 4 to 6 hr after exposure to large quantities of causative organic dust. Chronically, these diseases may present with the gradual onset of cough, dyspnea on exertion, fatigue, anorexia, and weight loss which may progress to pulmonary fibrosis or severe pulmonary insufficiency. While early ideas on the pathogenesis of hypersensitivity pneumonitis support the role of Type III immune complex hypersensitivity, more recent evidence attests to the important and integral role of Type IV or delayed-type hypersensitivity. It is the purpose of this review, therefore, to describe those immune mechanisms relevant to the pathogenesis of hypersensitivity pneumonitis and stress the importance of "local" pulmonary immune responsiveness.     

Towards identifying optimal doses for alpha-2 adrenergic modulation of colonic and rectal motor and sensory function

RATIONALE: Visceral sensation and motility are important in functional gut disorders and are partly controlled by adrenergic innervation. OBJECTIVES: To characterize the alpha2-adrenergic control of motor and sensory function of descending colon and rectum. METHODS: In 32 healthy volunteers, we assessed compliance, fasting and postprandial tone, and sensations of gas, urgency and pain during phasic distentions. Each subject received one agent at clinically approved doses: clonidine (0.05, 0.1, 0.2 or 0.3 mg p.o. ); or the alpha2 antagonist yohimbine (0.0125 mg, 0.05 mg, 0.125 mg or 0.2 mg intravenously and infusion over 2.5 h). RESULTS: Clonidine increased colonic and rectal compliance, and reduced tone, pain, gas sensation and rectal urgency. Clonidine showed large pairwise differences in sensation and motility between 0.05 and 0.1 mg doses, which did not interfere with the colon's motor response to feeding. Conversely, yohimbine dose-dependently altered the compliance curve, increased tone and sensations of gas, pain and urgency. Drug effects in the colon were more marked at low distensions; alpha2 modulation of rectal sensation was observed at all levels of distension. CONCLUSIONS: alpha2-adrenergic mechanisms modulate colorectal sensations and motility; at doses as low as 0.05 mg, clonidine reduced colorectal sensation while the tone response to feeding was preserved. These studies provide insight into the potential use of alpha2 agents in disease states.     

Review article: drugs interfering with visceral sensitivity for the treatment of functional gastrointestinal disorders--the clinical evidence

At present, the concept of visceral hypersensitivity provides the leading hypothesis regarding the generation of symptoms in functional gastrointestinal disorders. This paper discusses the current clinical evidence for drugs that have been proposed to interfere with visceral sensitivity in functional gastrointestinal disorders. Several possible pharmacological targets have been identified to reduce visceral pain and to reverse the processes underlying the persistence of visceral hypersensitivity. However, most of the available evidence comes from experimental animal models and cannot simply be extrapolated to patients with functional gastrointestinal disorders. In this review, we selected five drug classes that have been shown to exhibit visceral analgesic properties in experimental studies, and of which data were available regarding their clinical efficacy. These included opioid substances, serotonergic agents, antidepressants, somatostatin analogues and alpha(2)-adrenergic agonists. Although clinical trials show a limited benefit, in particular for serotonergic agents, the evidence illustrating that these effects result from normalization of visceral sensation is currently lacking. Therefore, we conclude that the concept of targeting visceral hypersensitivity as a treatment for functional gastrointestinal disorders is still controversial. Future evaluations require patient selection based on the presence of visceral hypersensitivity and application of compounds that exhibit 'true' viscerosensory effects.     

Review article: bloating in functional bowel disorders

Bloating is a frequently reported symptom in functional bowel disorders. It usually occurs in combination with other symptoms, but may also occur in isolation. The severity of bloating tends to worsen during the course of the day and improves overnight. Although frequently considered to be a subjective phenomenon, recent studies have shown that bloating is associated with a measurable increase in abdominal girth. The pathophysiology of bloating remains elusive, but the evidence supports a sensorimotor dysfunction of the bowel. The possible mechanisms include abnormal gas trapping, fluid retention, food intolerance and altered gut microbial flora. Further studies are needed to define the sensorimotor abnormalities associated with bloating, which might be segmental and transient rather than generalized and persistent. The lack of understanding of this symptom is paralleled by a limited availability of therapeutic options. Conventional medications used in functional bowel disorders are not helpful and may indeed worsen the symptoms. In future, new drugs with activity against serotonin and kappa receptors, or novel approaches such as the use of exclusion diets, probiotics and hypnotherapy, may prove to be useful.     

