Dissociation of tactile and acoustic components in air puff startle

Targeting Peripheral Somatosensory Neurons to Improve Tactile-Related Phenotypes in ASD Models

Somatosensory over-reactivity is common among patients with autism spectrum disorders (ASDs) and is hypothesized to contribute to core ASD behaviors. However, effective treatments for sensory over-reactivity and ASDs are lacking. We found distinct somatosensory neuron pathophysiological mechanisms underlie tactile abnormalities in different ASD mouse models and contribute to some ASD-related behaviors. Developmental loss of ASD-associated genes Shank3 or Mecp2 in peripheral mechanosensory neurons leads to region-specific brain abnormalities, revealing links between developmental somatosensory over-reactivity and the genesis of aberrant behaviors. Moreover, acute treatment with a peripherally restricted GABAA receptor agonist that acts directly on mechanosensory neurons reduced tactile over-reactivity in six distinct ASD models. Chronic treatment of Mecp2 and Shank3 mutant mice improved body condition, some brain abnormalities, anxiety-like behaviors, and some social impairments but not memory impairments, motor deficits, or overgrooming. Our findings reveal a potential therapeutic strategy targeting peripheral mechanosensory neurons to treat tactile over-reactivity and select ASD-related behaviors.

The adhesion molecule cadherin 11 is essential for acquisition of normal hearing ability through middle ear development in the mouse

Cadherin 11 (Cdh11), a member of the cadherin adhesion molecule family, is expressed in various regions of the brain as well as the head and ear. To gain further insights into the roles of Cdh11 in the development of the ear, we performed behavioral tests using Cdh11 knockout (KO) mice. KO mice showed reduced acoustic startle responses and increased thresholds for auditory brainstem responses, indicating moderate hearing loss. The auditory bulla volume and ratio of air-filled to non-air-filled space in the middle ear cavity were reduced in KO mice, potentially causing conductive hearing loss. Furthermore, residual mesenchymal and inflammatory cells were observed in the middle ear cavity of KO mice. Cdh11 was expressed in developing mesenchymal cells just before the start of cavitation, indicating that Cdh11 may be directly involved in middle ear cavitation. Since the auditory bulla is derived from the neural crest, the regulation of neural crest-derived cells by Cdh11 may be responsible for structural development. This mutant mouse may be a promising animal model for elucidating the causes of conductive hearing loss and otitis media.

Kinesthetic stimulation for obstructive sleep apnea syndrome: An "on-off" proof of concept trial

Obstructive sleep apnea (OSA) occurs when the upper airway narrows or collapses due to the loss of upper airway muscle activation at sleep onset. This study investigated the effectiveness of triggered kinesthetic stimulation in patients with OSA. This proof-of-concept, open-label, multicenter prospective study was conducted on 24 patients with severe OSA. During a one night evaluation, kinesthetic stimulation was intermittently delivered in 30 minute periods. The duration of apneas and hypopneas during Stim _on and Stim _off periods were compared. Five hospital-based university centers in France participated. Sleep studies were evaluated by a single scorer at a core laboratory (CHU Grenoble). Results show that during the Stim _on phases, statistically significant decreases in durations of apneas and hypopneas were observed in 56% and 46% of patients, respectively. Overall, 75% of patients showed an improvement in apneas or hypopneas durations. The mean reduction in durations for patients with a significant decrease was 4.86 seconds for apneas and 6.00 seconds for hypopneas. This proof of concept study is the first to identify kinesthetic stimulation as a potentially effective therapy for OSA. These data justify evaluation in a controlled study.

Biological implications of coeruleospinal inhibition of nociceptive processing in the spinal cord

The coeruleospinal inhibitory pathway (CSIP), the descending pathway from the nucleus locus coeruleus (LC) and the nucleus subcoeruleus (SC), is one of the centrifugal pain control systems. This review answers two questions regarding the role coeruleospinal inhibition plays in the mammalian brain. First is related to an abnormal pain state, such as inflammation. Peripheral inflammation activated the CSIP, and activation of this pathway resulted in a decrease in the extent of the development of inflammatory hyperalgesia. During inflammation, the responses of the dorsal horn neurons to graded heat stimuli in the LC/SC-lesioned rats did not produce a further increase with the increase of stimulus intensity in the higher range temperatures. These results suggest that the function of CSIP is to maintain the accuracy of intensity coding in the dorsal horn because the plateauing of the heat-evoked response in the LC/SC-lesioned rats during inflammation is due to a response saturation that results from the lack of coeruleospinal inhibition. The second concerns attention and vigilance. During freezing behavior induced by air-puff stimulation, nociceptive signals were inhibited by the CSIP. The result implies that the CSIP suppresses pain system to extract other sensory information that is essential for circumstantial judgment.

