Role of the Hippocampus, the Bed Nucleus of the Stria Terminalis, and the Amygdala in the Excitatory Effect of Corticotropin-Releasing Hormone on the Acoustic Startle Reflex

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Volume 17, Number 16, Issue of August 15, 1997 pp. 6434-6446
Copyright ©1997 Society for Neuroscience

Role of the Hippocampus, the Bed Nucleus of the Stria Terminalis, and the Amygdala in the Excitatory Effect of Corticotropin-Releasing Hormone on the Acoustic Startle Reflex

Younglim Lee and Michael Davis
Department of Psychiatry, Yale University, New Haven, Connecticut 06508

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Previously, we demonstrated that transection of the fimbria/fornix blocked the excitatory effect of corticotropin-releasinghormone (CRH) on startle (CRH-enhanced startle), suggesting thatthe hippocampus and its efferent target areas that communicatevia the fimbria may be critically involved in CRH-enhanced startle.The bed nucleus of the stria terminalis (BNST) receives directprojections from the ventral hippocampus via the fimbria/fornix.Therefore, the role of the ventral hippocampus, the BNST, andthe amygdala in CRH-enhanced startle was investigated. NMDA lesionsof the BNST completely blocked CRH-enhanced startle, whereas chemicallesions of the ventral hippocampus and the amygdala failed toblock CRH-enhanced startle. However, the same amygdala-lesionedanimals showed a complete blockade of fear-potentiated startle,a conditioned fear response sensitive to manipulations of theamygdala. In contrast, BNST-lesioned rats had normal fear-potentiatedstartle. This indicates a double dissociation between the BNSTand the amygdala in two different paradigms that enhance startleamplitude. Microinfusions of CRH into the BNST, but not into theventral hippocampus, mimicked intracerebroventricular CRH effects.Furthermore, infusion of a CRH antagonist into the BNST blockedCRH-enhanced startle in a dose-dependent manner. Control studiesshowed that this blockade did not result from either leakage ofthe antagonist into the ventricular system or a local anestheticeffect caused by infusion of the antagonist into the BNST. Thepresent studies strongly suggest that CRH in the CSF can activatethe BNST, which could lead to activation of brainstem and hypothalamicBNST target areas involved in anxiety and stress responses.
Key words: bed nucleus of the stria terminalis (BNST); amygdala; hippocampus; corticotropin-releasing hormone (CRH); startle; anxiety; fear

INTRODUCTION

Intracerebroventricular infusion of corticotropin-releasing hormone (CRH) elicits a constellation of behavioral, physiological,and endocrinological changes similar to those produced by naturalstressors (cf. Dunn and Berridge, 1990). Thus far, however, theexact anatomical sites responsible for these behavioral and physiologicalactions of CRH after intracerebroventricular administration havenot been identified. As part of an effort to delineate the neuralcircuitry underlying intracerebroventricular CRH effects, recentlywe investigated a possible involvement of the septum, using increasedacoustic startle amplitude after CRH (CRH-enhanced startle) asa behavioral measure (Lee and Davis, 1997). Electrolytic lesionsof the whole septum and the medial septum, but not the lateralseptum, blocked CRH-enhanced startle. However, fiber-sparing chemicallesions of the medial septum failed to block CRH-enhanced startle,suggesting that the blockade seen with electrolytic lesions wasprobably caused by damage to fibers of passage, presumably thefornix. Supporting this conclusion, functional lesions of thefornix induced by knife cuts of the fimbria/fornix completelyblocked CRH-enhanced startle.

The fimbria/fornix is the main output pathway for the hippocampus (cf. Amaral and Witter, 1995). Therefore, the blockade ofCRH-enhanced startle by transection of the fimbria/fornix suggeststhat the hippocampus might be critically involved in CRH-enhancedstartle. Among its subdivisions, however, the dorsal hippocampusseems not to be involved, because electrolytic lesions of thisarea did not block CRH-enhanced startle (Lee and Davis, 1997).A possible involvement of the ventral hippocampus in CRH-enhancedstartle has not been investigated. Interestingly, the ventralhippocampus projects to the bed nucleus of the stria terminalis(BNST) via the fimbria/fornix (cf. Canteras and Swanson, 1992;Cullinan et al., 1993; Amaral and Witter, 1995). Furthermore,both the ventral hippocampus and the BNST contain a moderate amountof CRH receptors (De Souza et al., 1984; Chalmers et al., 1995;Sawchenko and Swanson, 1985). Therefore, it is conceivable thatCRH given intracerebroventricularly primarily binds to the ventralhippocampus and modulates startle amplitude via hippocampal-BNSTconnections. Alternatively, both the ventral hippocampus and theBNST may be the primary receptor sites for CRH given intracerebroventricularly.

The amygdala complex also has been implicated in CRH-enhanced startle. Liang and colleagues (1992) reported that electrolyticlesions of the amygdala blocked CRH-enhanced startle, whereasCRH infused into the amygdala failed to mimic intracerebroventricularCRH effects on startle. Because the amygdala has direct projectionsto the nucleus reticularis pontis caudalis (Hitchcock and Davis,1991), a part of the primary acoustic startle circuit (Davis etal., 1982; Lee et al., 1996), these data suggest that the amygdalamay play an obligatory role in CRH-enhanced startle, even thoughit is not the primary receptor site for CRH given intracerebroventricularly.In other words, CRH given intracerebroventricularly may bind toreceptors in structures afferent to the amygdala, such as theBNST or hippocampus, thereby exciting the amygdala indirectly.In turn this would lead to an increase in startle amplitude viathe direct connections between the amygdala and the nucleus reticularispontis caudalis.

In the present series of studies we attempted to determine the location of the primary receptor site(s) for intracerebroventricularCRH using the CRH-enhanced startle paradigm. Three criteria wereconsidered to be necessary for a given structure x to be identifiedas a primary receptor site for CRH given intracerebroventricularly.First, chemical lesions of structure x should block intracerebroventricularCRH effects. Second, CRH infused directly into structure x shouldmimic intracerebroventricular CRH effects. Third, a CRH antagonistinfused directly into structure x should antagonize effects ofCRH given intracerebroventricularly. Based on these three criteria,the present studies examined the role of the BNST, ventral hippocampus,and amygdala complex in CRH-enhanced startle.