Review article: fructose malabsorption and the bigger picture

Fructose is found widely in the diet as a free hexose, as the disaccharide, sucrose and in a polymerized form (fructans). Free fructose has limited absorption in the small intestine, with up to one half of the population unable to completely absorb a load of 25 g. Average daily intake of fructose varies from 11 to 54 g around the world. Fructans are not hydrolysed or absorbed in the small intestine. The physiological consequences of their malabsorption include increasing osmotic load, providing substrate for rapid bacterial fermentation, changing gastrointestinal motility, promoting mucosal biofilm and altering the profile of bacteria. These effects are additive with other short-chain poorly absorbed carbohydrates such as sorbitol. The clinical significance of these events depends upon the response of the bowel to such changes; they have a higher chance of inducing symptoms in patients with functional gut disorders than asymptomatic subjects. Restricting dietary intake of free fructose and/or fructans may have durable symptomatic benefits in a high proportion of patients with functional gut disorders, but high quality evidence is lacking. It is proposed that confusion over the clinical relevance of fructose malabsorption may be reduced by regarding it not as an abnormality but as a physiological process offering an opportunity to improve functional gastrointestinal symptoms by dietary change.     

Enterochromaffin cells and 5-HT signaling in the pathophysiology of disorders of gastrointestinal function

Disorders of gastrointestinal function are common and significantly reduce quality-of-life, as well as negatively impacting healthcare costs. Consequently, there is much interest in understanding the pathogenesis of these disorders. Increasing, albeit as yet limited, evidence has implicated alterations in 5-hydroxytryptamine (5-HT) release, and the subsequent interaction of 5-HT with specific 5-HT receptor subtypes, in the altered gut function of patients with irritable bowel syndrome (IBS) and other functional bowel diseases. Alterations to enterochromaffin cells and/or 5-HT signaling can result in gastrointestinal dysmotility, visceral hypersensitivity and secretomotor abnormalities in the gut. Evidence is beginning to link disturbed 5-HT physiology with the pathophysiology of diarrhea and constipation in IBS, and with slow-transit constipation. This review discusses the current evidence on the pathobiology of these systems.     

Review article: the hypersensitive gut—peripheral kappa agonists as a new pharmacological approach

Hypersensitivity to pain is a common component of functional bowel disorders. Hyperalgesia may be induced by various stimuli which produce a cocktail of inflammatory mediators that decrease the pain threshold. Drugs able to block these peripheral events within the gut may offer a new pharmacological approach for treating functional bowel disorders. Kappa opioids have been shown to inhibit somatic pain through a peripheral mechanism of action, acting directly on receptors located on peripheral sensory endings. They can block both the nociceptive messages as well as the release of sensory peptides. This paper reviews the effects of opioid agonists on gut visceral pain and motility anomalies induced by visceral pain. Kappa opioids have strong effects on all models tested, with a peripheral mechanism of action allowing the design of drugs acting only in the periphery and having no central nervous system side-effects. This contrasts with mu agonists which are centrally active on pain and worsen the subsequent transit and motility anomalies.     