Relationship between PPI and baseline startle response

Prepulse inhibition (PPI) of the startle response to a sudden noise is the reduction in startle observed when the noise is preceded shortly by a mild sensory event, which is often a tone. A part of the literature is based on the assumption that PPI is independent of the baseline startle. A simple model is presented and experimental validation provided. The model is based on the commonly accepted observation that the neuronal circuit of PPI differs from that of startle. But, by using a common output, the measures of both phenomena become linked to each other. But, how can we interpret the numerous experimental data showing PPI to be independent of the startle level? It is suggested that in a number of such cases the baseline startle would have been stabilized by a ceiling effect in the startle/PPI neuronal networks. Reducing the startle level, for example in a PPI evaluation procedure, may disclose properties of startle masked by this ceiling effect. Disclosure of habituation to the startle eliciting noise produced an increase of PPI along its initial measurements. Taken together, even if the neuronal process that sustains startle and PPI are distinct, separating them experimentally requires careful parametric methods and caution in the interpretation of the corresponding observations.

The nucleus locus coeruleus/subcoeruleus contributes to antinociception during freezing behavior following the air-puff startle in rats

An air puff elicits a startle response in mammals. Following the startle response, rats react with a defensive-like, immobile posture (DIP) of approximately 2-5s in length. We have previously reported that air-puff stimulation (APS) activates the nucleus locus coeruleus/subcoeruleus (LC/SC) so that the DIP is induced. The LC/SC is one of the structures that plays an important role in endogenous pain control. Our particular interest is whether APS induces nociceptive modulation. Rats were tested for behavioral nociception with heating of the tail. Rats whisked their tail following heating and then bit the heat source when the tail could not escape heating by tail flick. The tail flick latency (TFL) and the bite latency (BL) were measured as an indicator of nociception. Compressed house air (14.4 psi in strength, 0.1s in duration) was presented for APS. Two weeks before the experiment, the rats received bilateral injections of 6 μg of the neurotoxin 6-hydroxydopamine to specifically lesion noradrenaline-containing neurons of the LC/SC. APS produced prolongation of the TFL and the BL. In both the TFL and the BL, APS-induced prolongation was not observed in rats with the LC/SC lesions. When BLs were plotted against DIP periods, the BL was almost constant regardless of the change in the DIP period. These results suggest that (1) APS produces nociceptive modulation, (2) the LC/SC is involved in APS-induced nociceptive modulation, and (3) two APS-induced events, the DIP and nociceptive modulation, are a parallel phenomenon.

The modulatory effects of rostral ventromedial medulla on air-puff evoked microarousals in rats

This study tested whether the duration of microarousals from sleep evoked by innocuous air-puff is affected by intra-RVM administration of neurotensin and bicuculline, pharmacological manipulations that affect on and off cell activity. Air-puff evoked microarousal duration was unaffected by 0.05ng neurotensin, but decreased by 502ng neurotensin, and 5 and 50ng bicuculline. These results suggest a putative role for off cells in protecting sleep from interruption by non-noxious stimuli.

The nucleus locus coeruleus/subcoeruleus affects the defensive-like, immobile posture following an air-puff startle reaction in the rat

The air-puff startle is an example of a simple behavior in mammals. Following the startle reaction, rats assume a defensive-like, immobile posture (DIP) of approximately 2-5 s in length. The aim of the present study was to examine the effect of bilateral lesions of the nucleus locus coeruleus/subcoeruleus (LC/SC) on the DIP. Using male Sprague-Dawley rats, the DIP period in the air-puff startle was measured with a digital stop watch. The DIP period was defined as the time between the application of the air-puff stimuli and the first motion after the startle reaction. For air-puff stimulation (14.4 psi in strength, 0.1 s in duration), compressed house air was presented as a transient through a vinyl tube suspended 2.5 cm above the rat's head. Two weeks before the experiment, the rats received bilateral injections of 6 microg of the neurotoxin 6-hydroxydopamine to specifically lesion noradrenaline-containing neurons of the LC/SC. In the sham-lesioned rats (n=8), the DIP period did not significantly alter compared with that before operation. In contrast, in the LC/SC-lesioned rats (n=9), the DIP period significantly reduced to 78% of the values before lesions. The results suggest that the LC/SC is involved in the development of the DIP. We speculate that the DIP period is an attentional state and vigilance condition because LC/SC neurons have been implicated in the regulation of the attentional state and vigilance.

