Your search keyword '"J, Keightley"' showing total 11 results

1. Novel intrinsic neurogenic and myogenic mechanisms underlying the formation of faecal pellets along the large intestine of guinea‐pigs

Author

Simon J. H. Brookes, Phil G. Dinning, Melinda Kyloh, Timothy J. Hibberd, Marcello Costa, Lauren J. Keightley, Nick J. Spencer, and Lukasz Wiklendt

Subjects

Colon, Physiology, Guinea Pigs, Rectum, Myogenic mechanism, Feces, 03 medical and health sciences, symbols.namesake, Cecum, 0302 clinical medicine, medicine, Animals, Large intestine, Intestine, Large, Migrating motor complex, 030304 developmental biology, Myoelectric Complex, Migrating, 0303 health sciences, Reabsorption, Chemistry, digestive, oral, and skin physiology, Interstitial cell of Cajal, Cell biology, medicine.anatomical_structure, symbols, 030211 gastroenterology & hepatology, Enteric nervous system, Gastrointestinal Motility

Abstract

Key points In herbivores, including guinea pigs, clearly defined faecal pellets are formed at a distinct location along the large intestine (colonic flexure). The mechanism underlying formation of these faecal pellets at this region has remained, until now, a major unresolved issue. We reveal a progressive and gradual reduction in water content of faecal content along the bowel. Hence, the distinct transition from amorphous to pellet shaped faecal content could not be explained by a dramatic increase in water reabsorption from a specific site. We discovered novel patterns of anterograde neurogenic and retrograde myogenic motor activity that facilitate the formation of faecal pellets. The formation of "pellet-like" boluses at the colonic flexure involves the interaction of an antegrade migrating motor complex in the proximal colon and retrograde myogenic slow phasic contractions at the colonic flexure. The findings uncover major new intrinsic mechanisms responsible for the formation of discrete faecal scybala in the large intestine of a vertebrate. Abstract Soft faecal material is transformed into discrete, pellet-shaped faeces at the colonic flexure. Here, analysis of water content in natural faecal material revealed a decline from cecum to rectum without significant changes at the flexure. Thus, pellet formation is not explained by changes in viscosity alone. We then used video imaging of colonic wall movements with electromyography in isolated preparations containing guinea-pig proximal colon, colonic flexure and distal colon. To study the pellet formation process, the colonic segments were infused with artificial contents (Krebs solution and 4-6% methylcellulose) to simulate physiological faecal content flow. Remarkably, pellet formation took place in vitro, without extrinsic neural inputs. Infusion evoked slowly propagating neurogenic contractions, the proximal colonic migrating motor complexes (∼0.6cpm), which initiated pellet formation at the flexure. Lesion of the flexure, but not the proximal colon, disrupted formation of normal individual pellets. In addition, a distinct myogenic mechanism was identified, whereby slow phasic contractions (∼1.9cpm) initiated at the flexure and propagated short distances retrogradely into the proximal colon and antegradely into the distal colon. There were no detectable changes in the density or distribution of pacemaker-type Interstitial Cells of Cajal across the flexure. The findings provide new insights into how solid faecal content is generated, suggesting the major mechanisms underlying faecal pellet formation involve the unique interaction at the colonic flexure between antegrade PCMMCs, organized by enteric neurons, and retrograde myogenic SPCs. Additional, as yet unidentified extrinsic and/or humoral influences appear to contribute to processing of faecal content, in vivo. This article is protected by copyright. All rights reserved.