MATERIALS AND METHODS
Animals Male Sprague Dawley rats (Charles River, Kingston, NY) weighing 350-450 gm were used. The animals were housed in groups ofthree before surgery in 20 × 24 × 36 cm hanging wire cages andwere housed singly in 19 × 20 × 25 cm wire cages after surgery.The animal colony was on a 12 hr light/dark schedule (lights onat 7 A.M.) with food and water continuously available.
Startle apparatus The startle apparatus is been described in detail in the accompanying article (Lee and Davis, 1997). Briefly, five separatestabilimeters consisting of an 8 × 15 × 15 cm Plexiglas and wiremesh cage suspended between compression springs within a steelframe were used. Cage movement resulted in displacement of anaccelerometer where the resultant voltage was proportional tothe velocity of cage displacement. Startle amplitude was definedas the peak accelerometer voltage that occurred during the first200 msec after onset of the startle stimulus.

The startle stimuli were delivered by high-frequency Radio Shack super tweeters located 10 cm behind each stabilimeter. Startlestimuli were 50 msec bursts of white noise at various intensities.Throughout all experiments, background white noise was 55 dB.

Presurgery matching. Three to 4 weeks after delivery, the animals were placed in the startle test cages and given a presurgerymatching test consisting of a 5 min acclimation period followedby 60 startle eliciting noise bursts at 105 dB, at a 30 sec intertrialinterval (ITI). The animals were subsequently divided into shamor lesion groups, having similar mean startle amplitudes acrossthe last 10 startle stimuli.
Surgery NMDA lesions of the BNST, ventral hippocampus, and basolateral nucleus of the amygdala and ibotenic acid lesions of the centralnucleus of the amygdala. The lesions were made by infusing 200nl of NMDA (20 mg/ml) into the BNST or the ventral hippocampusover 4 min. The coordinates relative to bregma were $-$ 0.2 mm anteroposterior(AP), ±1.7 mm mediolateral (ML) and $-$ 6.8 mm dorsoventral (DV)for the BNST (n = 20), and $-$ 4.8 mm AP, ±5.0 mm ML, and $-$ 8.0 mmDV for the ventral hippocampus (n = 40). For lesions of the basolateralnucleus of the amygdala (BLA; n = 15), NMDA was infused in twodifferent locations, using the following coordinates relativeto bregma: $-$ 2.7 mm AP, ±5.2 mm ML, and $-$ 8.6 mm DV (200 nl/4 min)and $-$ 2.7 mm AP, ±5.2 mm ML, and $-$ 8.3 mm DV (100 nl/2 min). Lesionsof the central nucleus of the amygdala (CeA) were made using ibotenicacid (Research Biochemicals, Natick, MA), because a pilot studyshowed that ibotenic acid was more effective than NMDA in lesioningthe CeA without much damage to the BLA. One hundred fifty nanolitersof the ibotenic acid solution (15 mg/ml in 0.1 M PBS, pH 7.4)was infused over 3 min at the following coordinates relative tobregma: $-$ 2.2 mm AP, ±4.3 mm ML, and $-$ 8.6 mm DV (n = 15). For thecontrol animals (n = 15), an equivalent amount of phosphate bufferwas infused into the ventral hippocampus, amygdala, or BNST (n= 5 in each case), using the procedures described above.

Intra-BNST and intraventral hippocampus cannula implantation. The BNST was cannulated bilaterally using the following coordinateswith respect to bregma: $-$ 0.5 mm AP, ±1.5 mm ML, and $-$ 7.8 mm DV(n = 10). Cannulation of the ventral hippocampus was also bilateral,and the coordinates with respect to bregma were $-$ 4.8 mm AP, ±5.0mm ML, and $-$ 8.0 mm DV (n = 15).

Intra-BNST, lateral ventricle, or intra-CeA cannulation combined with intracisternal cannulation. In different animals, theBNST, lateral ventricles, or CeA were cannulated bilaterally withconcomitant intracisternal cannulation. The coordinates with respectto bregma were $-$ 2.3 mm AP, ±4.0 mm ML, and $-$ 9.0 mm DV (CeA; n= 10); $-$ 0.5 mm AP, ±1.5 mm ML, and $-$ 5.0 mm DV (lateral ventricles;n = 7); and $-$ 0.5 mm AP, ±1.5 mm ML, and $-$ 7.8 mm DV (BNST; n =10). The coordinates for intracisternal cannulation were $-$ 11.6mm AP, ±0.0 mm ML, and $-$ 7.8 mm DV.
Test procedure and drug administration Postsurgery matching. One week after surgery, the animals were tested with an identical matching procedure used for presurgerymatching. The decision regarding which animals would be infusedwith CRH on test 1 and which would be infused with artificialCSF (ACSF) was made so that the mean startle amplitudes acrossthe last 10 trials in the postmatching test were equivalent inthe CRH and vehicle groups in a given test day.

Intracerebroventricular CRH test. The effect of intracerebroventricular CRH on startle was tested 1 d after postsurgery matching.The animals were given a predrug baseline test, which was identicalto the matching test. Immediately after the test, the animalswere removed from the cage, and half were infused with CRH (1µg/5 µl over 2 min; human/rat CRH, Peninsula Laboratory), whereasthe other half were infused with the vehicle ACSF (5 µl/2 min).After intracerebroventricular infusion, the animals were placedback in the startle chambers and presented with 240 startle-elicitingnoise bursts at a 30 sec ITI (post-drug test). Forty-eight hourslater, the animals were tested again using a crossover designin which the animals infused with CRH on test 1 were infused withACSF on test 2 and vice versa.

Intra-BNST and intraventral hippocampus infusion of CRH. The general protocol for testing the effects of CRH directly infusedinto the BNST and the ventral hippocampus on startle was similarto that used in testing the effects of intracerebroventricularCRH on startle. Immediately after the predrug baseline test, theanimals were removed from the cage and infused bilaterally withone of four doses of CRH into the BNST [0 (ACSF), 40, 80, or 160ng/0.6 µl total] over 3 min. Subsequently, the animals were placedback into the startle chambers and given a postdrug test as describedabove. The test was 2 hr long, consisting of 240 startle trials.This rather long test session was chosen, because a pilot studyshowed that the excitatory effect of CRH on startle after intra-BNSTinfusion lasted as long as the intracerebroventricular CRH effecton startle. All animals were tested four times with each of theCRH doses. Each test was 48 hr apart, and the injection orderwas based on a Latin square design. For intraventral hippocampusinfusions of CRH, infusion and testing procedures were identicalto those of the intra-BNST study, except three rather than fourdoses of CRH (0, 40, and 80 ng/0.3 µl) were used.