Perinatal AZT exposure alters the acoustic and tactile startle response to 8-OH-DPAT and apomorphine in adult rats

The present study was designed to assess the dopaminergic and serotonergic contributions of the acoustic startle response (ASR) and the tactile startle response (TSR) in adult rats that had been perinatally exposed to AZT (azidothymidine, zidovudine; an antiretroviral agent). Each dam was randomly assigned to a treatment group: non-treated, AZT0, 100 or 150 mg/kg. Once daily gastric intubation began prenatally on gestational day (G) 19 and continued to G22 and then the pups were intubated between postnatal day (PND) 2-20. On PND60, animals were tested for responses to both acoustic and tactile stimuli following a challenge of vehicle, 0.25 or 0.5 mg/kg 8-OH-DPAT, a 5-HT(1A) agonist, or 0.75 or 2.0 mg/kg apomorphine (APO, a dopaminergic agonist) IP. Both DPAT and APO increased startle magnitude as expected. Additionally, perinatal AZT exposure enhanced startle responses following both DPAT and APO, an effect not due to perinatal handling or intubation. Similarly, perinatal AZT increased tactile responses following drug challenge in a gender-specific manner. Perinatal AZT also prolonged startle latencies, a change which may indicate that perinatal AZT alters conduction velocity. Therefore, the administration of AZT during the perinatal period results in long-term functional alterations within the startle reflex pathways.

Acoustic characteristics of air puff-induced 22-kHz alarm calls in direct recordings

Alarm calls were induced in adult Wistar rats by an air puff. Emitted calls were digitized and directly recorded on a computer hard drive. The long-duration 22-kHz calls were emitted almost exclusively in series. Initial calls in the series tended to have the longest durations, higher frequency range, and the highest degree of frequency modulation, as compared to other calls. The frequency modulation always appeared as a downward sweep and seemed to represent a tuning of individual calls to a 3 kHz communicatory band. Regardless of the maximum frequency, rats always reached approximately the same minimum frequency, common to all calls. Thus, the broader was the frequency range of a given call, the longer the call duration. It is postulated, therefore, that rats emit 22-kHz calls at the minimum possible ultrasonic frequency they are able to produce, which is synonymous with peak frequency. It is further postulated that production of alarm calls in series, with long call duration and the invariably low ultrasonic frequency, maximizes successful communication in dangerous situations. Exceptions to this rule were observed immediately following air puffs, suggesting that acoustic parameters of the initial calls may differ from the alarming properties of the remaining 22-kHz calls.

Glutamate and GABAB transmissions in lateral amygdala are involved in startle-like electromyographic (EMG) potentiation caused by activation of auditory thalamus

The lateral amygdala nucleus (LA) receives auditory inputs from both the auditory thalamus (medial geniculate nucleus, MGN) and auditory association cortex (AAC). These auditory inputs are closely linked with glutamate and GABA(B) receptors in the LA. The LA has intra-amygdaloid connections with the central amygdala nucleus, which mediates auditory fear potentiation of startle (AFPS) via pathways to the startle circuits. The purpose of the present study was to establish an electromyographic (EMG) model for studying AFPS-related neural transmissions in the LA. Hind-limb startle-like EMG responses to single-pulse electrical stimulation of the trigeminal nucleus (TN) were recorded in anesthetized rats. These EMG responses were enhanced by single-pulse sub-threshold electrical stimulation of the MGN when the MGN stimulus led the TN stimulus at short inter-stimulus intervals (ISI). However, the EMG responses were not affected by single-pulse sub-threshold electrical stimulation of the AAC. Bilateral injection of the glutamate antagonist, kynurenic acid, into the LA decreased both the EMG enhancement caused by MGN stimulation at short ISIs and EMG responses to combined TN and AAC stimulation across various ISIs. Moreover, bilateral injection of the GABA(B) antagonist, phaclofen, into the LA increased both EMG responses to combined TN and MGN stimulation across various ISIs, and EMG responses to combined TN and AAC stimulation at short ISIs. These results suggest that the auditory inputs to the LA from the MGN and those from the AAC are affected differently by glutamate and GABA(B) receptors in the LA, and play differential roles in modulating startle responses.