Published

2021

2. Mechanisms underlying initiation of propulsion in guinea pig distal colon

Author

Timothy J. Hibberd, Marcello Costa, David J. Smolilo, Lauren J. Keightley, Simon J. Brookes, Phil G. Dinning, and Nick J. Spencer

Subjects

Hepatology, Physiology, Colon, Physiology (medical), Calcitonin Gene-Related Peptide, Guinea Pigs, Gastroenterology, Animals, Receptors, Nicotinic, Hexamethonium, Synaptic Transmission

Abstract

Colonic motor complexes (CMCs) are a major neurogenic activity in guineapig distal colon. The identity of the enteric neurons that initiate this activity is not established. Specialized intrinsic primary afferent neurons (IPANs) are a major candidate. We aimed to test this hypothesis. To do this, segments of guineapig distal colon were suspended vertically in heated organ baths and propulsive forces acting on a pellet inside the lumen were recorded by isometric force transducer while pharmacological agents were applied to affect IPAN function. In the absence of drugs, CMCs acted periodically on the pellet, generating peak propulsive forces of 12.7 ± 5 g at 0.56 ± 0.22 cpm, lasting 49 ± 17 s (215 preparations

Published

2022

3. Roles of three distinct neurogenic motor patterns during pellet propulsion in guinea‐pig distal colon

Author

Phil G. Dinning, Lukasz Wiklendt, Marcello Costa, Taher Omari, John W. Arkwright, Timothy J. Hibberd, Lauren J. Keightley, Nick J. Spencer, Simon J. H. Brookes, David Wattchow, and Vladimir P. Zagorodnyuk

Subjects

Male, 0301 basic medicine, Colon, Physiology, Guinea Pigs, Neuromuscular transmission, Action Potentials, Motor Activity, Propulsion, 03 medical and health sciences, 0302 clinical medicine, medicine, Biological neural network, Animals, Large intestine, High resolution manometry, Migrating motor complex, Myoelectric Complex, Migrating, Electromyography, Chemistry, Muscle, Smooth, Electrophysiology, 030104 developmental biology, medicine.anatomical_structure, Biophysics, Female, Enteric nervous system, Gastrointestinal Motility, 030217 neurology & neurosurgery, Muscle Contraction

Abstract

Key points Enteric neural circuits enable isolated preparations of guinea-pig distal colon to propel solid and fluid contents by a self-sustaining neuromechanical loop process. In addition there are at least three neural mechanisms which are not directly involved in propulsion: cyclic motor complexes, transient neural events and distal colon migrating motor complexes. In excised guinea-pig colon we simultaneously recorded high resolution manometry, video-imaging of colonic wall movements and electrophysiological recordings from smooth muscle, which enabled us to identify mechanisms that underlie the propulsion of colonic content. The results show that the intermittent propulsion during emptying of the multiple natural faecal pellets is due to the intermittent activation of cyclic motor complexes and this is facilitated by transient neural events. Loss or dysfunction of these activities is likely to underlie disordered gastrointestinal transit. Abstract It is well known that there are different patterns of electrical activity in smooth muscle cells along different regions of the gastrointestinal tract. These different patterns can be generated by myogenic and/or neurogenic mechanisms. However, what patterns of electrical activity underlie the propulsion of natural faecal content remains unknown, particularly along the large intestine, where large quantities of water are reabsorbed and semi-solid faeces form. In this study, we developed a novel approach which enables for the first time the simultaneous recording of high resolution intraluminal manometry, electrophysiology from the smooth muscle, and spatio-temporal video imaging of colonic wall movements. Using this approach we were able to reveal the nature of enteric neuromuscular transmission and patterns of motor activity responsible for the movement of content. Three distinct neurogenic patterns of electrical activity were recorded even in the absence of propulsive movement. These were the cyclic motor complexes (CMCs), the transient neural events (TNEs) and the slowly propagating distal colonic migrating motor complexes (DCMMCs). We present evidence that the initiation of pellet propulsion is due to a cyclic motor complex (CMC) occurring oral to the pellet. Furthermore, we discovered that the intermittent propulsion of natural faecal pellets is generated by intermittent activation of CMCs; and this propulsion is facilitated by hexamethonium-sensitive TNEs. However, TNEs were not required for propulsion. The findings reveal the patterns of electrical activity that underlie propulsion of natural colonic content and demonstrate that propulsion is generated by a complex interplay between distinct enteric neural circuits.

