Urethral closure mechanisms under sneeze-induced stress condition in rats: a new animal model for evaluation of stress urinary incontinence

The urethral closure mechanism under a stress condition induced by sneezing was investigated in urethane-anesthetized female rats. During sneezing, while the responses measured by microtip transducer catheters in the proximal and middle parts of the urethra increased, the response in the proximal urethra was almost negligible when the bladder response was subtracted from the urethral response or when the abdomen was opened. In contrast, the response in the middle urethra during sneezing was still observed after subtracting the bladder response or after opening the abdomen. These responses in the middle urethra during sneezing were significantly reduced approximately 80% by bilateral transection of the pudendal nerves and the nerves to the iliococcygeous and pubococcygeous muscles but not by transection of the visceral branches of the pelvic nerves and hypogastric nerves. The sneeze leak point pressure was also measured to investigate the role of active urethral closure mechanisms in maintaining total urethral resistance against sneeze-induced urinary incontinence. In sham-operated rats, no urinary leakage was observed during sneeze, which produced an increase of intravesical pressure up to 37 +/- 2.2 cmH2O. However, in nerve-transected rats urinary leakage was observed when the intravesical pressure during sneezing exceeded 16.3 +/- 2.1 cmH2O. These results indicate that during sneezing, pressure increases elicited by reflex contractions of external urethral sphincter and pelvic floor muscles occur in the middle portion of the urethra. These reflexes in addition to passive transmission of increased abdominal pressure significantly contribute to urinary continence mechanisms under a sneeze-induced stress condition.     

Decay of inspiratory muscle pressure during expiration in anesthetized cats

In six spontaneously breathing anesthetized cats (pentobarbital sodium, 35 mg/kg) we studied the antagonistic pressure developed by the inspiratory muscles during expiration (PmusI). This was accomplished in two ways: 1) with our previously reported method (J. Appl. Physiol.: Respirat. Environ. Exercise Physiol. 52: 1266-1271, 1982) based on the measurement of changes in lung volume and airflow during spontaneous expiration, together with determination of the total passive respiratory system elastance and resistance; and 2) measurement of the time course of changes in tracheal/pressure after airway occlusion at end inspiration, up to the moment when the inspiratory muscles become completely relaxed. The agreement between the two methods is generally good, both in the amplitude of PmusI and in its time course. We also applied the first method to spontaneous expirations through added linear resistive loads. These did not alter the relative decay of PmusI. Thus in anesthetized cats the braking action of the inspiratory muscles does not decrease when expiratory resistive loads are added, i.e., when such braking is clearly not required.     

Carotid chemoreceptor discharge during epinephrine infusion in anesthetized cats.

It is known that during exercise there is an increase in plasma epinephrine. The purpose of the present investigation was to determine whether stimulation of carotid chemoreceptors by epinephrine is a direct effect or secondary to epinephrine-induced increases in arterial plasma [K+] and whole body CO2 production (VCO2). Chemoreceptor discharge was recorded from single fiber preparations of the carotid sinus nerves in anesthetized cats ventilated to a constant arterial PCO2 (PaCO2). Infusion of epinephrine (1 microgram.kg-1 x min-1) caused arterial [K+] to increase from a mean of 2.7 to 3.8 mM. VCO2 increased so that ventilation had to be increased by 60% to maintain PaCO2 constant. Mean chemoreceptor discharge increased by 50%, but this was no greater than would be predicted on the basis of the increases in arterial [K+] and VCO2. In a further group of experiments epinephrine was infused at 0.1 microgram.kg-1 x min-1 and produced no significant increase in chemoreceptor firing. These experiments provide no evidence for epinephrine having a direct effect on the carotid chemoreceptor.     