Habituation of the acoustic and the tactile startle responses in mice: two independent sensory processes

To test whether habituation is specific to the stimulus modality, the authors analyzed cross-habituation between the tactile startle response' (TSR) and the acoustic startle response (ASR). The acoustic artifacts of airpuffs used to elicit the TSR were reduced by using a silencer and were effectively masked by background noise of 90-100 dB sound-pressure level. ASR was elicited by 14-kHz tones. TSR and ASR habituated in DBA and BALB mice: both the TSR and ASR habituated to a greater extent in DBA mice than in BALB mice. In both strains, habituation of the TSR did not generalize to the ASR, and vice versa. From this, the authors concluded that habituation of startle is located in the sensory afferent branches of the pathway.

Kynurenate in the pontine reticular formation inhibits acoustic and trigeminal nucleus-evoked startle, but not vestibular nucleus-evoked startle

The startle reflex is elicited by acoustic, trigeminal or vestibular stimulation, or by combinations of these stimuli. Acoustic startle is mediated largely by ibotenate-sensitive neurons in the ventrocaudal pontine reticular formation (PnC). In these studies we tested whether startle elicited by stimulation of different modalities is affected by infusion of the non-selective glutamate antagonist, kynurenate, into the PnC. In awake rats, startle responses evoked by either acoustic or spinal trigeminal nucleus stimulation were inhibited by kynurenate, but not saline, infusions, with the most effective placements nearest PnC. In chloral hydrate-anesthetized rats, kynurenate in the PnC reduced trigeminal nucleus-evoked hindlimb EMG responses, but not vestibular nucleus-evoked startle. Kynurenate in the vestibular nucleus had no effect on trigeminal nucleus-evoked startle. These results indicate that trigeminal nucleus stimulation evokes startle largely through glutamate receptors in the PnC, similarly to acoustic startle, but vestibular nucleus-evoked startle is mediated through other pathways, such as the vestibulospinal tract.

Defensive movements evoked by air puff in monkeys

Electrical stimulation of two connected cortical areas in the monkey brain, the ventral intraparietal area (VIP) in the intraparietal sulcus and the polysensory zone (PZ) in the precentral gyrus, evokes a specific set of movements. In one interpretation, these movements correspond to those typically used to defend the body from objects that are near, approaching, or touching the skin. The present study examined the movements evoked by a puff of air aimed at various locations on the face and body of fascicularis monkeys to compare them to the movements evoked by stimulation of VIP and PZ. The air-puff-evoked movements included a movement of the eyes from any initial position toward a central region and a variety of stereotyped facial, shoulder, head, and arm movements. These movements were similar to those reported on stimulation of VIP and PZ. One difference between the air-puff-evoked movements and those evoked by stimulation of VIP and PZ is that the air puff evoked an initial startle response (a bilaterally symmetric spike in muscle activity) followed by a more sustained, lateralized response, specific to the site of the air puff. In contrast, stimulation of VIP and PZ evoked mainly a sustained, lateralized response, specific to the site of the receptive fields of the stimulated neurons. We speculate that VIP and PZ may contribute to the control of defensive movements, but that they may emphasize the more spatially specific reactions that occur after startle.

Differences between SHR and WKY following the airpuff startle stimulus in the number of Fos expressing, RVLM projecting neurons

The neurocircuitry responsible for excessive stress-induced cardiovascular responses in genetic hypertensive rats remains elusive. Prior studies detailed a differential cardiovascular response profile to airpuff startle stimuli between Spontaneously Hypertensive (SHR) and Wistar Kyoto (WKY) rats. We recently identified strain differential Fos expression in the rostroventrolateral medulla (RVLM) and several RVLM projecting sites following airpuff startle. The current study sought to define RVLM projecting neurons that also express Fos following placement in the test chamber and administration of the airpuff startle stimulus. Unilateral iontophoretic micro-injections of fluorogold were made into the RVLM of 9-10 week old SHR and WKY rats. Two to three weeks later, animals were subjected to a series of 60 airpuff startle stimuli. Brains were double labeled for Fos and fluorogold. Single fluorogold and single Fos cells, and double labeled cells were found in the nucleus tractus solitarius (NTS), caudal ventral lateral medulla (CVLM), Kölliker fuse (KF), ventral lateral, lateral, and dorsal central gray, lateral hypothalamus (LH), and paraventricular nucleus of the hypothalamus (PVN). These data are consistent with the notion that the RVLM receives differential excitatory and/or inhibitory input from higher brain centers, perhaps contributing to differential Fos expression in the RVLM, differential autonomic responding, or both.