Intracisternal CRH in combination with intra-BNST infusion of $alpha$ -helical CRH_9-41. The test procedures were similar tothose for intracerebroventricular CRH, except that various dosesof $alpha$ -helical CRH_9-41 ( $alpha$ -hCRH_9-41) [0 (ACSF), 2, 4,or 6 µg total; Peninsula Laboratory] were infused into the BNST5 min before intracisternal infusion of CRH (0.5 µg). The totalvolume infused into the BNST was 0.3 µl/side, and the infusionrate was 0.1 µl/1 min. All animals were tested four times witheach of the $alpha$ -hCRH_9-41 doses. Each test was 48 hr apart,and the injection order was based on a Latin square design. Toverify the location of cannulas in the BNST functionally, theanimals were tested with intra-BNST infusion of 160 ng of CRH48 hr after the last intra-BNST CRH antagonist test session. Again,general procedures for infusion and testing were the same as thoseused previously.

Intracisternal CRH in combination with either intracerebroventricular infusion or intra-CeA infusion of $alpha$ -hCRH_9-41.The test procedures were similar to those of the intracerebroventricularCRH test, except that either 6 µg of $alpha$ -hCRH_9-41 (total)or ACSF was infused bilaterally into the lateral ventricles orthe CeA 5 min before intracisternal infusion of CRH (0.5 µg).The total volume infused into the lateral ventricle or the CeAwas 0.3 µl/side, and the infusion rate was 0.1 µl/1 min. All animalswere tested with both $alpha$ -hCRH_9-41 and ACSF infused into thelateral ventricles over two test sessions. Each test was 48 hrapart, and the injection order was counterbalanced.

Potentiated startle training. Two days after their last CRH test, the animals received potentiated startle training. The fear-potentiatedstartle effect, which is blocked by lesions of the amygdala (Campeauand Davis 1995; Sananes and Davis, 1992), was used as a functionaltest of successful amygdala lesions in the rats previously testedwith CRH. On each of 2 consecutive days, the animals were placedin the startle chambers, and after a 5 min acclimation periodreceived 10 light-shock pairings. The conditioned stimulus wasa 3700 msec duration, 750 ft lambert light generated by an 8 Wfluorescent bulb, which was attached to the back of the individualchambers. The unconditioned stimulus, a 0.6 mA foot shock, wasgenerated by five Lehigh Valley SGS-004 constant current shockerslocated outside of the chamber. Shock intensity was measured usinga method described previously (Davis and Astrachan, 1978). Theshock was delivered during the last 500 msec of the 3700 mseclight at an average ITI of 4 min (range, 3-5 min). To obtain ameasure of how the lesions might have affected reactivity to footshocks, stabilimeter output during the 10 shocks was sampled fora 200 msec period after the onset of the shock. The mean levelof cage output across the 20 foot shocks over the 2 training dayswas computed for each animal and used as an indicator of shockreactivity. Throughout potentiated startle training, backgroundwhite noise was 55 dB. The training was performed in the dark,except during light-shock pairing trials.

Potentiated startle testing after lesions of the BNST or amygdala complex. Forty-eight hours after the last potentiated startletraining session, the animals were brought into the startle chambersand subjected to a potentiated startle test. After a 5 min acclimationperiod, 40 50-msec-long, 95 dB startle-eliciting white noise burstswere delivered. These startle noise bursts, called leaders, wereused to provide steady, habituated baseline levels of startlebefore fear-potentiated startle testing. Immediately after the40 leaders, 20 50 msec noise bursts at each of three intensities(90, 95, and 105 dB) were presented. Half of the stimuli at eachof these intensities were presented in darkness (noise alone trials),and the other half were presented 3200 msec after the onset ofthe light (3700 msec total duration; light noise trial). All startlestimuli were presented in a balanced, irregular order, and theITI was 30 sec. The tests were given in the dark, except duringlight noise trials, and throughout the test the background whitenoise was 55 dB.

Potentiated startle testing with intra-CeA $alpha$ -hCRH_9-41. The fear-potentiated startle effect, which is blocked by infusionof local anesthetics into the amygdala, was used as a functionaltest to evaluate whether $alpha$ -hCRH_9-41 might have local anestheticeffects. A day after the second fear-potentiated startle-trainingsession, the animals were brought into the startle chambers and5 min later presented with 20, 95 dB startle-eliciting white noisebursts (leaders). After the leaders, three noise alone trialsand three light noise trials were presented in a quasirandom order.All startle-eliciting noise bursts were 95 dB. This rather shorttest was given to match the animals into two subgroups havingsimilar mean potentiated startle levels but minimizing the amountof extinction. The following day, the animals were again broughtinto the startle chambers and given a fear-potentiated startletest session (PS test 1). Before the test session, however, oneof the two subgroups of animals was infused with ACSF (0.3 µl),and the remaining group was infused with $alpha$ -hCRH_9-41 (6 µgin 0.3 µl of ACSF). Infusions were made bilaterally into the CeA(3 µg/side), and the infusion rate was 0.1 µl/1 min.

Forty-eight hours later, the animals were subjected once more to a fear-potentiated startle test (PS test 2). In this case,animals that received ACSF in PS test 1 were now infused with $alpha$ -hCRH_9-41 and vice versa. In an effort to make the levelof conditioning to the light at the beginning of PS test 2 similarto that before PS test 1, the animals received a short retrainingsession (5 light-shock pairings rather than 20 pairings) 24 hrbefore PS test 2.
Histology At the completion of the studies, the animals were perfused, and their brains were removed and fixed in 30% sucrose in 10%formalin solution. Coronal sections (40 µm) were cut through therelevant brain areas, and every third section was mounted ontogelatin-coated slides. For verification of cannulation, the sectionswere stained with cresyl violet. Chemical lesions were verifiedusing the Kluver-Barrera method to assess damage to cell bodiesversus fibers of passage separately.
Data analysis A predrug startle score was computed by taking the mean of the last 10 startle amplitudes of the predrug test. For each animal,the postdrug startle test scores were blocked by 20 (12 startlescore blocks), with the mean score of each block designated asthe raw startle score. Throughout the experiments, there wereno significant differences in the baseline startle levels beforeany infusion of drugs (Table 1). Therefore, for graphic illustrationsof the effect of CRH or ACSF on startle, percent change scoreswere derived by subtracting the baseline scores from each rawstartle score after infusion. These difference scores were thendivided by the baseline scores and multiplied by 100 [(post $-$ pre)/pre × 100].