Published

2019

4. Functional changes in low- and high-threshold afferents in obstruction-induced bladder overactivity

Author

Simon J. H. Brookes, Marcello Costa, Lauren J. Keightley, Nick J. Spencer, Vladimir P. Zagorodnyuk, and Sarah Nicholas

Subjects

Male, medicine.medical_specialty, Physiology, Guinea Pigs, Urinary Bladder, 030232 urology & nephrology, Urology, Action Potentials, Urination, urologic and male genital diseases, 03 medical and health sciences, Bladder outlet obstruction, 0302 clinical medicine, Lower urinary tract symptoms, medicine, Animals, Afferent Pathways, Urinary Bladder, Overactive, business.industry, medicine.disease, female genital diseases and pregnancy complications, Urinary Bladder Neck Obstruction, Disease Models, Animal, Urodynamics, Spinal Nerves, Sensory Thresholds, business, Mechanoreceptors, 030217 neurology & neurosurgery

Abstract

Neural mechanisms of lower urinary tract symptoms in obstruction-induced bladder overactivity remain unclear. We made the first single unit recordings from different types of spinal afferents to determine the effects of bladder outlet obstruction in guinea pigs. A model of gradual bladder outlet obstruction in male guinea pigs was used to produce overactive bladder. Conscious voiding was assessed in metabolic cages, and micturition was recorded in anesthetized guinea pigs in vivo. Single unit extracellular recordings were made ex vivo from spinal afferent nerves in flat sheet preparations of the bladder. Guinea pigs with partially obstructed bladders showed a significant increase in conscious voiding frequency compared with sham-operated guinea pigs. Also, nonvoiding contractions increased significantly in both frequency and amplitude. Although spontaneous firing of low-threshold bladder afferents was increased, their stretch-induced firing was reduced. The proportion of capsaicin-sensitive low-threshold afferents increased in obstructed bladders. Interestingly, spontaneous and stretch-induced firing were both significantly increased in high-threshold afferents after obstruction. In summary, sensory signaling increased in the obstructed bladder during the filling phase. This is largely mediated by low-threshold stretch-sensitive afferents that are activated by increased local nonvoiding contractions. Increased spontaneous firing by high-threshold afferents also contributes. Our findings revealed a complex effect of bladder outlet obstruction on different types of bladder afferents that needs consideration for potential therapeutic targeting of lower urinary tract symptoms in obstruction-induced bladder overactivity.

Published

2019

5. Motor patterns in the proximal and distal mouse colon which underlie formation and propulsion of feces

Author

Nick J. Spencer, Phil G. Dinning, Lukasz Wiklendt, Timothy J. Hibberd, Simon J. H. Brookes, Marcello Costa, and Lauren J. Keightley

Subjects

Male, 0301 basic medicine, Colon, Physiology, Stimulus (physiology), Biology, Guinea pig, Feces, Mice, 03 medical and health sciences, 0302 clinical medicine, Smooth muscle, medicine, Extracellular, Animals, Large intestine, Pellet Formation, Peristalsis, Endocrine and Autonomic Systems, Gastroenterology, Anatomy, Mice, Inbred C57BL, 030104 developmental biology, medicine.anatomical_structure, Mouse Colon, Female, 030211 gastroenterology & hepatology, Gastrointestinal Motility, Muscle Contraction

