Warning: fopen(/home/virtual/pediatrics/journal/upload/ip_log/ip_log_2024-03.txt) [function.fopen]: failed to open stream: Permission denied in /home/virtual/pediatrics/journal/ip_info/view_data.php on line 82

Warning: fwrite(): supplied argument is not a valid stream resource in /home/virtual/pediatrics/journal/ip_info/view_data.php on line 83
Vasovagal syncope with mild versus moderate autonomic dysfunction: a 13-year single-center experience

Volume 65(1); January

< Previous     Next >

Article Contents

Clin Exp Pediatr > Volume 65(1); 2022
Lee and Lee: Vasovagal syncope with mild versus moderate autonomic dysfunction: a 13-year single-center experience

Abstract

Background

An adequate large-scale pediatric cohort based on nationwide administrative data is lacking in Korea.

Purpose

This study aimed to differentiate patients with VVS by autonomic dysfunction severity using the composite autonomic severity score (CASS) and compare the clinical manifestations and prognosis between patient subgroups.

Methods

We retrospectively reviewed the medical records of 66 VVS patients divided into 3 groups by CASS. To compare the differences between these groups, we analyzed VVS type, triggers, prodromal symptoms, management of syncope, and prognosis between patients with mild versus moderate autonomic dysfunction.

Results

Of our 66 patients with VVS, 41 had mild autonomic dysfunction (62.1%) and 25 had moderate autonomic dysfunction (37.9%). We found no significant intergroup differences in age, sex, inducible factor (P=0.172), prodromal symptoms, laboratory findings, head-up tilt test, type of syncope, or prognosis (P=0.154).

Conclusion

We found no evidence that autonomic dysfunction degree is affected by VVS characteristics, test findings, parameters, or prognosis; therefore, no further evaluations are needed to classify autonomic dysfunction severity.

Introduction

Syncope is defined as a transient loss of consciousness (LOC) associated with cerebral hypoperfusion [1]. Syncope can happen when the cerebral blood flow is less than 30 mL/min per 100 g brain tissue or when the mean cerebral blood flow rate is below 50% [2,3]. It is a common problem in children and adolescents; approximately 15% of children and adolescents experience at least one episode of syncope before the age of 18 [4]. Syncope can be classified as neurally mediated, orthostatic, or cardiogenic. Among these, the most common form of syncope is vasovagal syncope (VVS) which is a subtype of neurally mediated syncope [5].
VVS can be diagnosed in approximately 50% of cases by detailed history taking and physical examination [1]; however, diagnosis is challenging for the remaining cases. A significant problem is that history taking is limited because patients lose consciousness, and so only bystanders can provide an account of events.
To maintain homeostasis in conditions of environmental change, vital signs are regulated by the autonomic nervous system. Stimulation from the sympathetic nervous system increases heart rate, and cardiac contractility, whereas that of the parasympathetic nervous system decreases heart rate, and cardiac contractility. To maintain adequate blood flow in the entire body, including brain, effective regulation of the autonomic nervous system is essential [6,7]. In cases of VVS, not yet fully elucidated, decreased venous pooling by standing up rapidly or other reason, results in decrease in a venous return to the heart and diminishing cardiac output. Consequently, sympathetic nervous system increases to maintain blood pressure. The increased sympathetic nervous system has positive chronotropic and inotropic effects, makes ventricle contract more vigorously. But underfilled ventricle stimulates ventricular neural afferents to the brain. These afferents terminate in cardiovascular control centers where the input signals are integrated and results in sympathetic and parasympathetic activity to cardiovascular system. In VVS patients, activated central nuclei activate sympathetic tone and rapidly withdraw and increase in parasympathetic tone. Then increased parasympathetic tone reduces chronotropic response for evolving hypotension which is result of withdrawal of sympathetic tone. This response makes inappropriate heart rate slowing and the patients could LOC [8,9].
The head-up tilt test (HUT) is widely used to diagnose VVS. The test elicits autonomic functional changes that provoke a syncope. However, a limitation of the test is that it is difficult to classify the severity of the autonomic dysfunction.
Thus, the hypothesis underlying our current study was that there would be differences in the type, nature, and test results of VVS in our study group depending on the degree of autonomic nerve dysfunction. And the purpose of this study, was to characterize and classify the degree of autonomic dysfunction using different autonomic function tests and compare the clinical features according to degree of autonomic dysfunction.