Contributions of the vestibular nucleus and vestibulospinal tract to the startle reflex

The startle reflex is elicited by strong and sudden acoustic, vestibular or trigeminal stimuli. The caudal pontine reticular nucleus, which mediates acoustic startle via the reticulospinal tract, receives further anatomical connections from vestibular and trigeminal nuclei, and can be activated by vestibular and tactile stimuli, suggesting that this pontine reticular structure could mediate vestibular and trigeminal startle. The vestibular nucleus, however, also projects to the spinal cord directly via the vestibulospinal tracts, and therefore may mediate vestibular startle via additional faster routes without a synaptic relay in the hindbrain. In the present study, the timing properties of the vestibular efferent pathways mediating startle-like responses were examined in rats using electrical stimulation techniques. Transient single- or twin-pulse electrical stimulation of the vestibular nucleus evoked bilateral, startle-like responses with short refractory periods. In chloral hydrate-anesthetized rats, hindlimb electromyogram latencies recorded from the anterior biceps femoris muscle were shorter than those for stimulation of the trigeminal nucleus, and similar to those for stimulation of the caudal pontine reticular nucleus or ventromedial medulla. In awake rats, combining vestibular nucleus stimulation with either acoustic stimulation or trigeminal nucleus stimulation enhanced the whole-body startle-like responses and led to strong cross-modal summation without collision effects. In both chloral hydrate-anesthetized and awake rats, combining vestibular nucleus stimulation with ventromedial medulla stimulation produced a symmetrical collision effect, i.e. a loss of summation at the same positive and negative stimulus intervals, indicating a continuous connection between the vestibular nucleus and ventromedial medulla in mediating vestibular startle. By contrast, combining trigeminal nucleus stimulation with ventromedial medulla stimulation resulted in an asymmetric collision effect when the trigeminal nucleus stimulation preceded ventromedial medulla stimulation by 0.5 ms, suggesting that a monosynaptic connection between the trigeminal nucleus and ventromedial medulla mediates trigeminal startle. We propose that the vestibulospinal tracts participate strongly in mediating startle produced by activation of the vestibular nucleus. The convergence of the vestibulospinal tracts with the reticulospinal tract within the spinal cord therefore provides the neural basis of cross-modal summation of startling stimuli.

Prepulse startle deficit in the Brown Norway rat: a potential genetic model

Prepulse inhibition (PPI), an operational measure of sensorimotor gating, is deficient in schizophrenia patients. PPI was compared among 4 strains of rats: Sprague-Dawley, Spontaneously Hypertensive, Wistar Kyoto (WKY), and Brown Norway (BN). PPI was dramatically lower in BN versus the other strains, especially WKY, for both acoustic and airpuff startle stimuli, whereas startle amplitude was similar between BN and WKY. Female BN also had lower PPI than did female WKY. Response to increasing prepulse intensities showed a right shift in the BN relative to the WKY. Visual prepulses also showed deficiencies in BN versus WKY. The absence of background noise did not negate strain differences. Auditory brainstem response to clicks and tone pips revealed no differences in auditory threshold between the 2 strains. These results are the first to demonstrate that BN have impaired sensorimotor gating compared with WKY, without impaired acoustic acuity.

Airpuff startle stress elicited fos expression in brain cardiovascular areas of young SHR and WKY rats

Prior studies comparing Fos expression in adult Wistar Kyoto (WKY) and Spontaneously Hypertensive rats (SHR) identified more Fos-positive neurons in a subset of brain regions following two stressors: placement in a startle chamber and presentation of an airpuff startle stimulus. The present study assessed Fos expression in five week old SHR and WKY rats in those same brain areas. Like adults, young SHR expressed more Fos-positive neurons than WKY in response to the startle chamber alone. Unlike adults, in the SHR only the locus coeruleus showed a increases in Fos expression following addition of the airpuff. Otherwise, startle chamber and airpuff startle treatments induced roughly equivalent Fos expression in the SHR, possibly reflecting a ceiling effect. Young WKY exhibited predominant airpuff-induced elevations. The present results demonstrate that certain brain regions are strain-differentially activated by stressors prior to overt hypertension and that differential Fos expression is an early developmental feature of these strains.