Efferent activity in the phrenic nerve during startle reflex in chloralose anesthetized cats

Efferent activity was investigated in the phrenic nerve during startle reflex manifesting as somatic nerve discharges (lower intercostal nerves and the nerve endings) in chloralose anesthetized cats. Inhibition (usually of short duration, lasting 23–36 msec) of inspiration activity was found to be the main component of response in the phrenic nerve in the shaping of "low threshold" startle reflex produced by acoustic and tactile stimuli and stimulation of low threshold peripheral afferents. Reflex discharge prevailed amongst the response patterns produced in the phrenic nerve by stimulating high threshold afferents, i.e., early (propriospinal) and late (suprasegmental, arising from stimulating intercostal nerve) or late only (when stimulating the hindlimb nerves). Two patterns of late response could be distinguished, one on inspiration (found in roughly 3 out of 4 experiments) and other on exhalation — the respiratory homologs of somatic startle reflex. Response pattern is described throughout the respiratory cycle. Structure and respiratory modulation of reflex responses produced in the phrenic nerve by stimulating bulbar respiratory structure are also examined. Possible neurophysiological mechanisms underlying phrenic response during the shaping of startle reflex are discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 19, No. 4, pp. 473–482, July–August, 1987.     

Synaptic excitation of reticulospinal neurons during the startle reaction in cats anesthetized with chloralose

Synaptic processes in reticulospinal neurons of the pons and medulla during the startle reaction evoked by somatic stimulation were investigated in cats anesthetized with chloralose. The main type of response of reticulospinalneurons was found to be PSPs involving intrareticular (proprioreticular) pathways of varied complexity: oligosynaptic (including supposedly monosynaptic) and polysynaptic. Comparison of EPSP characteristics with parameters of spino-bulbospinal (SBS) discharges recorded simultaneously in the intercostal nerves showed that polysynaptic EPSPs evoked through corresponding proprioreticular pathways were most effective in creating a descending SBS volley. About half the reticulospinal neurons of the pons and medulla were involved at any one time in the synaptic relay process during the startle reflex. The conduction velocity in axons of these neurons varied from 30 to 98 m/sec (means 64.5 Mp 16.5 m/sec). Some distinguishing features of the functional organization of the reticular "center" for the startle reaction are discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 13, No. 6, pp. 594–603, November–December, 1981.     

Urethral catheterization of the female rat

Urinary tract catheterization of the rat may be required for a variety of clinical and experimental reasons. The external urinary orifice is easily visualized and rests anterior to the vaginal opening, making urinary tract catheterization easier in the female rat than in other species. This column describes a technique for short-term urethral catheterization in the adult female rat.     

Selective metabolic effects of salbutamol in anesthetized cats.

Salbutamol was found to produce a selective stimulation of beta adrenergic receptors mediating metabolic responses in anesthesized cats. Salbutamol was infused intravenously at a rate of 1 μg/Kg/min; this agent produced a significant decrease in diastolic blood pressure and concomitantly increased blood glucose and lactate while decreasing plasma potassium. Salbutamol did not elevate plasma free fatty acids. In contrast to salbutamol, comparable infusions of isoproterenol produced all cardiovascular and metabolic effects non-selectively. The cardiovascular and metabolic effects of salbutamol were blocked by oxprenolol, a beta adrenergic receptor antagonist. The apparent selectivity of action of salbutamol suggests that metabolic beta adrenergic receptors are heterogeneous and can be differentiated into at least two separate types.     

Laryngeal-receptor responses to phasic CO2 in anesthetized cats

We compared the effects ofCO₂ applied continuously andduring expiration on laryngeal-receptor activity in paralyzed,artificially ventilated and nonparalyzed, spontaneously breathing catsby using an isolated larynx, artificially ventilated to approximate anormal respiratory cycle. The majority of quiescent negative-pressure and all cold receptors were excited by 5 and 9%CO₂ applied both continuously andduring expiration. In general, quiescent positive-pressure, tonicnegative-pressure, and tonic positive-pressure receptors were inhibitedby 5 and 9% CO₂ appliedcontinuously and during expiration. There were no significantdifferences between responses to 5 and 9%CO₂ or to continuous and expiredCO₂ or between paralyzed andnonparalyzed preparations. In conclusion, laryngeal receptors respondto changes in CO₂ concentrationoccurring during a normal respiratory cycle. Because laryngeal-receptorstimulation exerts reflex effects on ventilation and upper airwaymuscle activity, these results suggest that airwayCO₂ plays a role in reflexregulation of breathing and upper airway patency.