18-Month-Old with Lethargy and Accelerated Idioventricular Rhythm in Prehospital Setting: A Case Report.

INTRODUCTION: We report a case of accelerated idioventricular rhythm (AIVR) identified by Emergency Medical Services (EMS) monitoring of an infant presenting with lethargy and respiratory distress. Accelerated idioventricular rhythms are rare ventricular rhythms originating from the His-Purkinje system or ventricular myocytes, consisting of >3 monomorphic beats with gradual onset and termination.1 An AIVR is usually well-tolerated and does not require treatment, though sustained arrythmia may induce syncope, and the rhythm has been seen in newborn infants with congenital heart diseases.1 Monitoring ill children with ECG can identify such dysrhythmias in the prehospital setting. CASE REPORT: An 18-month-old male presented to their pediatrician with lethargy and respiratory distress, prompting activation of EMS. The patient was placed on a 4-lead ECG initially revealing monomorphic QRS complexes at a rate of 170 beats per minute (BPM). A 12-lead ECG was interpreted as sinus tachycardia by the paramedics who noted the QRS complexes were "getting taller and shorter" with a stable rapid heart rate. The clinician then noted a consistently wide tachycardia which spontaneously converted to a narrow complex tachycardia. The QRS pattern remained variable, with notation of variable R-wave height. After arrival to the emergency department, pediatric cardiology was consulted and interpreted the prehospital ECG findings as accelerated idioventricular rhythm. The patient experienced multiple occurrences of accelerated idioventricular rhythm during hospitalization without associated hypoxia or decreased perfusion. DISCUSSION: Accelerated idioventricular rhythm is relatively rare entity without underlying cardiac disease and most cases are asymptomatic or benign. In the pediatric population, AIVR is generally related to congenital heart defects, cardiac tumors, and cardiomyopathies. In the prehospital setting, continuous ECG monitoring should be a part of care by Advanced Life Support personnel in children with altered mental status, respiratory distress, unexplained syncope, or suspected arrhythmias and 12 lead ECG should be considered if there is any abnormality noted. While this patient did not experience persisting morbidity from AIVR, the potentially hazardous rhythm would not have been recognized without the astute observation, clinical management and persistent follow up of the prehospital clinicians.

Medium-Term Outcomes in Pediatric Patients Undergoing Cardiac Catheterization Early After Congenital Cardiac Surgery.

Safety and acute outcomes for patients who need catheterization shortly after congenital cardiac surgery has been established; literature on mid-term outcomes is lacking. We sought to evaluate the mid-term outcomes of patients who undergo early postoperative cardiac catheterization. This is a retrospective cohort study of patients who underwent cardiac catheterization within 6 weeks of congenital cardiac surgery with longitudinal follow-up and assessment of mid-term outcomes. Multivariable analysis was utilized to relate variables of interest to outcomes. 99 patients underwent cardiac catheterizations within 6 weeks of cardiac surgery between January 2008 and September 2016. Forty-six (45.5%) interventional procedures were performed at a median age of 41 days (IQR 21-192) and a median weight of 3.9 kg (3.3-6.6). During a median follow-up duration of 4.24 years (1.6-5.6) in study survivors, 61% of patients remained free from the primary endpoint (death and/or transplant). Sixty-nine patients (69.7%) underwent an unplanned surgical or catheter procedure. Renal failure at catheterization (OR 280.5, p 0.0199), inotropic medication at catheterization (OR 14.8, p 0.002), and younger age were all significantly associated with meeting the primary endpoint. Patients requiring surgical intervention as an initial additional intervention underwent more unplanned re-interventions, while patients who survived to hospital discharge demonstrated favorable mortality, though with frequent need for re-intervention. In patients requiring early postoperative cardiac catheterization, renal failure, younger age, and need for inotropic support at catheterization are significantly associated with meeting the primary endpoint.

Upper-Extremity Venous Access for Children and Adults in Pediatric Cardiac Catheterization Laboratory.