Table 1. Baseline startle levels before infusion of drugs

Pre-ACSF Pre-CRH

Chemical lesion

  Hippocampus 265 ± 29 189 ± 23

  BNST 254 ± 38 347 ± 63

  BLA 319 ± 96   333 ± 66

  CeA 269 ± 33 215 ± 40

  Sham 228 ± 49 229 ± 35

F_(4,44) = 1.81; p < 0.144

Microinfusion

  BNST

    ACSF 335 ± 48

    40 ng 226 ± 39

    80 ng 283 ± 44

    160 ng 198 ± 35

F_(3,24) = 9.72; p < 0.001

  Hippocampus

    ACSF 193 ± 52

    40 ng 235 ± 51

    80 ng 237 ± 36

F_(2,16) = 0.61; p < 0.558

Intra-BNST antagonist

  ACSF 351 ± 66

  3 µg 315 ± 98

  6 µg 475 ± 125

F_(2,12) = 3.19; p < 0.095

Intracerebroventricular antagonist

  ACSF 253 ± 100

  6 µg 165 ± 28

F_(1,6) = 0.83; p < 0.396

Intra-CeA antagonist

  ACSF 185 ± 36

  6 µg 185 ± 41

F_(1,7) = 0.28, p < 0.615

For statistical evaluations of the drug effects, predrug baseline and mean startle amplitude over the last 120 trials afterCRH infusion (last 60 min, trials 121-240) were calculated andcompared with predrug baseline and mean startle amplitudes afterACSF infusion using ANOVA. For statistical evaluation of the intra-BNSTand intraventral hippocampal CRH infusions on startle, each animal'spredrug baseline and mean startle amplitude over the last 120trials after different doses of CRH infusion were calculated andcompared using a one-way ANOVA. BNST and amygdala lesion effectson fear-potentiated startle were assessed by comparing mean startleamplitude in the absence and presence of light combined over thethree intensities of startle-eliciting noise bursts using ANOVA.Effects of the CRH antagonist on fear-potentiated startle werealso evaluated in the same way using a one-way ANOVA.

RESULTS

Effects of chemical lesions of the hippocampus, BNST, and amygdala complex on CRH-enhanced startle and fear-potentiated startle
Histological verification showed that 10 of the 20 animals had only partial lesions of the BNST, and one animal had a misplacedcannula. Thus, in total, nine animals were included in the dataanalysis. The center of our ventral hippocampal lesions was aimedat the anterior part of this area, which is known to project tothe BNST (Cullinan et al., 1993); as a result, the posterior aspectof the ventral hippocampus was consistently spared in all animals.Many of the ventral hippocampus lesioned animals showed bilateralpartial lesions (n = 14) or unilateral lesions (n = 6) and thereforewere excluded from the data analysis. An additional eight animalswho had an abnormally low baseline startle amplitude (<70 units;n = 5) and intracerebroventricular cannula misplacements (n =3) were also excluded. Among the remaining 12 animals that wereincluded in the data analysis, five showed multiple holes in thelesion area, likely attributable to the severity of the lesion.Although verification of these lesions was difficult, the remainingtissue suggested that the area was clearly lesioned, so that theirdata were included. Seven animals who had complete lesions ofthe ventral hippocampus without visible damage of passing fiberswere also subjected to further data analysis. Seven of the CeA-lesionedanimals were excluded from data analysis because of either misplacementof intracerebroventricular cannulas or partial lesions or overlyextensive lesions, which encroached on the medial part of theBLA. NMDA lesions of the BLA showed consistent sparing of themost posterior part of the BLA in all animals. Eight of 15 animalsshowed further sparing of the BLA and therefore were not includedin the data analysis. Three sham-lesioned animals were not includedin the data analysis because of misplacement (n = 2) or loss (n= 1) of the cannulas. As a result, the numbers of rats used fordata analysis in each group were BNST, 9; ventral hippocampus,12; CeA, 8; BLA, 7; and sham, 12. Histological reconstructionsof the smallest and largest chemical lesions of these areas areillustrated in Figure 1C.
Fig. 1. Effects of sham lesions and chemical lesions of the bed nucleus of the stria terminalis, ventral hippocampus, and centralor basolateral nucleus of the amygdala on mean percent changeof startle amplitude after intracerebroventricular infusion of1 µg of CRH (A) or ACSF (B). Each data point represents the meanpercent change of 20 postdrug test trials. C, Smallest (left)and largest (right) lesions of these areas.
[View Larger Version of this Image (51K GIF file)]

Figure 1 shows the effects of intracerebroventricular CRH (Fig. 1A) or ACSF (Fig. 1B) on startle amplitude after chemicallesions of the four areas mentioned above. NMDA lesions of theBNST completely blocked CRH-enhanced startle, whereas ibotenicacid lesions of the CeA and NMDA lesions of the BLA or ventralhippocampus failed to do so. Supporting this conclusion, separate2 × 2 ANOVAs using drug (ACSF vs CRH) and time (predrug vs postdrug)as within-subject factors showed that the animals with sham, BLA,CeA, or ventral hippocampus lesions showed a significant drugby time interaction (sham, F_(1,11) = 34.335; p < 0.001; BLA, F_(1,6)= 8.24; p < 0.028; CeA, F_(1,7) = 6.04; p < 0.044; and ventralhippocampus, F_(1,11) = 5.32; p < 0.042), indicating that CRH increasedstartle amplitudes significantly in these animals. On the otherhand, animals with BNST lesions failed to show a significant drugby time interaction (F_(1,8) = 0.00; p < 0.968), indicating blockadeof CRH-enhanced startle after the lesions.

