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3/2023
vol. 98 Opis przypadku
Cough as a symptom of respiratory infection or a rare cardiological pathology in an infant
Anna Chanas
1
,
Klaudia Obsznajczyk
1
,
Beata Kucińska
1
,
Bożena Werner
1
Pediatr Pol 2023; 98 (3): 248-253
Data publikacji online: 2023/09/01
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INTRODUCTIONIn the pediatric population respiratory infections are the most common reason for seeking a pediatric consultation. In most cases, they appear to be benign infections and resolve after symptomatic treatment. In the case of therapy failure or when life threatening symptoms (e.g. severe dyspnea, cyanosis, dehydration) are present, patients should be referred to a hospital. When the patient’s condition does not improve with the standard treatment for infection, a heart pathology should be considered as the possible cause of cough, especially in cases with high level of N-terminal pro-brain natriuretic peptide (NT-proBNP).CASE REPORTA 10-week-old infant with body weight 5300 g, previously considered healthy (born at 40 weeks of gestation, Apgar score of 10 points, body weight 3220 g), was admitted to a general pediatric hospital because of dyspnea. According to the parents, the child presented symptoms such as cough and dyspnea for several days, with no fever. Also difficulties with feeding, sweating, anxiety and frequent crying were reported by the parents.Upon admission to the pediatric department his general condition was considered to be quite good with dyspnea being the leading sign and suspicion of respiratory tract infection (pneumonia) was established. Laboratory tests revealed the following: negative inflammatory markers (WBC 8.7×103/ul with normal peripheral blood smear, C-reactive protein within normal range), respiratory acidosis in capillary blood gasses (pH – 7.231, pCO2 – 41mm Hg, pO2 – 50 mm Hg) and a negative test for respiratory syncytial virus (RSV). Antibiotic (cefuroxime), nebulized ipratropium bromide and intravenous steroids were administered, but despite treatment the patient’s condition worsened: saturation dropped to 70% and respiratory acidosis became more severe (pH –7.098, pCO2 – 58 mm Hg, pO2 – 47 mm Hg). The chest X-ray performed on the first day of admission revealed cardiomegaly and bilateral parenchymal atelectasis changes with hyperinflation. Due to cardiomegaly and worsening of the clinical condition, a cardiological consultation was requested. Echocardiography (ECHO) revealed significant left ventricle dilation and severely diminished left ventricular (LV) systolic function, which are typical for dilated cardiomyopathy (DCM). The patient was transferred to the cardiology department. At the time of admission to the cardiology department the patient was in a poor general condition with signs of heart failure (HF) on physical examination: prolonged capillary refill time, tachycardia with a heart rate of 170 bpm, galop rhythm and a blood pressure of 55/35 mm Hg. Heart sounds were silent and a systolic murmur grade 2 on the Levine scale was best heard at the apex. Oxygen saturation was 90–92% on room air. Capillary blood gases revealed a pH value of 7.364, pCO2 – 46 mm Hg, pO2 – 54 mm Hg. He presented tachypnea and dyspnea (respiratory rate 70/min, intercostal retraction). Lung auscultation revealed bilateral crackles. The liver was enlarged, palpable 3 cm below the costal margin. The chest X-ray (Figure 1) revealed an increased cardiothoracic index (0.72) and haziness in the upper right and upper and middle left lobes, as well atelectasis in the lower right lobe and slight right sided pneumothorax. Twelve-lead electrocardiogram (ECG) (Figure 2) showed evidence of an infarction with the presence of deep Q-waves in leads representative for the left ventricle and raised the suspicion of coronary artery problem. Echocardiography showed LV enlargement (37 mm; Z-score + 4.95) (Figure 3), moderate mitral regurgitation and severely diminished LV systolic function with extremely low ejection fraction (EF) measured using the Simpson method – 10% (norm ≥ 55%). The origin of the coronary arteries was not evaluated in the first ECHO because of the child’s anxiety and lack of cooperation. Blood tests showed very high levels of NT-proBNP (> 25 000 pg/l, norm < 125 pg/ml) and troponin I (3100 ng/l, norm < 19 ng/l). Pharmacological treatment for HF was initiated with intravenous diuretics and a phosphodiesterase inhibitor. High-flow nasal cannula therapy initiated for respiratory support. Echocardiography was repeated and the origin of the left main coronary artery (LMCA) was not clearly visualized in the left Valsalva sinus, and retrograde blood flow through the pulmonary trunk during diastole as well as systolic and diastolic flow through the collateral circulation within the ventricular septum was present. Additionally, mild dilatation of the right coronary artery (RCA) was visualized. Based on these findings, anomalous origin of the LMCA from the pulmonary artery (ALCAPA) was suspected. This diagnosis was confirmed using computed tomography angiography (CT- angio). The patient was qualified for urgent cardiac surgery with extracorporeal circulation as a life-saving procedure. The anomalous left coronary artery was reimplanted in the aorta. There were no significant complications in the postoperative period. A gradual improvement of the patient’s condition, ECHO results and laboratory tests was observed. The left ventricle EF rose to 46% on the day of discharge from the hospital. The concentrations of NT-proBNP and troponin I decreased significantly (NT-proBNP > 25 000–4000 pg/l; troponin I 3100–59 ng/l), but were still elevated. The electrocardiogram