Abstract

Background In herbivores, the proximal and distal colonic regions feature distinct motor patterns underlying formation and propulsion of fecal pellets, respectively. Omnivores, such as mice and humans, lack a similar clear anatomical transition between colonic regions. We investigated whether distinct processes form and propel content along the large intestine of a mouse (an omnivore). Methods We recorded propulsive and non-propulsive neurogenic motor activity in mouse large intestine under six different stimulus conditions of varying viscosities. Gut wall movements were recorded by video and smooth muscle electrical behavior recorded with extracellular suction electrodes. Key results Three major neurally mediated motor patterns contributed to pellet formation and propulsion. (1) Pellet-shaped boluses are pinched off near the ceco-colonic junction and slowly propelled distally to a transition located at 40% length along the colon. (2) At this functional colonic flexure, propulsion speed is significantly increased by self-sustaining neural peristalsis. Speed transition at this location also occurs with artificial pellets and with spontaneously formed boluses in the empty colon. (3) Periodic colonic motor complexes (CMCs) were present in all conditions reaching a maximal frequency of about 0.4 cpm and extending across the proximal and distal colon with faster speed of propagation. Conclusions and inferences The three motor patterns share a unique underlying fundamental property of the enteric circuits, which involve extended ensembles of enteric neurons firing at close to 2 Hz. The demonstration of distinct functional differences between proximal and distal colon in rabbit, guinea pig, and now mouse raises the possibility that this may be an organizational principle in other mammalian species, including humans.

Published

2021

6. Characterization of alternating neurogenic motor patterns in mouse colon

Author

David Smolilo, Lukasz Wiklendt, Marcello Costa, Phil G. Dinning, Nick J. Spencer, Simon J. H. Brookes, Lauren J. Keightley, and Timothy J. Hibberd

Subjects

0301 basic medicine, Colon, Physiology, Action Potentials, Motility, Mice, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Large intestine, Peristalsis, Myoelectric Complex, Migrating, Endocrine and Autonomic Systems, Chemistry, Gastroenterology, Muscle, Smooth, In vitro, Cell biology, 030104 developmental biology, Mouse Colon, medicine.anatomical_structure, 030211 gastroenterology & hepatology, Enteric nervous system, Gastrointestinal Motility, Colonic motility, Ex vivo

Abstract

Background Colonic motor complexes (CMCs) have been widely recorded in the large intestine of vertebrates. We have investigated whether in the smooth muscle, a single unified pattern of electrical activity, or different patterns of electrical activity give rise to the different neurogenic patterns of motility underlying CMCs in vitro. Methods To study differences of the CMCs between proximal and distal colon, we used a novel combination of techniques to simultaneously record muscle diameter and force at multiple sites along the whole mouse colon ex vivo. In addition, electrical activity of smooth muscle was recorded by suction electrodes. Key results Two distinct types of CMCs were distinguished; CMCs that propagated along the entire colon (complete CMC) and CMCs which were restricted to the proximal colon (incomplete CMC). The two types of CMC often occurred in the same preparations. Incomplete CMCs had longer bursts of smooth muscle action potentials than complete CMCs and propagated more slowly. Interestingly, both types of CMC were associated with similar frequency bursts of smooth muscle action potentials at ~2.4 Hz. In the most proximal colon, an additional firing frequency was detected close to ~7 Hz generating multiple peaks within each CMC. Conclusions & inferences We report distinct characteristics underlying complete and incomplete CMCs in isolated mouse colon. Recognizing these distinct patterns of motility will be important for future interpretation of analysis of murine colonic motility recordings. The identification of alternating patterns of motor activity in proximal colon, but not distal colon may reflect specific neural mechanisms for fecal pellet formation.

Published

2020

7. Identification of neurogenic intestinal motility patterns in silver perch (Bidyanus bidyanus) that persist over wide temperature ranges

Author

Bradley S. Jones, Lauren J. Keightley, Nick J. Spencer, Phil G. Dinning, James O. Harris, and Lukasz Wiklendt

Subjects

0301 basic medicine, medicine.medical_specialty, Physiology, Motility, Nicotinic Antagonists, Tetrodotoxin, Hexamethonium, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Internal medicine, medicine, Animals, 14. Life underwater, Perch, biology, Endocrine and Autonomic Systems, Gastroenterology, Temperature, biology.organism_classification, Intestinal motility, Cold Temperature, Intestines, 030104 developmental biology, Endocrinology, Nicotinic agonist, chemistry, Perches, %22">Fish , 030211 gastroenterology & hepatology, Bidyanus bidyanus, Isotonic Solutions, Gastrointestinal Motility, Sodium Channel Blockers