In a recent study, we showed that knife cuts of the fimbria/fornix blocked CRH-enhanced startle, whereas lesions of the dorsalhippocampus did not (Lee and Davis, 1997). Given the fact thatthe fimbria/fornix is the major output pathway for the hippocampalformation, the failure to block CRH-enhanced startle by eitherdorsal hippocampal (Lee and Davis, 1997) or ventral hippocampallesions (current study) is puzzling. Interestingly, although NMDAlesions of the ventral hippocampus overall failed to block CRH-enhancedstartle, further investigation of the data revealed that therewas a clear dichotomy in lesion effects among ventral hippocampal-lesionedanimals. Thus, five animals who had tissue damage in the lesionarea, indicative of severe lesions, showed unusually large increasesin startle after CRH (about a 350-400% increase compared withthe typical 150-200% increase), whereas the other seven animalsshowed a mean increase in startle amplitude of <20% after theCRH infusion. A separate ANOVA using these two subgroups as independentgroups showed a significant drug by time by group interaction(F_(1,10) = 9.51; p < 0.012), indicating a difference in the magnitudesof CRH-enhanced startle between these two subgroups (Fig. 2).Thus far, however, we have not been able to determine the criticalhistological difference between these subgroups.
Fig. 2. Mean percent change of startle amplitude after intracerebroventricular infusion of 1 µg of CRH or ACSF. The open circles showthe behavioral data of the animals that had a blockade of CRH-enhancedstartle after NMDA lesions of the ventral hippocampus [group 1(G1)], and the closed circles show the behavioral data of theanimals that had super CRH-enhanced startle after lesions [Group2 (G2)]. Notice the difference in the scale.
[View Larger Version of this Image (22K GIF file)]

A previous study showed that large electrolytic lesions of the amygdala blocked CRH-enhanced startle (Liang et al., 1992).It is possible, therefore, that the failure of chemical lesionsof either the CeA or BLA in the present study resulted from inadequatelesions. To test this, the animals with lesions of the BLA, CeA,or BNST were trained and tested for fear-potentiated startle,which is known to be blocked by chemical lesions of either theCeA (Campeau and Davis, 1995) or the BLA (Sananes and Davis, 1992).Figure 3 shows that lesions of the CeA and the BLA, but not theBNST, completely blocked fear-potentiated startle. An overallANOVA showed that the main trial type effect was significant (noisealone vs light-noise, F_(1,26) = 19.27; p < 0.001), whereas themain group effect was not (F_(3,26) = 1.60; p < 0.214). More importantly,however, there was a significant two-way interaction between lesionand trial type (F_(3,26) = 5.39; p < 0.005). A post hoc test usingTukey's multiple comparisons showed that the magnitude of fear-potentiatedstartle was significantly greater in the sham-lesioned animalscompared with the BLA-lesioned (p < 0.019) or the CeA-lesionedanimals (p < 0.018) but not with the BNST-lesioned animals (p< 0.776). These results were not attributable to differences insensitivity to foot shocks after chemical lesions, because a comparisonof shock reactivity among the BLA, CeA, BNST, and sham lesiongroups showed no significant difference in reactivity to footshocks after lesions. Taken together, NMDA lesions of the BNST,which successfully blocked CRH-enhanced startle, did not haveany effect on fear-potentiated startle, whereas chemical lesionsof the BLA or the CeA completely blocked fear-potentiated startlebut had no effect on CRH-enhanced startle.
Fig. 3. Effects of sham lesions and NMDA lesions of the bed nucleus of the stria terminalis and central or basolateral nucleus ofthe amygdala on fear-potentiated startle. Each bar representsthe mean startle amplitude over 30 noise alone trials (10 of eachat 90, 95, and 105 dB; black bars) or 30 light noise trials (10of each at 90, 95, and 105 dB noise in the presence of light;white bars). The difference (hatched bars) between the noise andlight noise trials indicates the magnitude of fear-potentiatedstartle.
[View Larger Version of this Image (31K GIF file)]

Effects of intra-BNST and intra-hippocampus (anterior) infusions of CRH on startle
Nine of the 10 intra-BNST animals showed proper locations of the cannula tips and were subjected to data analysis. The anteriorpart of the ventral hippocampus was substantially more difficultto cannulate, and only 9 of 15 animals had cannula tips locatedinside of the hippocampus bilaterally. Figure 4B shows the compositesof the bilateral BNST and the ventral hippocampus cannula placements.
Fig. 4. Effects of various doses of CRH infused into the bed nucleus of the stria terminalis (A) or the ventral hippocampus (B), onmean percent change of startle amplitude. Each data point representsthe mean percent change of 20 postdrug test trials. C, Histologicalreconstructions showing placements of cannula tips of the animalsincluded in the data analysis.
[View Larger Version of this Image (35K GIF file)]

Intra-BNST infusion of CRH increased startle amplitude in a dose-dependent manner. Although the magnitude of increasing startleamplitude after intra-BNST CRH was not as large as that inducedby intracerebroventricular CRH (70% increase from baseline vs>100% increase from baseline), the onset of the CRH effect wasimmediate, as expected if the BNST is a primary receptor site.In contrast, there is a 20-30 min delay in the onset of CRH-enhancedstartle after intracerebroventricular infusions. If this delayreflects the time required for CRH to diffuse into a primary receptorsite, direct infusion of CRH into the receptor site should elicitits effect without any delay. Furthermore, although intra-BNSTCRH increased startle significantly during the first 60 min afterinfusion (F_(3,24) = 3.21; p = 0.041), the excitatory effect ofCRH on startle was larger and more stable throughout the secondhour of the test session, similar to characteristics of intracerebroventricularCRH-enhanced startle.

In contrast, CRH infused into the ventral hippocampus did not show significantly different effects on startle compared withACSF infusion. Both CRH and ACSF increased startle somewhat overthe first 40 min of the test period but did not have any effectson startle for the remaining 80 min of the test session. The nonspecificand transient nature of this excitatory effect may be attributableto mechanical excitation after pressure injections.

An ANOVA on the effects of CRH after intra-BNST infusions showed significant dose (F_(3,24) = 2.99; p < 0.05), and time maineffects (predrug baseline vs postdrug, F_(1,8) = 7.275; p < 0.027)and a significant time by dose interaction (F_(3,24) = 6.52; p< 0.002). The main infusion order effect was not significant (p< 0.235), suggesting that the infusion sequence of the differentdoses was not a determining factor for the significant dose effect.Subsequent tests, using Dunnett's multiple comparisons, showedthat there were significant differences in startle amplitudesafter both 80 ng (t₍₈₎ = 4.72; p < 0.01) and 160 ng (t₍₈₎ = 4.87;p < 0.01) CRH infusions compared with infusion of ACSF. The differencein startle amplitudes after ACSF and 40 ng CRH infusions was notsignificant (p > 0.05).