Cochlear and trigeminal systems contributing to the startle reflex in rats

The startle reflex is evoked by strong acoustic or tactile stimuli, or by electrical stimulation of acoustic or tactile pathways. To dissociate the contributions of acoustic and tactile pathways, stimulating electrodes were placed in adjacent cochlear and trigeminal nuclei. The currents needed to evoke startle-like responses were an order of magnitude lower in ventral trigeminal sites (12-80 microA for a 0.1-ms pulse) than in cochlear nucleus sites (150-800 microA). At low threshold sites in both areas, brief acoustic stimuli were followed 0-4 ms later by a single electrical pulse and the current required to evoke startle was measured at several interstimulus intervals. Summation between the acoustic and electrical stimuli for startle was strong in both cochlear and trigeminal sites. Collision effects were found in the anteroventral cochlear nucleus when the electrical stimulus followed the ipsilateral acoustic stimulus by 2.0 ms, suggesting that acoustic startle is mediated by axons in the anteroventral cochlear nucleus. Collision effects were found at 4.0 ms if the electrical stimulus was presented in the contralateral pontine reticular formation, suggesting that acoustic signals mediating startle mainly cross to the pontine reticular formation. Collision effects were not found in medial or posterior sites in the cochlear nucleus, or trigeminal sites, suggesting that the neurons that mediate startle in these sites do not mediate acoustic startle. Therefore, acoustic startle is mediated through high threshold cochlear nucleus sites, while low threshold sites are non-acoustic, probably as a result of trigeminal or vestibular stimulation.

Summation between acoustic and trigeminal stimuli evoking startle

Electrical stimulation of the spinal trigeminal pathway evokes a short-latency startle-like response in rats. To explore the relationship between acoustic and tactile systems mediating startle, we studied temporal summation between pairs of startle-evoking stimuli in awake rats by varying the interstimulus interval. The stimuli were: (i) two noise bursts; (ii) two unilateral electrical stimuli near the principal nucleus of the trigeminal nerve; (iii) electrical stimulation of the left and right trigeminal nucleus; or (iv) a noise burst and unilateral stimulation of the trigeminal nucleus. Following two noise bursts, the amplitude of startle increased as the interval increased from 0 to 4 ms, then declined smoothly as the interval increased to 15 ms. Unilateral stimulation of the trigeminal nucleus resulted in a sharper summation effect, with maximal summation at 2 ms, and refractory periods estimated at 0.4-0.8 ms. Bilateral stimulation of the trigeminal nucleus resulted in broader summation without a refractory period, and maximal summation when the stimuli on both sides of the trigeminal nucleus were presented simultaneously. The combination of acoustic and trigeminal stimulation was most effective in enhancing startle amplitudes, and summation peaked when the noise burst preceded the trigeminal stimulation by 5 ms. Similarly, electromyogram latencies measured in the hindlimb were 3-4 ms shorter for trigeminal stimulation than for the noise burst. Startle appears to be optimally activated by simultaneous acoustic and tactile stimuli, as occurs during head blows.

Strain differences in Fos expression following airpuff startle in Spontaneously Hypertensive and Wistar Kyoto rats

The airpuff startle stimulus elicits both a behavioral and a concurrent sympathetic and parasympathetic activation, which have been shown to differ between inbred normotensive Wistar Kyoto and Spontaneously Hypertensive rat strains. Neither the brain sites responsible for the cardiovascular and motor responses, nor the origins of the strain differential responses, have yet been elucidated. The goals of the present study were (i) to define the neuronal pattern of immunoreactive Fos expression to the airpuff stimulus, and (ii) to determine whether this pattern of expression differed between the two contrasting inbred rat strains, thereby relating to observed differences in response. The airpuff stimulus induced Fos protein expression in discrete nuclei within the hypothalamus, thalamus, midbrain, pons and medulla of both strains, with strain-dependent differences evident in the hypothalamus (lateral, ventromedial and dorsomedial), pons (locus coeruleus) and medulla (rostroventrolateral medulla and solitary tract nuclei). To remove Fos expression arising from test chamber novelty, which was observed in both strains, a subset of animals was habituated to the test chamber for four days prior to testing. Habituation reduced Fos expression in several brain regions in the Wistar Kyoto, but failed to do so in the Spontaneously Hypertensive rat. The present results are the first to identify a set of brain regions likely to be responsible for the mediation of the cardiovascular and motor responses associated with the airpuff startle stimulus. Several of the identified areas contain neurotransmitters implicated by prior pharmacological studies. Further, these data identify differences in the degree of activation of specific neuronal structures that probably underlie strain differences in the cardiovascular response to the airpuff. Additionally, the results provide a cellular correlate to reported deficits in behavioral habituation by the Spontaneously Hypertensive rat and suggest a potentially profound difference between the ability of these two strains to adapt to repeated mild stress stimuli.