New developments in the treatment of functional dyspepsia

Functional dyspepsia is a clinical syndrome defined by chronic or recurrent pain or discomfort in the upper abdomen of unknown origin. Although generally accepted, investigators differently interpret this definition and clinical trials are often biased by inhomogeneous inclusion criteria.The poorly defined multifactorial pathogenesis of dyspeptic symptoms has hampered efforts to develop effective treatments. A general agreement exists on the irrelevant role played by Helicobacter pylori in the pathophysiology of functional dyspepsia. Gastric acid secretion is within normal limits in patients with functional dyspepsia but acid related symptoms may arise in a subgroup of them. Proton pump inhibitors appear to be effective in this subset of patients with dyspepsia. Non-painful dyspeptic symptoms are suggestive of underlying gastrointestinal motor disorders and such abnormalities can be demonstrated in a substantial proportion of patients. Postprandial fullness and vomiting have been associated with delayed gastric emptying of solids, and early satiety and weight loss to postcibal impaired accommodation of the gastric fundus. Prokinetics have been shown to exert beneficial effects, at least in some patients with dyspepsia. In contrast, drugs enhancing gastric fundus relaxation have been reported to improve symptoms, although conflicting results have also been published. An overdistended antrum may also generate symptoms, but its potential pathogenetic role and the effects of drugs on this abnormality have never been investigated formally. Visceral hypersensitivity plays a role in some dyspeptic patients and this abnormality is also a potential target for treatment. Both chemo- and mechanoreceptors can trigger hyperalgesic responses. Psychosocial abnormalities have been consistently found in functional digestive syndromes, including dyspepsia. Although useful in patients with irritable bowel syndromes (IBS), antidepressants have been only marginally explored in functional dyspepsia.Among the new potentially useful agents for the treatment of functional dyspepsia, serotonin 5-HT(4) receptor agonists have been shown to exert a prokinetic effect. Unlike motilides, 5-HT(4) receptor agonists do not appear to increase the gastric fundus tone and this may contribute to improve symptoms. 5-HT(3) receptor antagonists have been investigated mainly in the IBS and the few studies performed in functional dyspepsia have provided conflicting results. Also, kappa-opioid receptor agonists might be useful for functional digestive syndromes because of their antinociceptive effects, but available results in functional dyspepsia are scanty and inconclusive. Other receptors that represent potential clinical targets for antagonists include purinoceptors (i. e., P2X2/3 receptors), NMDA receptors (NR2B subtype), protease-activated receptor-2, the vanilloid receptor-1, tachykinin receptors (NK(1)/NK(2)) and cholecystokinin (CCK)(1) receptors.     

Pharmacology and clinical experience with fedotozine

Fedotozine [(1R)-1-phenyl-1-[(3,4,5-trimethoxy)benzyloxymethyl]-N,N- dimethyl-n-propylamine, (2S,3S-tartrate] is derived from the arylacetamide series. As with other compounds of this series, fedotozine is more or less selective of kappa(1)-opioid receptors and particularly for the kappa(1a)-receptor subtype, where it acts as an agonist. Pharmacological studies have shown that fedotozine exerts a peripheral antinociceptive action, comparable with that of other kappa-agonists. Its main effects have been demonstrated at the level of the afferent nerve pathways originating from the gut. Fedotozine alters the processing of visceral sensations along these pathways and hence, the perception of gut stimuli at the brain level. It modifies reflexes induced in various pathological conditions, like experimental inflammation of the gut, chemically-induced peritonitis or post-operative ileus. Fedotozine also decreases the nociceptive reflexes triggered by noxious gut distension in animals. In humans, fedotozine decreases the perception of gut distension, both in physiological and pathological conditions. Clinical trials undertaken in patients with functional digestive disorders, non-ulcer dyspepsia and irritable bowel syndrome, have shown that fedotozine relieves abdominal pain in these patients in 6-week treatments. kappa-Opioid receptors remain an interesting area for future development of new treatments for abdominal pain in patients with functional digestive disorders.     

Post-inflammatory modification of colonic afferent mechanosensitivity

1. The present review discusses interactions between the immune and nervous systems in post-infectious irritable bowel syndrome (PI-IBS).
2. Visceral pain is the single symptom that most affects the quality of life of patients with irritable bowel syndrome (IBS), yet it is the least successfully managed. An underlying hypersensitivity of colonic afferents to mechanical stimuli has long been implicated in visceral pain in IBS, but little more is known of the physiological aetiology.
3. The PI-IBS patients are a cohort of IBS patients who attribute their symptoms to a preceding gastrointestinal infection by pathogens such as Campylobacter or Salmonella . Current evidence suggests that the immune system remains activated in these patients and contributes to their visceral hypersensitivity. This is characterized by a shift in the phenotype of circulating immune cells towards a Type 1 (Th1 predominating) state. Products from these immune cells sensitize colonic afferents to mechanical stimuli.
4. Rectal instillation of trinitrobenzene sulphonic acid induces a Th1-mediated inflammatory response, consistent with clinical observations in PI-IBS. The visceral hypersensitivity observed in this model is biphasic, with an initial onset characterized by visceral hypersensitivity correlating with histological damage followed by a delayed phase that occurs after histological recovery. Interestingly, this chronic visceral hypersensitivity is mediated by afferents in closest apposition to blood vessels, but furthest from the initial site of damage.
5. Both clinical and experimental evidence indicates that chronic dysregulation of the immune system induces visceral afferent hypersensitivity and, therefore, may be the central mechanism underlying PI-IBS.     