In contrast, intraventral hippocampus infusions of neither ACSF nor different doses of CRH induced significant changes instartle amplitude through the second hour of the test sessions(p > 0.05). However, analysis based on the data from the first60 min of the test session showed a significant main time effect(preinfusion vs postinfusion, F_(1,8) = 10.24; p < 0.013) withouta significant main dose effect (p < 0.570) or a significant interactionbetween dose and time (p < 0.557), indicating that intraventralhippocampus infusion of CRH induced no dose-related changes instartle amplitude. Figure 4A shows a summary of the behavioraldata after intra-BNST and intraventral hippocampus infusions ofACSF and CRH.

Effects of intra-BNST infusions of $alpha$ -hCRH_9-41 on CRH-enhanced startle
Three of 10 animals were not included in the data analysis because of death (n = 1), loss of cannula (n = 1), and cannulamisplacement (n = 1). Figure 5C illustrates a composite of theBNST cannula placements.
Fig. 5. A, Mean percent change of startle amplitude after fourth ventricle infusion of 0.5 µg of CRH into rats pretreated 5 min earlierwith various doses of the CRH antagonist into the BNST. The samerats were subsequently tested with intra-BNST infusion of 160ng of CRH, and the behavioral data are shown in B. Each data pointrepresents the mean percent change of 20 postdrug test trials.i.c., Intracisternal. C, Histological reconstructions showingplacements of intra-BNST cannula tips of the animals includedin the data analysis.
[View Larger Version of this Image (25K GIF file)]

Figure 5A shows that intra-BNST infusions of $alpha$ -hCRH_9-41 attenuated the effect of 0.5 µg of CRH infused into the fourthventricle in a dose-dependent manner. This conclusion was confirmedby an overall ANOVA that yield a significant main time effect(pre- vs post-CRH infusion, F_(2,12) = 16.85; p < 0.006) and asignificant time by dose interaction (F_(2,12) = 5.12; p < 0.025).A post hoc test, using Dunnett's multiple comparisons, showedthat the magnitudes of CRH-enhanced startle were not differentwhen ACSF or 3 µg of $alpha$ -hCRH_9-41 were infused into the BNSTconcomitantly with intracisternal infusion of CRH (t₍₆₎ = 2.04;p > 0.05). However, the magnitude of CRH-enhanced startle wassignificantly reduced when 6 µg of $alpha$ -hCRH_9-41, comparedwith ACSF, was infused into the BNST concomitantly with intracisternalCRH (t₍₆₎ = 3.15; p < 0.05). Furthermore, the dose-dependent reductionof the CRH effect by the CRH antagonist was not due to the particularinfusion order of the antagonist, because there was no main infusionorder effect (p < 0.327).

In addition, the cannula placements in the BNST in the antagonist study appeared to be directed toward functionally relevantsites for the excitatory effect of CRH on startle, because a subsequentinfusion of 160 ng CRH into the same sites increased startle amplitudesignificantly (t₍₅₎ = 3.90; p < 0.011) (Fig. 5B). Indeed, in theseanimals (n = 6; one animal was excluded in this experiment becauseof loss of the cannula after the antagonist study), the magnitudeof the increase in startle was comparable to that found afterintracerebroventricular infusion of a much higher amount of CRH.

Effects of intracerebroventricular infusion of 6 µg of $alpha$ -hCRH_9-41 on CRH-enhanced startle
The BNST is located immediately ventral to the lateral ventricles. Therefore, one could argue that the blockade seen withintra-BNST infusion of $alpha$ -hCRH_9-41 resulted from leakageof the antagonist into the lateral ventricles. Therefore, to becertain that leakage into the ventricle could not explain theintra-BNST antagonist effect, 6 µg of $alpha$ -hCRH_9-41 was infusedintentionally into the lateral ventricle in combination with intracisternalinfusion of 0.5 µg of CRH. All seven animals showed correct cannulaplacements (bilateral lateral ventricle and unilateral fourthventricle) and were therefore included in the data analysis.

Figure 6 shows that 6 µg of $alpha$ -hCRH_9-41 infused into the lateral ventricles did not block the effect of 0.5 µg of CRHgiven intracisternally on startle. In fact, if anything, the CRHeffect seemed even larger after this dose of the antagonist. Anoverall ANOVA revealed that there was a main effect of time, reflectingthe pretreatment to posttreatment increase in startle amplitudesafter CRH infusion (F_(1,6) = 9.18; p < 0.023) but no main antagonisteffect (F_(1,6) = 0.57; p < 0.478) or time by antagonist interaction(F_(1,6) = 1.03; p < 0.349). Thus, intracisternal infusion of 0.5µg of CRH increased startle amplitude significantly, regardlessof whether ACSF or $alpha$ -hCRH_9-41 was concomitantly infusedinto the lateral ventricles. This makes it highly unlikely thatthe blockade of CRH-enhanced startle seen with the same dose of $alpha$ -hCRH_9-41 infused locally into the BNST resulted from leakageof the CRH antagonist into the lateral ventricles located justdorsal to the BNST infusion sites.
Fig. 6. Mean percent change of startle amplitude after fourth ventricle infusion of 0.5 µg of CRH into rats pretreated 5 min earlierwith 6 µg of the CRH antagonist into the lateral ventricles. Eachdata point represents the mean percent change of 20 postdrug testtrials. I.c., Intracisternal; i.c.v., intracerebroventricular.
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Effects of intra-CeA infusion of 6 µg of $alpha$ -hCRH_9-41 on CRH-enhanced startle and expression of fear-potentiated startle
In the first part of the present experiment, $alpha$ -hCRH_9-41 was infused into the CeA concomitantly with intracisternal CRHto examine the anatomical specificity of the blockade of CRH-enhancedstartle seen with intra-BNST infusions of $alpha$ -hCRH_9-41. Twoof 10 animals were excluded because of cannula misplacements.Figure 7C, left panel, illustrates a composite of cannula locationswithin the CeA.
Fig. 7. A, Mean percent change of startle amplitude after fourth ventricle infusion of 0.5 µg CRH into rats pretreated 5 min earlierwith 6 µg of the CRH antagonist into the CeA. Each data pointrepresents mean percent change of 20 postdrug test trials. I.c.,Intracisternal. B, Effects of ACSF or 6 µg of the CRH antagonistinfused into the CeA on expression of fear-potentiated startle.Each bar represents the mean startle amplitude over 30 noise alonetrials (10 of each at 90, 95, and 105 dB; black bars) or 30 lightnoise trials (10 of each at 90, 95, and 105 dB noise in the presenceof light; white bars). The difference (hatched bars) between thenoise and light noise trials indicates the magnitude of fear-potentiatedstartle. C, Histological reconstructions showing placements ofintra-CeA cannula tips of the animals included in the data analysis.
[View Larger Version of this Image (30K GIF file)]