showed changes indicating an evolution of LV myocardial infarction. The patient was discharged from the hospital 52 days after surgery with a recommendation to continue pharmacotherapy (carvedilol, captopril, spironolactone, digoxin, acetylsalicylic acid) for HF and regular check-ups. DISCUSSIONOur 10-week-old boy was brought to the general pediatric hospital with suspicion of respiratory tract infection due to persistent cough. Non-infectious causes of cough in children include foreign body aspiration, asthma, allergy, gastroesophageal reflux disease and HF, and should always be taken into consideration in the diagnostic work-up.Additional signs typical for lower respiratory tract infections include tachypnea, dyspnea, wheezes, and crepitations, which were almost all present in our patient. Tachycardia can also accompany lower respiratory tract infections and fever. Of note, those signs could also be present in any conditions leading to HF, such as congenital heart defects, especially coarctation of the aorta and aortic valve stenosis in the newborn period and/or infancy. Also in early infancy, non-cyanotic congenital heart defects with left to right shunts could be responsible for HF after pulmonary resistance decreases. Supraventricular tachycardia, being the most frequent symptomatic arrhythmia in children, as well myocarditis, could also lead to HF. The parents of our patient also reported difficulties with feeding. It is one of the most commonly reported symptoms of HF in infants, occurring together with poor weight gain. In infants and small children the Ross scale is used to assess HF severity. One of the parameters included is the volume of milk consumed during a single feeding, as well as feeding time. This scale also includes the assessment of pattern and frequency of breathing, the heart rate, the presence of a third heart sound, enlargement of the liver and the assessment of peripheral perfusion. In a child with left ventricle failure, apart from tachypnea and dyspnea, during lung auscultation we can hear crackling sounds and rales resulting from lung congestion. Of note, in small infants severe lung congestion could also compress the soft bronchi and bronchioles, and wheezing, typical mostly for obstructive bronchitis and asthma, could also be heard. Other symptoms of HF include tachycardia, gallop rhythm, sweaty skin, cold extremities, prolonged capillary refill and weak peripheral pulse, hypotension, hepatomegaly and peripheral edema. Tachycardia can accompany a fever and each 1ºC can raise the heart rate by about 10–15 bpm. Fever was not present in our infant, which should raise suspicion for a cause other than respiratory infection for the infant’s condition. Typical symptoms for right ventricle failure, such as hepatomegaly, were also present in our patient. During auscultation of our patient’s heart, we noted a soft systolic murmur at the apex with an intensity of grade 2 on the Levine scale. The murmur appeared as a consequence of LV and mitral valve annulus dilatation, which subsequently caused mitral regurgitation. Negative inflammatory markers did not support the infection theory of the presenting symptoms and signs in our infant. The evaluation for RSV infection was also negative. Very high levels of troponin and NT-proBNP were noted in our patient. Troponin I is a marker of cardiac ischemia. NT-proBNP levels correlate with the severity of HF. During the neonatal stage the norms of NT-proBNP and troponin levels are higher than in older children or adults. Moreover, what sometimes make diagnostics difficult, NT-proBNP (but generally not troponin) can be elevated not only in HF but also in severe respiratory tract infections in children with an anatomically healthy heart. However, the level of NT-proBNP is then lower than in HF cases. According to available studies reviewed by Edwards et al. [1], in a group of 1000 children with bronchiolitis the median NT-proBNP level was 241 pg/ml, whereas in children with cardiac failure it was above 7321 pg/ml. In our patient NT-proBNP was above 25 000 pg/ml, which strongly suggested a cardiological cause of the symptoms. In the present case, heart enlargement with a cardio-thoracic index of 0.72 was described in the chest X-ray. The cardio-thoracic index is the quotient of the maximum size of the heart and the chest. Its normal value in newborns is about 0.6 (resulting from a more horizontal position of the heart in the chest) and it decreases with age to 0.5 due to a more vertical orientation of the heart [2]. An increased cardio-thoracic index value with signs of HF raised suspicion of a heart problem as a major cause in our patient. The causes of cardiomegaly in children include, for example, congenital heart defects, myocarditis, pericarditis, cardiomyopathies, long episodes of arrhythmia, and severe arterial hypertension. In a study by Zheng et al.