Aging effects on the startle response and startle plasticity in Fischer F344 rats

The effects of aging on acoustic and airpuff startle reactivity, acoustic and airpuff startle habituation, acoustic and cross-modal (light-acoustic) prepulse inhibition (PPI), and fear-potentiated startle (FPS) were examined using 3- (Y: young), 11- (AD: adult), 17- (MA: middle-aged), and 22- (O: old) month-old Fischer F344 rats. AD rats had the highest acoustic startle reactivity with the Y and MA rats showing smaller and comparable startle levels. The O rats had diminished startle reactivity, with over a 65% reduction in responding. Airpuff startle reactivity was comparable in the Y and AD groups, while the MA and O groups had 40% and 80% reductions in airpuff startle respectively. There was an age-related increase in airpuff startle habituation. Acoustic and cross-modal PPI were reduced significantly in O rats when compared to other age groups. Finally, there were no effects of age on FPS. In summary, these studies suggest that in Fischer F344 rats, there are age-associated differences in startle reactivity, startle habituation, and PPI, but no aging effect on FPS.

Attenuation of Fos expression to airpuff startle stimuli following tympanic membrane rupture

The airpuff startle stimulus consists of two modalities, tactile and acoustic. Tympanic membrane rupture (TMR) effectively deafens a rat, thus preventing it from perceiving the acoustic component of the airpuff and permitting study of the tactile component in isolation. Previous studies have shown that the tactile modality is sufficient to drive the cardiovascular response to the airpuff, but cannot elicit the full behavioral startle response. In the present study Fos protein was used as a marker of neuronal activation to identify brain regions activated by the airpuff in both intact and TMR rats. Results show an attenuation of Fos expression following TMR in the dorsal and ventral cochlear nuclei, ventral nucleus of the lateral lemniscus and medial geniculate nucleus. In contrast, Fos expression following TMR was unchanged in the locus coeruleus, the laterodorsal tegmental nucleus, the supramammilary nucleus, and the ventromedial hypothalamic nucleus. Analysis of behavioral data confirmed that the startle response to the airpuff was diminished following TMR. These data are the first of which we know to employ an immediate early gene approach to discriminate between brain regions activated by the tactile and acoustic startle stimulus modalities. The results are discussed in terms of the classical acoustic startle circuit, and the central autonomic pathways activated by the tactile component of the airpuff.

Affective modulation of tactile startle

Two studies were conducted to investigate affective modulation of startle responses to unilateral tactile probes and to determine whether such modulation is lateralized. Right-handed undergraduates received airpuffs to the left or right temple while viewing pleasant, neutral, and unpleasant pictures. Side of probe presentation was varied between the two trial blocks of the experiment in Study 1 (n = 48) but varied randomly within trial blocks in Study 2 (n = 48). Primary results were consistent across studies. Replicating and extending the findings for acoustic probes, eyeblink responses to tactile probes were larger during unpleasant than during pleasant pictures. However, affective modulation of startle did not differ reliably between the two sides of probe presentation (sensory laterality) or the two sides of the response (motor laterality) in either study or in a combined analysis.

Habituation of airpuff-elicited cardiovascular responses in the spontaneously hypertensive rat

Repeated delivery of fast rise-time acoustic stimuli elicit cardiac changes in humans that reflect startle, orienting, and defense responses. To test the hypothesis that fast rise-time stimuli produce these responses in the rat, we evaluated magnitude, latency, and habituation of cardiovascular responses to brief airpuff stimuli in normotensive rats. We also evaluated airpuff-elicited cardiovascular responses in spontaneously hypertensive rats. In addition to a robust increase in blood pressure, airpuffs produced one or more of three sequential heart-rate responses in normotensive rats--first, short-latency tachycardia (latency ).8 s), then rapidly habituating bradycardia (latency 2.2 s), then long-latency tachycardia (latency 3.5 s)--which likely reflected startle, orienting, and defense responses, respectively. Airpuffs rarely produced bradycardia in hypertensive rats, suggesting that this strain does not appropriately orient to sensory stimuli. In addition, compared to normotensive rats, hypertensive rats exhibited greater between-session habituation of long-latency tachycardia and blood pressure increases. This finding contrasts with the Folkow hypothesis, which assumes that, in subjects with a genetic predisposition to develop hypertension, sympathetic responses will remain exaggerated after repeated stimulation, thus contributing to thickening of the arterial vasculature.