Methods

1. Patient enrollment

One hundred thrity-five patients diagnosis as syncope, aged between 8 to 18, admission to the Department of Pediatrics at Daegu Fatima Hospital between January 2008 and July 2020 were enrolled in this study and their medical records were retrospectively reviewed. We include all of these patients and we exclude limited available data, diagnosed as other than VVS, and negative HUT results.
Finally, we exclude 19 patients because of limited data, 20 with postural orthostatic tachycardia syndrome patients, 15 with negative HUT, 2 with brain tumors, 2 with encephalopathy, and 2 with atrioventricular block. After excluding these patients, we diagnose 66 patients with VVS and enrolled in our study. Of our VVS patients, we diagnosed mild autonomic dysfunction in 41 patients, moderate autonomic dysfunction in 25, and no other patients were diagnosed as severe autonomic dysfunction.

2. Data collection

Patients’ medical records were retrospectively reviewed to examine their age, sex, height, body weight, prodromal symptoms, and triggers. After admission, the patients underwent a blood test, which included complete blood count, total protein, albumin, serum electrolytes, aspartate aminotransferase, alanine aminotransferase, C-reactive protein, in addition to a thyroid function test, electrocardiogram, Holter test, chest x-ray, electroencephalogram (EEG), echocardiogram, HUT, Transcranial Doppler (TCD), and autonomic function tests. All patients in our study were followed-up through the outpatient department to analyze prognosis.

3. HUT and TCD

HUT (TT-800s, Pampas, Gimpo, Korea) was performed after at least 8 hours of bed rest before the test. After the patient lay in the supine position for 10 minutes, the test was performed for 20 minutes at a 70° tilt. Patients who showed symptoms, such as dizziness, visual disturbance, or nausea, as well as those with atypical symptoms, such as headache and arm and leg pain or weakness during testing were considered positive [10]. If patients show negative result, repeat the HUT with pharmacological provocation. At the 2013, we changed protocols of HUT. During 2008–2013, isoproterenol was used for the pharmacological provocation, but after 2013, we changed it to nitroglycerine. Other than that, other protocols are same during our study periods.
VVS was classified by cardioinhibition, vasodepressor, mixed type VVS using previously defined diagnostic criteria [1].
TCD (Pioneer System TC 2020, Nicolet Biomedical Inc., Madison, WI, USA) was on the middle cerebral artery of patients, and systolic, diastolic, and mean cerebral artery blood flow were used to calculate the pulsatility index (PI) using the following formula: PI=(Vsystol – Vdiastol)/Vmean

4. Autonomic function tests

The CASS is calculated using sudomotor index, adrenergic index, cardiovascular heart rate index. And each index is calculated by following test.
The quantitative sudomotor axon reflex test (QSART) (Q-sweat, WR Medical Electronics Co., Maplewood, MN, USA) is the test evaluates the function of the postganglionic sympathetic sudomotor axon [11]. From the test, we could get the amount of sweating and latencies from 3 sites (forearm, proximal leg, distal leg) [12,13]. And from that results, sudomotor index could be calculated [14]. The Valsalva test evaluates the sympathetic adrenergic and parasympathetic functions using heart rate responses. From the test, Valsalva ratio is calculated by dividing the highest heart rate by the lowest [14]. The heart rate response to deep breathing was used to determine the cardiac parasympathetic function through the vagal nerve. For the test, lie down the patient on the bed and instructed to inhale and exhale for 5 seconds each for 6 times. After testing, the cardiovascular heart rate index is calculated [14].
From the previous study, it was challenging to quantifying the severity of autonomic dysfunction. For this reason, we performed autonomic function testing and calculate composite autonomic severity score (CASS). The CASS is the total sum of the sudomotor index, adrenergic index, cardiovascular heart rate index as a protocol [13]. Cardiovascular heart rate index is calculated by using Valsalva ratio and heart rate response to deep breathing. Adrenergic score is calculated from the Valsalva ratio and HUT results. From the total sum of cardiovascular heart rate index, adrenergic score, and sudomotor index, CASS is calculated. CASS ranges from 0 to 10. In which a score between 0–3 is classified as mild, 4–7 as moderate, and 8–10 as severe [14]. From CASS, we could objectively quantitate autonomic dysfunction.

5. Statistical analysis

All statistical analyses were performed using the PASW statics ver. 18.0 (SPSS Inc., Chicago, IL, USA). Mean values between the 2 groups were compared the independent t test, and chi-square test was used for comparisons of categorical data. Statistical significance was defined as a P<0.05.