[3] summarizing the experiences of patients with ALPACA, the most common findings in chest X-rays were cardiomegaly, pulmonary trunk dilatation, as well pulmonary edema in younger children. The standard ECG in our patient showed ST elevation in leads V5 and V6, consistent with coronary ischemia, and pathologic Q-waves in leads I, aVR, V5, and V6 – typical for myocardial infarction. Typical ECG changes due to anterolateral myocardial infarction include abnormal Q-wave, ST segment changes and T-wave inversion [4–6]. According to data from the literature, about 20–45% of patients with ALCAPA do not show an abnormal Q-wave in ECG and the only change is abnormal progression of R-waves in chest leads [3]. Echocardiography is the basic examination used in the diagnosis of heart pathology. In our patient transthoracic ECHO showed severely impaired LV systolic function with extremely low EF (10%) and LV dilatation, consistent with the diagnosis of DCM. Dilated cardiomyopathy is characterized by LV dilatation and dysfunction, resulting in diminished cardiac output and secondary congestive HF. It is the most common cardiomyopathy, comprising 50–60% of children with cardiomyopathy. In our patient transthoracic ECHO raised the suspicion of coronary abnormality as a cause of DCM. In an anatomically healthy child the right and left coronary arteries should arise from the right and left coronary sinus of Valsalva, respectively [7]. In ALCAPA, which is the most common variation of abnormal coronary origin in children, the LMCA arises from the pulmonary artery and in postnatal life is perfused with unoxygenated blood. During fetal life this anomaly is well tolerated as blood in the pulmonary trunk is well saturated, and is at a high pressure [8]. After birth, blood in the pulmonary artery becomes desaturated and its pressure decreases, while the left ventricle’s oxygen demand is steadily increasing. This disproportion starts to be symptomatic at about 2–3 months of life when the myocardium becomes ischemic, initially causing nonspecific signs and symptoms that may be mistaken for a respiratory infection [9]. The identification of the origin of the left coronary artery in ECHO can be challenging; one can sometimes even falsely visualize the wrong origin of the LCA when its course is close to the proper ostium. In such situations aortography is used to confirm the diagnosis [10]. Visualization of abnormal diastolic flow in the pulmonary artery in ECHO and a dilated RCA with collateral circulation between the right and left coronary artery in the ventricular septum, with signs of DCM, can also be useful to establish diagnosis of ALCAPA [10, 11]. The diastolic flow in the pulmonary artery is caused by higher blood pressure in the right than in the left coronary artery and pulmonary trunk. The pressure gradient results in blood flow from the right to the left coronary artery collateral circulation and further to the pulmonary artery. Currently, the gold standard for confirmation of ALCAPA is angio-CT [11]. According to a study by Roik et al. [12], in a group of 110 neonates and infants with congenital heart diseases, the orifices of the left coronary artery were visible in 100% of the performed angio-CT scans. In the present case, the symptoms worsened at 3 months of age, masked by a respiratory presentation. The lack of improvement after standard therapy for infection and results of specific cardiac tests led to the final diagnosis. Disturbing symptoms reported by parents may also include excessive crying mistakenly associated with an intestinal colic pain. In a study describing 3 cases of ALCAPA by Ma et al. [13], the reason for hospitalization was symptoms of respiratory infections, as in our case. The course of ALCAPA is more severe in infants. As in the present case, the symptoms of HF resulting from impaired LV systolic function are the most common and require pharmacological treatment. Our patient, prior to the operation, received an intravenous infusion of milrinone and furosemide. Usually, drugs that improve contractility of the heart muscle with the addition of loop diuretics are the first-line drugs in the treatment of acute HF. In chronic conditions the pillars of HF management are angiotensin-converting enzyme inhibitors responsible for reducing afterload (e.g. captopril, enalapril), β-blockers (e.g. metoprolol, carvedilol) and aldosterone antagonists (e.g. spironolactone). Each of these agents works through a different arm of the sympathetic nervous system or renin-angiotensin-aldosterone axis. β-blockers, by reducing the heart rate, also lower the heart’s need for oxygen. Moreover, by prolonging the diastolic phase, they improve the blood supply to the heart muscle. Because of its effect on lowering blood pressure it is important to ensure that the child is properly hydrated. Chronic HF management in children also includes thiazides and loop diuretics to achieve a euvolemic state. Digoxin, which was previously used more widely, has now been advised to be used at low doses in symptomatic, rather than asymptomatic, LV dysfunction. The disadvantage of digoxin is a narrow spectrum between the therapeutic and toxic doses. In the course of differential diagnosis of DCM, other causes of LV enlargement and/or impaired contractility should be considered, and examples are given in Table 1. Diagnosis of ALCAPA is an indication for cardiosurgical treatment and should be done as soon as possible. It involves the excision and reimplantation of the anomalous coronary artery from the pulmonary artery into the aorta [14, 15]. The results of surgical repair are usually good, and the median normalization time of LV function is about 6 months. Postoperative complications may occur and mainly include coronary artery stenosis. In a study by Gao et al. [14] the early mortality rate was 7.7% and the late mortality rate was 3.8%, resulting from end-stage HF and arrhythmia. Patients after treatment require lifelong cardiological follow-up [16]. CONCLUSIONSAlthough ALCAPA is a very rare congenital anomaly, it should be taken into consideration as a differential diagnosis in children with symptoms such as cough and dyspnea, mainly typical for respiratory infection, but also for LV failure. Immediate selection for cardiac surgery significantly improves the prognosis.DISCLOSUREThe authors declare no conflict of interest.REFERENCES1. Edwards KD, Tighe MP. How to use N-terminal pro-brain natriuretic peptide (NT-proBNP) in assessing disease severity in bronchiolitis. Arch Dis Child Educ Pract Ed 2020; 105: 282-288. 2.