Figure 7A showed that 6 µg of $alpha$ -hCRH_9-41 infused into the CeA did not block the excitatory effect of 0.5 µg CRH givenintracisternally on startle. An overall ANOVA revealed a significantmain effect of time (F_(1,7) = 11.94; p < 0.011), indicative ofthe excitatory effect of CRH, but neither a main antagonist effect(F_(1,7) = 0.01; p < 0.944) nor a time by antagonist interaction(F_(1,7) = 0.53; p < 0.489). These data suggest that CRH receptorsin the amygdala are not a part of the neural circuitry used byCRH given intracerebroventricularly, whereas CRH receptors inthe BNST are critically involved in mediating CRH-enhanced startle.

In the second part of the present experiment, the possibility that nonspecific effects of the antagonist (i.e., local anestheticeffects) may have caused the blockade of intracisternal CRH wasinvestigated. Because NMDA lesions of the BNST block CRH-enhancedstartle, one could argue that $alpha$ -hCRH_9-41 infused into theBNST blocked the intracisternal CRH effect not by pharmacologicalantagonism but by causing reversible inactivation of the BNST.Hence, after the main experiment looking at the effects of $alpha$ -hCRH_9-41infused into the amygdala on intracisternal CRH, the same ratswere trained and then tested for fear-potentiated startle afterinfusion of 6 µg of $alpha$ -hCRH_9-41 into the CeA. It is wellknown that the CeA is essential for the expression of fear-potentiatedstartle (Hitchcock and Davis, 1986, 1987; Campeau et al., 1992).Therefore, if 6 µg of $alpha$ -hCRH_9-41 did cause a local anestheticeffect, it should block the expression of fear-potentiated startle.To test this, 48 hr after the last CRH- $alpha$ -hCRH_9-41 test,the same animals were trained, and 2 d later the level of fear-potentiatedstartle was tested after intra-CeA infusion of either ACSF or6 µg of $alpha$ -hCRH_9-41, using a crossover design. Figure 7Bshows that ACSF or 6 µg of $alpha$ -hCRH_9-41 infused into the CeAfailed to block the expression of fear-potentiated startle. Thus,an overall ANOVA showed a highly significant increase in startlein the presence versus absence of the light (fear-potentiatedstartle, F_(1,7) = 23.40; p < 0.001) but no interaction betweenthe fear-potentiated startle effect and the antagonist effect(F_(1,7) = 3.30; p < 0.119). The present study provides the firstevidence demonstrating that CRH in the CeA may not be involvedin the expression of fear-potentiated startle. More importantly,because the functional integrity of the CeA is critical in expressingfear-potentiated startle, and because infusion of local anestheticsinto the amygdala blocks the expression of conditioned fear (Helmstetter,1994), including fear-potentiated startle (J. M. Hitchcock andM. Davis, unpublished observation), making the reasonable assumptionthat the putative local anesthetic effects of compounds will besimilar in different brain areas, these data suggest that $alpha$ -hCRH_9-41does not have local anesthetic effects at a 6 µg dose.

DISCUSSION

The BNST may be a primary receptor site for CRH given intracerebroventricularly
The present studies strongly suggest that the BNST might be a primary receptor site for the excitatory effect of intracerebroventricularCRH on the acoustic startle reflex. NMDA lesions of the BNST blockedCRH-enhanced startle. Intra-BNST infusions of CRH significantlyincreased startle amplitude, and a CRH antagonist, $alpha$ -hCRH_9-41,dose-dependently blocked CRH-enhanced startle.

The role of the hippocampus in CRH-enhanced startle is unclear. Because our ventral hippocampal lesions aimed to damage theanterior part of the ventral hippocampal/subiculum area, whichprojects directly into the BNST (Cullinan et al., 1993), the posterioraspect of this area was consistently spared. Therefore, it isclear that the effects of whole hippocampal or complete ventralhippocampal lesions need to be examined. At the present time,neither lesions of the dorsal hippocampus (Lee and Davis, 1997)nor those of the ventral hippocampus (present study) blocked CRH-enhancedstartle. However, a subset of the ventral hippocampus-lesionedanimals showed almost complete blockade of CRH-enhanced startle,whereas animals with seemingly more severe damage showed robustCRH-enhanced startle. Although we have replicated this effect,we have no further information to explain the differences betweenthese two subgroups. Lesion studies accompanied by various counterstainingmethods for different neurotransmitters (e.g., GABA and acetylcholine)are clearly needed. Because intraventral hippocampal infusionsof CRH did not enhance startle, we predict that the hippocampusmay play a modulatory role for CRH-enhanced startle rather thanbeing a primary receptor site.

The finding that large electrolytic lesions of the amygdala blocked CRH-enhanced startle (Liang et al., 1992) is still notresolved by the present data. Our suspicion is that the electrolyticlesions destroyed fibers projecting from the BNST to the startlepathway. Further studies using electrolytic lesions in combinationwith retrograde or anterograde tracing techniques will be requiredto address this issue.

Implications for a possible distinction between fear and anxiety
Intracerebroventricular infusion of CRH elicits a pattern of behavioral changes typically observed during states of fear oranxiety (cf. Dunn and Berridge, 1990). Although there is a closecorrespondence between these two emotional states, they also differin important ways. Fear is a natural, adaptive change elicitedby a potentially threatening stimulus, which prepares an animalto cope with provocation. Fear generally is elicited by an identifiablestimulus and subsides shortly after its offset. Anxiety also isa change in state that has many of the same signs and symptomsof fear. However, it may not be clearly associated with a singleeliciting stimulus, may last for long periods once activated,and may lack clear adaptive significance.

Defined in this way, fear-potentiated startle clearly represents a measure of conditioned fear, because it is rapidly producedby a definable stimulus and dissipates quickly once that stimulusis turned off. On the other hand, CRH-enhanced startle may bemore akin to anxiety, because it has a more gradual onset andlasts for a very long time.