6. Ethics statement

This study was approved by the Institutional Review Board of Daegu Fatima Hospital (approval number: DFE20ORIO087).

Results

1. Patient’s characteristics

The mean age of patients in our study was 13.8 years ranging from 8 to 18 years, with a sex ratio of 18 boys (27.3%) to 48 girls (72.7%). Forty-one patients, whose mean age was 14.1 years with a sex ratio of 8 boys (19.5%) to 33 girls (80.5%), were diagnosed with mild autonomic dysfunction. The remaining 25 patients of our study, whose mean age was 13.4 years with a sex ration of 10 boys (40.0%) to 15 girls (60.0%), were diagnosed with moderate autonomic dysfunction. We found no statistical differences between the 2 groups in sex distribution, body weight, height, body mass index, diastolic blood pressure, and heart rate (Table 1). In laboratory finding, complete blood cell count, electrolyte profile, thyroid function test, and N terminal pro B type natriuretic peptide shows no statistically difference between the 2 groups.

2. Triggers and prodromal symptoms

Among our 66 patients with VVS, we identified the following triggers: prolonged standing (n=47), postural change (n=14), bowel movement (n=2), exercise (n=1), stress (n=1), and unknown (n=1). We found no statistical differences in trigger cause between the 2 subgroups (P=0.172) (Fig. 1).
In the study group, some patients presented multiple prodromal symptoms. The symptoms presented in our study were dizziness (n=34), vision-related (n=34), nausea/vomiting (n=5), weakness on extremity (n=3), and headache (n=1); no symptoms were reported in 3 cases. There were no differences in prodromal symptoms between our 2 groups (P=0.149).

3. HUT results

All 66 patients in our study were positive on the HUT. Thirty patients were positive on HUT without using any medication, while 36 patients were positive on HUT after using medications such as isoproterenol or nitroglycerin. Among the 41 patients with mild autonomic dysfunction, 24 had vasodepressor VVS and 17 had mixed VVS. Among the 25 patients with moderate autonomic dysfunction, vasodepressor VVS was diagnosed in 15 and mixed VVS was diagnosed in 10. We found no instances of cardioinhibitory VVS in our study. Furthermore, there were no statical differences in type of VVS between the 2 groups (P=0.280) (Table 1).

4. TCD results

TCD was conducted in 66 patients of our study group. Diastolic blood flow, mean blood flow, and PI were measured by TCD in all patients before administration and during positive response on the HUT. Prior to testing, our study group had a mean diastolic blood flow of 53.85 cm/sec, mean blood flow of 74.39 cm/sec, and PI of 0.71 compared to a mean diastolic blood flow of 16.76 cm/sec, mean blood flow of 38.17 cm/sec, and PI of 1.51 when the positive response on the HUT. Diastolic blood flow and mean blood flow decreased by 68.7% and 46.7%, respectively, while PI increased by 112.68% when patients showed symptoms.
Patients with mild autonomic dysfunction showed a mean diastolic blood flow of 54.83 cm/sec, mean blood flow of 75.88 cm/sec, and PI of 0.70, whereas patients with moderate autonomic dysfunction showed a mean diastolic blood flow of 52.20 cm/sec, mean blood flow of 71.96 cm/sec, and PI of 0.73. We found no significant differences in mean diastolic and mean blood flow rates between patients with mild and moderate autonomic dysfunction (P>0.05). Moreover, the value of delta score between baseline and syncope (baseline value – syncope value) shows no statistical difference (Table 2).

5. Autonomic function test results and severity of symptoms

All 66 patients underwent autonomic function test. Mild autonomic dysfunction group shows mean Valsalva ratio of 2.03, heart rate response to deep breathing of 18.30, cardiovascular index of 0.20, adrenergic index of 1.17, and sudomotor index of 0.95. Moderate autonomic dysfunction group shows mean Valsalva ratio of 2.02, heart rate response to deep breathing of 20.28, cardiovascular index of 0.32, adrenergic index of 2.20, and sudomotor index of 2.00. From this result, cardiovascular index and adrenergic index shows statistically meaningful (P=0.033 and P<0.001, respectively) (Table 3).