Role of ion channels in mechanisms controlling gastrointestinal pain pathways

Hypersensitivity or sensitization of nociceptive primary afferents in the gastrointestinal tract has been proposed as a mechanism for organic and functional gastrointestinal pain. This hypersensitivity can be the result of alterations, either induced by a sensitizing agent or without a peripheral cause, in the functional properties of ion channels located in primary afferents. The tetrodotoxin-resistent sodium channel, known as Na(v)1.8, is present in nociceptive primary afferents, including those from the gut, and it has been implicated as being the main candidate for the enhanced activity that characterizes nociceptor sensitization. Other voltage-gated channels, such as calcium and potassium channels, can also contribute to the sensitization of primary afferents observed in gastrointestinal pain states.     

Autophagy and Digestive Disorders: Advances in Understanding and Therapeutic Approaches

The gastrointestinal (GI) tract is a series of hollow organs that is responsible for the digestion and absorption of ingested foods and the excretion of waste. Any changes in the GI tract can lead to GI disorders. GI disorders are highly prevalent in the population and account for substantial morbidity, mortality, and healthcare utilization. GI disorders can be functional, or organic with structural changes. Functional GI disorders include functional dyspepsia and irritable bowel syndrome. Organic GI disorders include inflammation of the GI tract due to chronic infection, drugs, trauma, and other causes. Recent studies have highlighted a new explanatory mechanism for GI disorders. It has been suggested that autophagy, an intracellular homeostatic mechanism, also plays an important role in the pathogenesis of GI disorders. Autophagy has three primary forms: macroautophagy, microautophagy, and chaperone-mediated autophagy. It may affect intestinal homeostasis, host defense against intestinal pathogens, regulation of the gut microbiota, and innate and adaptive immunity. Drugs targeting autophagy could, therefore, have therapeutic potential for treating GI disorders. In this review, we provide an overview of current understanding regarding the evidence for autophagy in GI diseases and updates on potential treatments, including drugs and complementary and alternative medicines.     

Pharmacology and clinical experience with fedotozine

Fedotozine {(1R)-1-phenyl-1-[(3,4,5-trimethoxy)benzyloxymethyl]-N,N- dimethyl-n-propylamine, (2S,3S-tartrate} is derived from the arylacetamide series. As with other compounds of this series, fedotozine is more or less selective of ₁-opioid receptors and particularly for the _1a-receptor subtype, where it acts as an agonist. Pharmacological studies have shown that fedotozine exerts a peripheral antinociceptive action, comparable with that of other κ-agonists. Its main effects have been demonstrated at the level of the afferent nerve pathways originating from the gut. Fedotozine alters the processing of visceral sensations along these pathways and hence, the perception of gut stimuli at the brain level. It modifies reflexes induced in various pathological conditions, like experimental inflammation of the gut, chemically-induced peritonitis or post-operative ileus. Fedotozine also decreases the nociceptive reflexes triggered by noxious gut distension in animals. In humans, fedotozine decreases the perception of gut distension, both in physiological and pathological conditions. Clinical trials undertaken in patients with functional digestive disorders, non-ulcer dyspepsia and irritable bowel syndrome, have shown that fedotozine relieves abdominal pain in these patients in 6-week treatments. κ-Opioid receptors remain an interesting area for future development of new treatments for abdominal pain in patients with functional digestive disorders.     

Food hypersensitivity and irritable bowel syndrome

Irritable bowel syndrome is a common condition but its pathophysiology remains poorly understood. Many irritable bowel syndrome patients give a history of food intolerance, but data from dietary elimination and re-challenge studies are inconclusive. Multiple aetio-pathological mechanisms have been postulated. The gut has an extensive immune system but current understanding of processing of food antigens in health and disease is limited. There is no clinically useful marker available to test for food hypersensitivity in irritable bowel syndrome. Researchers have employed both skin tests and serum immunoglobulins (IgG and IgE) as markers of food hypersensitivity in various disorders including irritable bowel syndrome, but published data are equivocal. In this article, the evidence for the role of food hypersensitivity in irritable bowel syndrome is reviewed and, based on the available data, a possible pathophysiological hypothesis has been formulated.