II. Slow oscillations in vaginal blood flow: regulation of vaginal blood flow patterns in rat by central and autonomic mechanisms.

INTRODUCTION: A new method for assessing female sexual arousal through changes in slow oscillatory patterns in vaginal blood flow was first described in the previous manuscript [1]. This method was translational and discriminated between normal healthy volunteers and women with female sexual arousal disorder. AIM: These studies addressed the influence of autonomic and central nervous systems on slow vaginal blood flow oscillations in rats. METHODS: Vaginal blood flow oscillations were measured in urethane-anesthetized rodents using laser Doppler flowmetry. Acquired data were filtered for frequency analysis range of 0.013-2.5 Hz. MAIN OUTCOME MEASURES: Data were assessed for changes in a high frequency range (HF = 0.6-2.5 Hz), and low frequency range (LF = 0.013-0.6 Hz). RESULTS: The basal HF oscillatory component of vaginal blood flow was primarily vagally mediated, although could be modulated pharmacologically with p-chloroamphetamine in the absence of vagal innervation. The LF component could be modulated by antagonists of noradrenergic receptors but did not appear to be dependent upon tonic activation of sympathetic circuitry. The non-selective dopamine receptor agonist apomorphine induced changes in vaginal blood flow oscillations consistent with sexual arousal during metestrus in the presence of the peripheral antagonist domperidone but not in the presence of the centrally acting antagonist haloperidol. Electrical stimulation of the paraventricular nucleus (PVN) of the hypothalamus induced an anti-arousal response in vaginal blood flow oscillations. These data demonstrated that manipulation of the central nervous system alone (via centrally acting apomorphine or electrical stimulation of the PVN) could produce either a pro-arousal or an anti-arousal response in vaginal blood flow oscillations. Alterations in the LF/HF ratio measured from vaginal laser Doppler flowmetry were independently regulated from vasculature in the trunk, the tongue, and electrocardiogram-derived heart rate variability, and were independent of overall vasocongestion of the vagina as measured by mean blood flow. CONCLUSIONS: These data indicated that slow oscillations in vaginal blood flow from rodents may be utilized as an animal model of female sexual arousal. Changes in these oscillations are driven by the central nervous system and modulated by the autonomic nervous system.

I. Slow oscillations in vaginal blood flow: alterations during sexual arousal in rodents and humans.

PURPOSE: This study investigated slow oscillatory rhythms in vaginal blood flow as a physiological marker of female sexual arousal in rodents, human healthy volunteers, and women with female sexual arousal disorder (FSAD). MATERIALS AND METHODS: Vaginal blood flow was measured in urethane-anesthetized rodents using laser Doppler flowmetry, while in humans, vaginal photoplethysmography was used. Acquired data were filtered for frequency analysis in the range of 0.013-2.5 Hz in rodents and 0.01-0.5 Hz in humans. Rodents were assessed for changes in a high frequency range (HF = 0.6-2.5 Hz), and a low frequency range (LF = 0.013-0.6 Hz). Human data were assessed for total spectral power in the entire frequency range. RESULTS: During naturally induced arousal (exposure to male), oscillatory rhythms in vaginal blood flow from rodents demonstrated an increase in the ratio of LF oscillations to HF oscillations (LF/HF ratio). Drugs known to induce sexual arousal (apomorphine and melanotan II) were tested in anesthetized rodents. Both compounds induced an increase in the LF/HF ratio. In humans, visual sexual stimulation induced an increase in the total power of slow oscillatory activity in vaginal blood flow in healthy human volunteers. No such increase was observed in women with FSAD. CONCLUSIONS: This study demonstrated that slow oscillations in vaginal blood flow are correlated with subjective physiological arousal and display diminished responsiveness in women with FSAD. Slow oscillations in vaginal blood flow are entirely independent of vaginal vasocongestion as women with FSAD demonstrated a normal vasocongestion response to visual sexual stimulation. In conditions where rodents would be expected to be sexually aroused, slow oscillations in vaginal blood flow showed a shift from HFs to LFs. This technique will greatly enhance the investigation of female sexual function both clinically and preclinically.

Animal models in urological disease and sexual dysfunction.

There are several conditions associated with dysfunction of the lower urinary tract or which result in a reduction in the ability to engage in satisfactory sexual function and result in significant bother to sufferers, partners and/or carers. This review describes some of the animal models that may be used to discover safe and effective medicines with which to treat them. While alpha adrenoceptor antagonists and 5-alpha-reductase inhibitors deliver improvement in symptom relief in benign prostatic hyperplasia sufferers, the availability of efficacious and well-tolerated medicines to treat incontinence is less well served. Stress urinary incontinence (SUI) has no approved medical therapy in the United States and overactive bladder (OAB) therapy is limited to treatment with muscarinic antagonists (anti-muscarinics). SUI and OAB are characterised by high prevalence, a growing ageing population and a strong desire from sufferers and physicians for more effective treatment options. High patient numbers with low presentation rates characterizes sexual dysfunction in men and women. The introduction of Viagra in 1998 for treating male erectile dysfunction and the success of the phosphodiesterase type 5 inhibitor class (PDE5 inhibitor) have indicated the willingness of sufferers to seek treatment when an effective alternative to injections and devices is available. The main value of preclinical models in discovering new medicines is to predict clinical outcomes. This translation can be established relatively easily in areas of medicine where there are a large number of drugs with different underlying pharmacological mechanisms in clinical usage. However, apart from, for example, the use of PDE5 inhibitors to treat male erectile dysfunction and the use of anti-muscarinics to treat OAB, this clinical information is limited. Therefore, current confidence in existing preclinical models is based on our understanding of the biochemical, physiological, pathophysiological and psychological mechanisms underlying the conditions in humans and how they are reflected in preclinical models. Confidence in both the models used and the pharmacological data generated is reinforced if different models of related aspects of the same disorder generate confirmatory data. However, these models will only be fully validated in retrospect once the pharmacological agents they have helped identify are tested in humans.