Abstract

BACKGROUND Fish are increasingly being utilized as a model species for genetic manipulation studies related to gastrointestinal (GI) motility. Our aim was to identify whether patterns of GI motility in fish and the mechanisms underlying their generation are similar to those recorded from mammals (including humans). METHODS The entire intestine was removed from euthanized adult Silver Perch (n = 11) and lesioned at the midway point to obtain two equal lengths. Proximal and distal segments were studied separately in organ baths with oxygenated Krebs solution, maintained at either 15°C (n = 5) or 25°C (n = 6). Motility was analyzed during rest, after oral infusion of Krebs solution, and after application of hexamethonium (100 µM) and tetrodotoxin (TTX) (0.6 µM). KEY RESULTS Antegrade and retrograde propagating contractions (PC) were recorded in all preparations. In the proximal intestine, at 15 and 25°C, retrograde PCs occurred at 2.7 [1.7-4.5] and 3.1 [1.6-6.5] times the frequency of antegrade PCs, respectively. Colder temperatures did not inhibit PC frequency. Hexamethonium did not inhibit PC, and however, TTX abolished all contractile activity. CONCLUSIONS AND INFERENCES Both neurogenic antegrade and retrograde propagating contractions occur throughout the intestine of Silver Perch. However, unlike the mammalian colon, these motor patterns do not require enteric nicotinic transmission and they are not inhibited by cold temperatures (15°C). Therefore, while the GI motility patterns in Silver Perch resemble those recorded from the colon of mammals, there may be differences in the mechanisms that underlying their generation.

Published

2020

8. Neural motor complexes propagate continuously along the full length of mouse small intestine and colon

Author

Marcello Costa, Lukasz Wiklendt, Simon J. H. Brookes, Timothy J. Hibberd, Philip G. Dinning, Lauren J. Keightley, Nick J. Spencer, and John W. Arkwright

Subjects

Male, Time Factors, Physiology, Colon, Ganglionic Blockers, Mouse Small Intestine, In Vitro Techniques, Cholinergic Antagonists, Enteric Nervous System, 03 medical and health sciences, 0302 clinical medicine, Physiology (medical), Intestine, Small, medicine, Pressure, Animals, 030304 developmental biology, 0303 health sciences, Myoelectric Complex, Migrating, Hepatology, Chemistry, Gastroenterology, Anatomy, Small intestine, Mice, Inbred C57BL, medicine.anatomical_structure, 030211 gastroenterology & hepatology, Female, Peristalsis, Cholinesterase Inhibitors

Abstract

Cyclical propagating waves of muscle contraction have been recorded in isolated small intestine or colon, referred to here as motor complexes (MCs). Small intestinal and colonic MCs are neurogenic, occur at similar frequencies, and propagate orally or aborally. Whether they can be coordinated between the different gut regions is unclear. Motor behavior of whole length mouse intestines, from duodenum to terminal rectum, was recorded by intraluminal multisensor catheter. Small intestinal MCs were recorded in 27/30 preparations, and colonic MCs were recorded in all preparations ( n = 30) with similar frequencies (0.54 ± 0.03 and 0.58 ± 0.02 counts/min, respectively). MCs propagated across the ileo-colonic junction in 10/30 preparations, forming “full intestine” MCs. The cholinesterase inhibitor physostigmine increased the probability of a full intestine MC but had no significant effect on frequency, speed, or direction. Nitric oxide synthesis blockade by Nω-nitro-l-arginine, after physostigmine, increased MC frequency in small intestine only. Hyoscine-resistant MCs were recorded in the colon but not small intestine ( n = 5). All MCs were abolished by hexamethonium ( n = 18) or tetrodotoxin ( n = 2). The enteric neural mechanism required for motor complexes is present along the full length of both the small and large intestine. In some cases, colonic MCs can be initiated in the distal colon and propagate through the ileo-colonic junction, all the way to duodenum. In conclusion, the ileo-colonic junction provides functional neural continuity for propagating motor activity that originates in the small or large intestine.NEW & NOTEWORTHY Intraluminal manometric recordings revealed motor complexes can propagate antegradely or retrogradely across the ileo-colonic junction, spanning the entire small and large intestines. The fundamental enteric neural mechanism(s) underlying cyclic motor complexes exists throughout the length of the small and large intestine.