Reduced sensorimotor reactivity following traumatic brain injury in rats

The present study examined sensorimotor reactivity in rats following traumatic brain injury (TBI). Moderate injury was induced with midline fluid percussion in some of the rats. Others received identical surgery, but were not injured (sham-injured rats), or received neither surgery nor injury (naive rats). All rats were evaluated in acoustic and/or tactile startle procedures. At 8 days post-injury, the sensorimotor reactivity of TBI rats to acoustic stimuli was severely reduced compared to that of sham-injured rats. This TBI-induced deficit was enduring (> 30 days). In a separate experiment, greater sensorimotor reactivity was observed with tactile (vs. acoustic) stimulation in both TBI and naive rats although startle amplitudes for the TBI rats were lower than control levels for both types of stimuli. These results suggest that sensorimotor reactivity is altered by TBI and that the startle procedure is a promising method for investigation of information processing alterations following TBI.

Developmental and pharmacological analysis of the cardiac response to an acoustic startle stimulus

The purpose of this research was to study the cardiac response of preweanling and adult rats to 10 presentations of an acoustic startle stimulus (0 ms rise time, 100 ms, 130 dB, white noise stimulus). The first presentation of the startle stimulus produced a decrease in heart rate (HR) at both ages. With continued stimulus presentations, the response shifted to tachycardia in the adults but remained bradycardia in the preweanlings. Pharmacological analysis revealed that the startle stimulus activated only the parasympathetic system in the preweanling rats on all 10 trials. In contrast, the startle stimulus produced coactivation of the parasympathetic and sympathetic systems in the adults on the first trial, with the parasympathetic system predominating, and solely sympathetic activation on later trials. These results are discussed in terms of current psychophysiological models of (a) the cardiac response to startle stimuli and (b) autonomic space.

The acoustic startle reflex: neurons and connections

The startle reflex protects animals from blows or predatory attacks by quickly stiffening the limbs, body wall and dorsal neck in the brief time period before directed evasive or defensive action can be performed. The acoustic startle reflex in rats and cats is mediated primarily by a small cluster of giant neurons in the ventrocaudal part of the nucleus reticularis pontis caudalis (RPC) of the reticular formation. Activation of these RPC neurons occurs 3-8 ms after the acoustic stimulus reaches the ear. Undetermined neurons of the cochlear nuclei activate RPC via weak monosynaptic and strong disynaptic connections. The strong disynaptic input occurs via neurons of the contralateral ventrolateral pons, including large neurons of the ventrolateral tegmental nucleus that integrate auditory, tactile and vestibular information. RPC giant neurons, in turn, activate hundreds of motoneurons in the brain stem and the length of the spinal cord via large reticulospinal axons near the medial longitudinal fasciculus. To hindlimb motoneurons, monosynaptic connections from the reticulospinal tract are weak, but disynaptic connections via spinal cord interneurons are stronger and show temporal facilitation, like the startle response itself.

Modification of acoustic and tactile startle by single microwave pulses

Single microwave pulses at 1.25 GHz were delivered to the head and neck of male Long-Evans rats as a prestimulus to acoustic and tactile startle. For acoustic startle, pulses averaging 0.96 microsecond in duration were tested with two specific absorption rate (specific absorption) ranges, 15.0-30.0 kW/kg (16.0-44.2 mJ/kg) and 35.5-86.0 kW/kg (66.6-141.8 mJ/kg), delivered 201, 101, 51, 3, and 1 ms before and 1 ms after onset of a startling noise. The low-intensity pulse did not affect peak amplitude, integral, or latency of the whole-body startle response. The high-intensity pulse at 101 and 51 ms inhibited the startle response by decreasing peak amplitude and integral; at 201 and 51 ms latency was increased. The high-intensity pulse at 1 ms enhanced the startle response by increasing peak amplitude and at 3 ms by increasing integral. For tactile startle, either microwave pulses averaging 7.82 microseconds in duration and 55.9-113.3 kW/kg (525.0-1055.7 mJ/kg) or 94 dB SPL clicks were delivered 157, 107, 57, and 7 ms before and 43 ms after onset of a startling air burst. The microwave pulse at 57 ms inhibited the startle response by decreasing peak amplitude; at 157, 107, 57, and 7 ms it increased latency. The microwave pulse at 43 ms after onset enhanced the startle response by increasing peak amplitude. The acoustic click at 157 and 57 ms inhibited the startle response by decreasing peak amplitude; at 157,2 107, and 57 ms it increased latency.(ABSTRACT TRUNCATED AT 250 WORDS)