The present studies found a double dissociation between the amygdala and BNST with respect to fear-potentiated and CRH-enhancedstartle. Lesions of the BNST, but not the CeA or BLA, completelyblocked CRH-enhanced startle. Conversely, the same lesions ofthe BNST did not block fear-potentiated startle, whereas lesionsof the CeA or BLA did. Moreover, $alpha$ -hCRH_9-41 infused intothe BNST, but not into the CeA, significantly attenuated CRH-enhancedstartle, consistent with the idea that only receptors in the BNSTare involved in CRH-enhanced startle. If one agrees that CRH-enhancedstartle is a measure of anxiety, whereas fear-potentiated startleis a measure of fear, the present results suggest that the BNSTmay be a neural substrate related to anxiety states, whereas theamygdala may be critical for fear responses.

Supporting this hypothesis, Möller et al. (1994) reported that c-fos antisense infused into the amygdala failed to blockintracerebroventricular CRH-induced suppression of punished responses,suggesting that the amygdala may not mediate anxiogenic effectsinduced by intracerebroventricular CRH. Walker and Davis (1996)found that blockade of glutamate receptors in the BNST, but notin the CeA, blocked the unconditioned anxiogenic effects of abright light (20 min duration), which produces a slowly developingincrease in startle amplitude that lasts for a long time oncethe light is turned off (Walker and Davis, 1997). Davis et al.(1995) showed that electrolytic lesions of the BNST blocked contextualconditioning or long-term sensitization of startle when fear-potentiatedstartle training occurred daily but had no effect on fear-potentiatedstartle itself. Gray et al. (1993) reported that lesions of theBNST attenuated increases in plasma levels of ACTH and corticosteroneafter reintroduction into a context previously paired with footshocks.

The hypothesis that the BNST may be a neural substrate related to anxiety, however, should not be taken as contradictory toa wealth of evidence pointing to the critical role of the amygdalain various stress and anxiety responses. Stress, including intracerebroventricularinfusion of CRH, induces strong c-fos activation within the amygdala(Arnold et al., 1992; Honkaniemi, 1992; Honkaniemi et al., 1992;Imaki et al., 1993), along with increased CRH mRNA (Swanson andSimmons, 1989; Mamalaki et al., 1992; Makino et al., 1994a,b,1995). Furthermore, CRH is released in the amygdala after restraintstress (Pich et al., 1995).

Similar to intracerebroventricular CRH effects, intra-amygdala infusion of CRH has been reported to produce anxiogenic behavior(Liang and Lee, 1988; Lee and Tasi, 1989; Elkabir et al., 1990),and a CRH antagonist infused into the amygdala significantly attenuatedstress-induced freezing (Heinrichs et al., 1992; Swiergiel etal., 1993) or anxiogenic effects of alcohol withdrawal (Rassnicket al., 1993; Menzaghi et al., 1994).

The BNST is a primary target of the amygdala (de Olmos et al., 1985; Sun et al., 1991; Alheid et al., 1995), and both theBNST and the amygdala share almost identical brainstem targetareas implicated in stress and anxiety responses (Schwaber etal., 1980; Takeuchi et al., 1982, 1983; Sofroniew, 1983; Swansonet al., 1984; Veening et al., 1984; Holstege et al., 1985; Grayand Magnuson, 1987, 1992; Moga et al., 1989). Interestingly, someof the projections to the amygdala (cf. Gray, 1993) and the projectionsfrom the amygdala to the BNST contain CRH (Sakanaka et al., 1986;Gray, 1990). Therefore, together with finding that CRH neuronsin the amygdala can be activated by CRH (Uryu et al., 1992), onecan hypothesize that stress may induce release of CRH in the amygdala,which then releases CRH in the BNST. Activation of the BNST byCRH would activate various brainstem target areas involved instress and anxiety responses. This would explain why lesions ofthe BNST but not the amygdala blocked effects of CRH given intracerebroventricularly(present study), whereas amygdala manipulations are effectivein blocking stress and anxiety responses caused by various stressors.If the BNST is indeed the final common pathway for stress andanxiety responses, one would predict that lesions of the BNSTor a CRH antagonist infused into the BNST would block variousstress and anxiety responses as effectively as these same treatmentsdo when applied to the amygdala.

Clinical implications
Patients with post-traumatic stress disorder (PTSD) or depression often show elevated CSF concentrations of CRH (Nemeroffet al., 1984; France et al., 1988; Arató et al., 1989; Bánkiet al., 1992a,b; Darnell et al., 1994). However, neither the originnor the function of this elevated CSF CRH is known. The presentstudies provide evidence that CSF CRH may play an active rolein CNS functions via interacting with the BNST.

If CSF CRH activates the BNST, which in turn chronically activates its target areas critical for stress and anxiety responses(see above), this may be responsible for enhanced anxiety observedin many of these patients. As one of the biological models ofPTSD and depression predicts (cf. Post et al., 1981; Charney etal., 1993), such effects might be amplified by stress-inducedkindling of various limbic areas, including the amygdala and BNST.The amygdala and BNST show particularly dense concentrations ofCRH cell bodies and receptors (Cummings et al., 1983; De Souzaet al., 1984; Sawchenko and Swanson, 1985; Sakanaka et al., 1987;Chalmers et al., 1995; Lovenberg et al., 1995), and chronic stressincreased CRH mRNA in the CeA and BNST (Mamalaki et al., 1992;Makino et al., 1994a,b, 1995). Taken together, these data raisethe possibility that stress may sensitize CRH systems in limbicstructures, such as the amygdala and/or BNST, leading to a persistentincrease in CRH transmission. If so, nonpeptide CRH antagonistscould have major prophylactic effects in halting the spiral ofstress-induced sensitization of limbic circuits. The present resultswould suggest that CRH antagonists that selectively bind to CRHreceptors in the BNST may be especially promising in this regard.

FOOTNOTES

Received Jan. 13, 1997; revised May 21, 1997; accepted May 29, 1997.

This research was supported by National Institute of Mental Health Grant MH-47840, Research Scientist Development Award MH-00004to M.D., a Grant from the Air Force Office of Scientific Research,and the state of Connecticut.

Correspondence should be addressed to Dr. Michael Davis, Yale University, Department of Psychiatry, Connecticut Mental HealthCenter, 34 Park Street, New Haven, CT 06508.

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