Aleszewicz-Baranowska J, Komorowska W. Podstawy diagnostyki kardiologicznej u dzieci. Forum Med Rodz 2007; 1: 242-249. 3.
Zheng J, Ding W, Xiao Y, et al. Anomalous origin of the left coronary artery from the pulmonary artery in children: 15 years experience. Pediatr Cardiol 2011; 32: 24-31. 4.
Hoffman JI. Electrocardiogram of anomalous left coronary artery from the pulmonary artery in infants. Pediatr Cardiol 2013; 34: 489-491. 5.
Amaral ME, Epifânio P, Noronha N, et al. Unusual cause of left ventricular dysfunction in a child. Rev Port Cardiol 2019; 38: 159.e1-159.e5. 6.
Rodriguez-Gonzalez M, Tirado A, Hosseinpour R, et al. Anomalous origin of the left coronary artery from the pulmonary artery: diagnoses and surgical results in 12 pediatric patients. Tex Heart Inst J 2015; 42: 350-356. 7.
Jiang GP, Wang HF, Gong FQ, et al. Diagnostic value of parasternal pulmonary artery short‑axis view for the anomalous origin of the left coronary artery from the pulmonary artery. J Cardiol 2014; 63: 444‑448. 8.
Lee AC, Foster E, Yeghiazarians Y. Anomalous origin of the left coronary artery from the pulmonary artery: a case series and brief review. Congenital Heart Dis 2017; 1: 111-115. 9.
Muzaffar T, Ahmad Ganie F, Gpoal Swamy S, et al. The surgical outcome of anomalous origin of the left coronary artery from the pulmonary artery. Int Cardiovasc Res J 2014; 8: 57-60. 10.
Wesselhoeft H, Fawcett JS, Johnson AL. Anomalous origin of the left coronary artery from the pulmonary trunk. Its clinical spectrum, pathology, and pathophysiology, based on a review of 140 cases with seven further cases. Circulation 1968; 38: 403-425. 11.
Han BK, Rigsby CK, Hlavacek A, et al. Computed tomography imaging in patients with congenital heart disease part 1: rationale and utility. An expert consensus document of the Society of Cardiovascular Computed Tomography. J Cardiovasc Comput Tomogr 2015; 9: 475-492. 12.
Roik D, Kucińska B, Roik M, et al. Image quality and radiation doses of volumetric 320-row computed tomography angiography with prospective electrocardiogram-gating in the assessment of coronary arteries in neonates and infants. Kardiol Pol 2022; 4: 567-574. 13.
Ma F, Zhou K, Shi X, et al. Misdiagnosed anomalous left coronary artery from the pulmonary artery as endocardial fibroelastosis in infancy. Medicine 2017; 96: e7199. 14.
Gao Y, Zhang J, Huang GY, et al. Surgical outcomes of anomalous origin of the left coronary artery from the pulmonary artery in children: an echocardiography follow-up. Chin Med J 2017; 130: 2333-2338. 15.
Dehaki MG, Al-Dairy A, Rezaei Y, et al. Mid-term outcomes of surgical repair for anomalous origin of the left coronary artery from the pulmonary artery: in infants, children and adults. Ann Pediatr Cardiol 2017; 10: 137-143. 16.
Zhang HL, Li SJ, Wang X, et al. Preoperative evaluation and midterm outcomes after the surgical correction of anomalous origin of the left coronary artery from the pulmonary artery in 50 infants and children. Chin Med J (Engl) 2017; 130: 2816-2822.
Copyright: © 2023 Polish Society of Paediatrics. This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License (http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
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