Published

2019

9. Identification of multiple distinct neurogenic motor patterns that can occur simultaneously in the guinea pig distal colon

Author

John W. Arkwright, Lukasz Wiklendt, Taher Omari, Timothy J. Hibberd, David Wattchow, Phil G. Dinning, Nick J. Spencer, Marcello Costa, Lauren J. Keightley, and Simon J. H. Brookes

Subjects

0301 basic medicine, Pathology, medicine.medical_specialty, Physiology, Colon, Neurogenesis, Guinea Pigs, Action Potentials, Myenteric Plexus, Electromyography, Biology, Guinea pig, 03 medical and health sciences, 0302 clinical medicine, Physiology (medical), medicine, Animals, Motor Neurons, Myoelectric Complex, Migrating, Hepatology, medicine.diagnostic_test, Gastroenterology, Muscle, Smooth, 030104 developmental biology, 030211 gastroenterology & hepatology, Distal colon, Gastrointestinal Motility

Abstract

In the guinea pig distal colon, nonpropulsive neurally mediated motor patterns have been observed in different experimental conditions. Isolated segments of guinea pig distal colon were used to investigate these neural mechanisms by simultaneously recording wall motion, intraluminal pressure, and smooth muscle electrical activity in different conditions of constant distension and in response to pharmacological agents. Three distinct neurally dependent motor patterns were identified: transient neural events (TNEs), cyclic motor complexes (CMC), and distal colon migrating motor complexes (DCMMC). These could occur simultaneously and were distinguished by their electrophysiological, mechanical, and pharmacological features. TNEs occurred at irregular intervals of ~3s, with bursts of action potentials at 9 Hz. They propagated orally at 12 cm/s via assemblies of ascending cholinergic interneurons that activated final excitatory and inhibitory motor neurons, apparently without involvement of stretch-sensitive intrinsic primary afferent neurons. CMCs occurred during maintained distension and consisted of clusters of closely spaced TNEs, which fused to cause high-frequency action potential firing at 7 Hz lasting ~10 s. They generated periodic pressure peaks mediated by stretch-sensitive intrinsic primary afferent neurons and by cholinergic interneurons. DCMMCs were generated by ongoing activity in excitatory motor neurons without apparent involvement of stretch-sensitive neurons, cholinergic interneurons, or inhibitory motor neurons. In conclusion, we have identified three distinct motor patterns that can occur concurrently in the isolated guinea pig distal colon. The mechanisms underlying the generation of these neural patterns likely involve recruitment of different populations of enteric neurons with distinct temporal activation properties.

Published

2018

10. New insights into neurogenic cyclic motor activity in the isolated guinea-pig colon

Author

Philip G. Dinning, Lukasz Wiklendt, Marcello Costa, Simon J. H. Brookes, Lauren J. Keightley, and Nick J. Spencer

Subjects

Myoelectric Complex, Migrating, Endocrine and Autonomic Systems, Physiology, Colon, Manometry, Guinea Pigs, Gastroenterology, Muscle, Smooth, Smooth muscle contraction, Anatomy, Distension, Contractility, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, chemistry, Muscle tension, Tetrodotoxin, Animals, 030211 gastroenterology & hepatology, Hexamethonium, Enteric nervous system, 030217 neurology & neurosurgery, Peristalsis, Muscle Contraction