6. Treatment outcomes and prognosis

Before follow-up, all patients received patient education, such as encouraging lifestyle modifications and increased water intake. We teach patients to stand up slowly after lying down and take water approximately 2 L/day. And 39 patients take oral medicine in addition to education and lifestyle modification. The types of oral medications prescribed were propranolol (n=29), midodrine (n=9), propranolol and midodrine (n=1). For the treatment, we could not compare the mild and moderate autonomic dysfunction group. As will be described later, biases are reflected so it is worthless to compare the 2 groups.
Patients were followed-up for an average of 4.6 months, and we found no significant differences in symptoms according to medication type and degree of autonomic dysfunction. After excluding 2 patients lost to follow-up, 38 (59.4%) had no symptoms, while 26 (40.6%) developed symptoms. The types of symptoms included at least 1 episode of dizziness (n=23), 1 episode of syncope (n=2), and 2 or more episodes of syncope (n=1) (Table 4).

Discussion

Syncope is a relatively common problem in adolescence, up to 15%–50% experience more than once before grown up [4,15,16]. Among the syncope patients, VVS is the most common and it is associated with autonomic dysfunction [17]. The main purpose of this study was to differentiate VVS patients according to their degree of autonomic dysfunction and analyze the difference between the 2 groups. In conclusion, we found no difference between the 2 groups, and no further evaluations are needed to classify the severity of autonomic dysfunction.
In this study, we performed laboratory test, ECG, HUT, TCD, and autonomic function tests for syncope diagnosis and severity assessment. It was previously shown that HUT is useful in diagnosis of syncope [1]. During HUT, the blood pressure and heart rate are monitored to evaluate hypotension, bradycardia, and tachycardia. In addition, TCD was giventoevaluate cerebral blood flow. In our study group, we found significant decreases in the diastolic (68.9%), mean (48.7%) blood flows, and a significant increase in PI (112.64%) at the time of a positive result in HUT compared to baseline.
Except for systolic blood pressure, we found no other differences in measures between mild and moderate autonomic dysfunction in our study. Comparisons between blood test results, TCD, prodromal symptoms, trigger factors, and follow-up outcomes revealed no differences between the 2 subgroups. In fact, only systolic blood pressure was slightly higher in the moderate autonomic dysfunction group by approximately 4 mmHg on average. Although our analysis indicated a statistically significant difference (P=0.033), we consider that the finding may be meaningless because such blood pressure difference between the 2 groups would not be expected to cause a physiological difference in autonomic function.
Syncope is related with autonomic dysfunction, and conventionally, HUT is most commonly used for the diagnoses of VVS. However, HUT alone cannot determine the severity of autonomic dysfunction, and the etiology of approximately 50%–75% of cases remains unknown [18]. In such challenging cases, autonomic function tests can play a key role in the diagnosis and evaluation of the severity of autonomic dysfunction.
From the previous study, they underwent autonomic function test for the diagnosis of syncope, but they did not differentiate degree of autonomic dysfunction [19,20]. Consequently, there were no attempts to quantifying the degree of autonomic dysfunction of VVS patients and compare the VVS patients by the degree of autonomic dysfunction.
From this point, we start this study. The hypothesis underlying our current study was that there would be differences in the type, nature, and test results of VVS in our study group depending on the degree of autonomic nerve dysfunction. However, subgroup analysis found no evidence of either clinical or laboratory differences in VVS between patients with mild or moderate autonomic dysfunction. This finding suggests that such differences in VVS are not detectable compared to other classification categories using the CASS system. In addition, it may be that clinical or other measured differences in VVS are offset by compensatory mechanisms.
As mentioned above, during follow-up, we did education alone and education with orally administered medication such as propranolol and midodrine. Propranolol lessens ventricular mechanoreceptor activation owing to its antisympathetic and negative inotropic effect [21]. Midodrine increases blood pressure by increasing peripheral vascular resistance with a modest reduction in heart rate [22]. Using the chi-square test, we found a significant difference between patients with mild and moderate autonomic dysfunction (P=0.006); however, it not that meaningful result. Because we use medication to compare syncope frequency and severity, but some patients wanted to be medicated irrespective of these factors, whereas other were not medicated even when it was recommended. Thus, we believe that this statistical finding is because of such biases and does not reflect a true association.
Our study had several limitations. First, we retrospectively analyzed medical records, and seconds, the number of enrolled patients was relatively small. These factors limited our ability to identify differences in VVS depending on the degree of autonomic dysfunction VVS.
In conclusion, using test of autonomic function, we evaluated the degree of autonomic dysfunction in patients with VVS and compare the 2 groups. Despite reviewing records at our center from the past 13 years, our study group of 66 patients may have insufficient power to allow identifying and defining the relationship between mild and moderate autonomic dysfunction in patients with VVS. Despite this limitation, the current study, shows that the degree of autonomic dysfunction may not be affected by characteristics, findings, parameters, and prognosis of VVS. Furthermore, although a definite relationship between mild and moderate autonomic dysfunction in patients with VVS was not identified, we propose that further study involving multiple centers and greater patient recruitment would reveal the relationship between the degree of autonomic dysfunction and characteristics, finding and prognosis of VVS.