BACKGROUND: Traditional approaches to pediatric cardiac catheterization have relied on femoral venous access. Upper- extremity venous access may enable cardiac catheterization procedures to be performed safely for diagnostic and interventional catheterizations. The objective of this multicenter study was to demonstrate the feasibility and safety of upper-extremity venous access in a pediatric cardiac catheterization laboratory. METHODS: A retrospective chart review of all patients who underwent cardiac catheterization via upper-extremity vascular access was performed. RESULTS: Eighty-two cardiac catheterizations were attempted via upper-extremity vein on 72 patients. Successful access was obtained in 75 catheterizations (91%) in 67 patients. Median age at catheterization was 18.79 years (interquartile range [IQR], 13.02-32.75 years; n = 75) with a median weight of 59.4 kg (IQR, 43.3-76.5 kg; n = 75). The youngest patient was 4.1 months old, weighing 4.3 kg. Local anesthesia or light sedation was utilized in 46 procedures (61%). Diagnostic right heart catheterization was the most common procedure (n = 65; 87%), with intervention performed via the upper extremity in 8 cases (11%). Median fluoroscopy time was 10.02 min (IQR, 2.87-36.26 min; n = 75), with dose area product/kg of 3.765 µGy•m²/kg (IQR, 0.74-34.12 µGy•m²/kg; n = 64). Median sheath duration time was 48 min (IQR, 19.5-147 min; n = 57) and median total procedure time was 116 min (IQR, 80.5-299 min; n = 65). Median length of stay for outpatient procedures was 5.37 hr (IQR, 4.25-6.92 hr; n = 27). There were no procedural complications. CONCLUSION: Upper-extremity venous access is a useful, feasible, and safe modality for cardiac catheterization in the pediatric cardiac catheterization laboratory.

Novel direct approach for placement of permanent transvenous pacing leads after Fontan procedure.

The need for transvenous pacing (patients who have exhausted epicardial options) after a Fontan-type operation has been recognized. Many novel strategies have been proposed, but currently, all of them require additional maneuvers or rerouting of the leads to the pacemaker pocket. In this report, we describe a novel direct approach to transvenous pacing after a Fontan-type operation from a standard, prepectoral approach.

Carotid body size measured by computed tomographic angiography in individuals born prematurely.

PURPOSE: We tested the hypothesis that the carotid bodies would be smaller in individuals born prematurely or exposed to perinatal oxygen therapy when compared individuals born full term that did not receive oxygen therapy. METHODS: A retrospective chart review was conducted on patients who underwent head/neck computed tomography angiography (CTA) at the Mayo Clinic between 10 and 40 years of age (n = 2503). Patients were identified as premature ( < 38 weeks) or receiving perinatal oxygen therapy by physician completion or billing codes (n = 16 premature and n = 7 receiving oxygen). Widest axial measurements of the carotid body images captured during the CTA were performed. RESULTS: Carotid body visualization was possible in 43% of patients and 52% of age, sex, and body mass index (BMI)-matched controls but only 17% of juvenile preterm subjects (p = .07). Of the carotid bodies that could be visualized, widest axial measurements of the carotid bodies in individuals born prematurely (n = 7, 34 ±â€¯4 weeks gestation, birth weight: 2460 ±â€¯454 g; average size: 2.5 ±â€¯0.2 cm) or individuals exposed to perinatal oxygen therapy (n = 3, 38 ±â€¯2 weeks gestation, Average size: 2.2 ±â€¯0.1 cm) were not different when compared to controls (2.3 ±â€¯0.2 cm and 2.3 ±â€¯0.2 cm, respectively, p > 0.05). CONCLUSIONS: Carotid body size, as measured using CTA, is not smaller in adults born prematurely or exposed to perinatal oxygen therapy when compared to sex, age, and BMI-matched controls. However, carotid body visualization was lower in juvenile premature patients. The decreased ability to visualize the carotid bodies in these individuals may be a result of their prematurity.