Abstract

Background The contents of the guinea pig distal colon consist of multiple pellets that move anally in a coordinated manner. This row of pellets results in continued distention of the colon. In this study, we have investigated quantitatively the features of the neurally dependent colonic motor patterns that are evoked by constant distension of the full length of guinea-pig colon. Methods Constant distension was applied to the excised guinea-pig by high-resolution manometry catheters or by a series of hooks. Key Results Constant distension elicited regular Cyclic Motor Complexes (CMCs) that originated at multiple different sites along the colon and propagated in an oral or anal direction extending distances of 18.3±10.3 cm. CMCs were blocked by tetrodotoxin (TTX; 0.6 μ mol L−1), hexamethonium (100 μ mol L−1) or hyoscine (1 μ mol L−1). Application of TTX in a localized compartment or cutting the gut circumferentially disrupted the spatial continuity of CMCs. Localized smooth muscle contraction was not required for CMC propagation. Shortening the length of the preparations or disruption of circumferential pathways reduced the integrity and continuity of CMCs. Conclusions & Inferences CMCs are a distinctive neurally dependent cyclic motor pattern, that emerge with distension over long lengths of the distal colon. They do not require changes in muscle tension or contractility to entrain the neural activity underlying CMC propagation. CMCs are likely to play an important role interacting with the neuromechanical processes that time the propulsion of multiple natural pellets and may be particularly relevant in conditions of impaction or obstruction, where long segments of colon are simultaneously distended.

Published

2017

11. Conscious voiding during bladder obstruction in guinea pigs correlates with contractile activity of isolated bladders

Author

Sarah Nicholas, Simon J. H. Brookes, Vladimir P. Zagorodnyuk, Marcello Costa, Ian L. Gibbins, and Lauren J. Keightley

Subjects

Male, medicine.medical_specialty, Contraction (grammar), Consciousness, media_common.quotation_subject, Physostigmine, Guinea Pigs, Urinary Bladder, Urology, Urination, Bethanechol, Distension, Muscarinic Agonists, urologic and male genital diseases, Cellular and Molecular Neuroscience, Bladder outlet obstruction, medicine, Animals, media_common, Urinary bladder, Bladder Obstruction, Dose-Response Relationship, Drug, Endocrine and Autonomic Systems, business.industry, Urinary bladder neck obstruction, Muscle, Smooth, Organ Size, medicine.disease, female genital diseases and pregnancy complications, Urinary Bladder Neck Obstruction, Disease Models, Animal, medicine.anatomical_structure, Neurology (clinical), Cholinesterase Inhibitors, business, medicine.drug, Muscle Contraction

Abstract

Purpose There are many hypotheses accounting for detrusor overactivity; however, the exact mechanisms are still incompletely understood. We used a model of bladder outlet obstruction in male guinea pigs as a way to produce detrusor overactivity. The objective was to determine whether changes in voiding of obstructed guinea pigs correlates with specific changes in contractile activity of their isolated bladders in vitro. Material and methods Conscious voiding activity of sham-operated and obstructed animals was measured in metabolic cages. Contractile activity (spontaneous or evoked by distension, electrical field stimulation or cholinergic agonists) was recorded via a pressure transducer in the isolated bladders in vitro. Results The frequency of conscious voiding increased (while voiding volume decreased) in the obstructed group, compared with the sham-operated group, 4 weeks after surgical intervention. In comparison to the sham-operated animals, the bladders from the obstructed guinea pigs were enlarged and inflamed, their frequency of spontaneous contractions was higher, while the amplitudes of electrical field stimulation (EFS)-induced contractions and bladder compliance were lower. Changes in conscious voiding during obstruction were significantly associated with alterations in structural parameters (bladder weight, thickness and histological damage score) and functional contractile parameters (frequency of spontaneous contractions, amplitude of EFS-induced contractions and bladder compliance) of their isolated bladders. Conclusions Our findings revealed significant association between conscious voiding and structural and contractile activity changes of the isolated bladders in obstruction. The data suggest that change in contractile activity of the bladder itself is a major contributor to obstruction-induced bladder overactivity.

Published

2015