Footnotes

Conflicts of interest

No potential conflict of interest relevant to this article was reported.

Fig. 1.
Triggers of vasovagal syncope.
cep-2021-00052f1.jpg
Table 1.
Patient characteristics by study group
Characteristic Total patients (n=66) Mild autonomic dysfunction (n=41) Moderate autonomic dysfunction (n=25) P value
Age (yr) 13.8±1.76 14.1±1.61 13.4±0.60 0.575
Sex
 Male 18 8 10 0.070
 Female 48 33 15
Type of vasovagal syncope 0.280
 Cardioinhibition 0 0 0
 Vasodepressed 39 24 15
 Mixed 27 17 10
Height (cm) 163.0±6.41 163.0±5.87 163.0±7.35 0.275
Body weight (kg) 54.9±11.97 53.8±10.03 56.8±14.66 0.258
Body mass index (kg/m2) 20.6±3.94 20.2±3.44 21.3±4.65 0.250
Systolic blood pressure (mmHg) 111.1±10.03 109.4±11.01 113.8±7.69 0.033
 Percentile 55.56±27.22 50.85±30.10 63.28±19.91 0.012
Diastolic blood pressure (mmHg) 63.8±8.08 64.0±8.37 63.3±7.73 0.568
 Percentile 53.67±21.72 47.78±25.23 63.32±7.73 0.412
Heart rate (frequency/min) 84.9±11.67 85.9±10.44 83.3±13.52 0.455

Values are presented as number or mean±standard deviation or number.

Mild and moderate groups were classified according to composite autonomic severity score.

Boldface indicates a statistically significant difference with P<0.05.

Table 2.
Transcranial Doppler results by study group
Variable Mild autonomic dysfunction (n=41) Moderate autonomic dysfunction (n=25) P value
Baseline
 Diastolic blood flow (cm/sec) 54.83±15.17 52.20±12.46 0.722
 Mean blood flow (cm/sec) 75.88±21.01 71.96±17.11 0.685
 Pulsatility index 0.70±0.15 0.73±0.12 0.798
Syncope
 Diastolic (cm/sec) 16.98±7.30 16.40±7.07 0.904
 Mean (cm/sec) 38.44±10.21 38.72±8.60 0.815
 Pulsatility index 1.54±0.49 1.47±0.37 0.806
Delta score (Δ) between baseline and syncope (Δ=baseline–syncope)
 Diastolic blood pressure 37.85±12.52 35.80±13.12 0.618
 Mean blood pressure 37.44±13.46 34.24±11.47 0.657
 Pulsatility index 0.84±0.46 0.73±0.41 0.827

Values are presented as mean±standard deviation.

Mild and moderate groups were classified according to composite autonomic severity score.

Table 3.
Autonomic function test results by study group
Variable Mild autonomic dysfunction (n=41) Moderate autonomic dysfunction (n=25) P value
Valsalva ratio 2.03±0.41 2.02±0.30 0.230
Heart rate response to deep breathing 18.30±5.22 20.28±6.94 0.098
Cardiovascular index 0.20±0.40 0.32±0.56 0.033
Adrenergic index 1.17±0.50 2.20±1.04 <0.001
Sudomotor index (QSART) 0.95±0.71 2.00±1.04 0.05

Values are presented as mean±standard deviation.

QSART, quantitative sudomotor axon reflex test.

Mild and moderate groups were classified according to composite autonomic severity score.

Boldface indicates a statistically significant difference with P<0.05.

Table 4.
Treatment outcomes and patient prognosis
Variable Mild autonomic dysfunction (n=41) Moderate autonomic dysfunction (n=25) P value
Treatment 0.006
Education 10 17
Education + medication 31 8
During follow-up 0.154
No symptoms 19 19
Symptoms 21 5
Follow-up loss 1 1

Mild and moderate groups were classified according to composite autonomic severity score.

Boldface indicates a statistically significant difference with P<0.05.

References

1. Brignole M, Moya A, de Lange FJ, Deharo JC, Elliott PM, Fanciulli A, et al. 2018 ESC Guidelines for the diagnosis and management of syncope. Eur Heart J 2018;39:1883–948.
crossref pmid
2. Schraeder PL, Lathers CM, Charles JB. The spectrum of syncope. J Clin Pharmacol 1994;34:454–9.
crossref pmid
3. Njemanze PC. Critical limits of pressure-flow relation in the human brain. Stroke 1992;23:1743–7.
crossref pmid
4. Massin MM, Bourguignont A, Coremans C, Comté L, Lepage P, Gérard P. Syncope in pediatric patients presenting to an emergency department. J Pediatr 2004;145:223–8.
crossref pmid
5. Benditt DG, van Dijk JG, Sutton R, Wieling W, Lin JC, Sakaguchi S, et al. Syncope. Curr Probl Cardiol 2004;29:152–229.
crossref pmid
6. Freeman R, Chapleau MW. Testing the autonomic nervous system. Handb Clin Neurol 2013;115:115–36.
crossref pmid
7. Low PA, Denq JC, Opfer-Gehrking TL, Dyck PJ, O'Brien PC, Slezak JM. Effect of age and gender on sudomotor and cardiovagal function and blood pressure response to tilt in normal subjects. Muscle Nerve 1997;20:1561–8.
crossref pmid
8. Medow MS, Merchant S, Suggs M, Terilli C, O'Donnell-Smith B, Stewart JM. Postural heart rate changes in young patients with vasovagal syncope. Pediatrics 2017;139:e20163189.
crossref pmid pmc
9. Adkisson WO, Benditt DG. Syncope due to autonomic dysfunction: diagnosis and management. Med Clin North Am 2015;99:691–710.
pmid
10. Gourishankar A, Belton MD, Hashmi SS, Butler IJ, Lankford JE, Numan MT. Demographic and clinical features of pediatric patients with orthostatic intolerance and an abnormal head-up tilt table test; a retrospective descriptive study. Pediatr Neonatol 2020;61:68–74.
crossref pmid
11. Novak P. Quantitative autonomic testing. J Vis Exp 2011;(53): 2502.
crossref pmid pmc
12. Low PA. Autonomic nervous system function. J Clin Neurophysiol 1993;10:14–27.
crossref pmid
13. Low PA. Laboratory evaluation of autonomic function. Suppl Clin Neurophysiol 2004;57:358–68.
pmid
14. Low PA. Composite autonomic scoring scale for laboratory quantification of generalized autonomic failure. Mayo Clin Proc 1993;68:748–52.
crossref pmid
15. Sun BC, Emond JA, Camargo CA Jr. Characteristics and admission patterns of patients presenting with syncope to U.S. emergency departments, 1992-2000. Acad Emerg Med 2004;11:1029–34.
crossref pmid
16. Ganzeboom KS, Colman N, Reitsma JB, Shen WK, Wieling W. Prevalence and triggers of syncope in medical students. Am J Cardiol 2003;91:1006. –8. A8.
crossref pmid
17. Jarjour IT. Postural tachycardia syndrome in children and adolescents. Semin Pediatr Neurol 2013;20:18–26.
crossref pmid
18. Moya A. Tilt testing and neurally mediated syncope: too many protocols for one condition or specific protocols for different situations? Eur Heart J 2009;30:2174–6.
crossref pmid
19. Sneddon JF, Counihan PJ, Bashir Y, Haywood GA, Ward DE, Camm AJ. Assessment of autonomic function in patients with neurally mediated syncope: augmented cardiopulmonary baroreceptor responses to graded orthostatic stress. J Am Coll Cardiol 1993;21:1193–8.
crossref pmid
20. Tao C, Tang C, Chen S, Jin H, Du J. Autonomic nervous function in vasovagal syncope of children and adolescents. Neurosci Bull 2019;35:937–40.
crossref pmid pmc
21. Sra JS, Murthy VS, Jazayeri MR, Shen YH, Troup PJ, Avitall B, et al. Use of intravenous esmolol to predict efficacy of oral beta-adrenergic blocker therapy in patients with neurocardiogenic syncope. J Am Coll Cardiol 1992;19:402–8.
crossref pmid
22. Ward CR, Gray JC, Gilroy JJ, Kenny RA. Midodrine: a role in the management of neurocardiogenic syncope. Heart 1998;79:45–9.
crossref pmid pmc
METRICS Graph View
  • 1 Web of Science
  • 1 Crossref
  • 1 Scopus
  • 7,296 View
  • 169 Download