Diagnosis of Congenital Heart Disease in the First Two Weeks of Life

The differential diagnosis of congenital heart disease which presents cyanosis or respiratory distress, or both, in the first two weeks of life, is difficult. Close correlation of clinical features, electrocardiogram and chest roentgenogram is most helpful. The diagnosis of congenital heart disease should lead to immediate cardiac catheterization, angiocardiography and appropriate therapy.     

The Acid-Base Status in Cyanotic Congenital Heart Disease

The relation between oxygen consumption, metabolic status and prognosis was studied in two infants with identically low arterial oxygen tensions (20 mm. Hg) due to cyanotic congenital heart disease. The first patient had low oxygen consumption, arterial blood acidosis and increased arterial lactate, and died at the age of 36 hours. The second had normal oxygen consumption, arterial acid-base balance, lactate and pyruvate, and survived. Since arterial oxygen tensions were similar in both, it was concluded that compensatory factors, such as cardiac output, pulmonary and systemic blood flow and increased oxygen saturation at normal pH levels (Bohr effect), are important in maintaining tissue oxidation and preventing anaerobiosis and lactate production. The importance of a knowledge of acid-base status in the immediate prognosis of cyanotic congenital heart disease is stressed. The treatment of acidosis by buffer therapy may be an important palliative, improving cardiac output and tissue oxidation, and should be undertaken as soon as possible before irreversible cellular damage has occurred.     

Ischemic Heart Disease: Precarious Coronary Lesions and Prognosis

Coronary arteriograms in 113 patients whose cases were followed for 2 to 12 years were analyzed in an attempt to discover why in some patients with angina pectoris there are long stable clinical courses and in others the courses proceed rapidly to death. It was found that patients with completed coronary occlusions, usually with distal portions reconstituted by collateral, had favorable prognoses with prolonged longevity. Patients with multiple high grade narrowings of the coronary arteries, on the other hand, had poor prognoses with high attrition rates. The more stenotic lesions present in the coronary arteries, the higher the attrition rates. Completed coronary occlusions, therefore, have been classified as nonprecarious while local coronary stenoses greater than 50 percent of the lumen diameter have been classified as degrees of precariousness according to the number of lesions present.When compared with classification by number of diseased vessels and by arteriographic score of Friesinger, the nonprecarious cases had better prognoses than the precarious.     

Implantation of Total Artificial Heart in Congenital Heart Disease

In patients with end-stage heart failure (HF), a total artificial heart (TAH) may be implanted as a bridge to cardiac transplant. However, in congenital heart disease (CHD), the malformed heart presents a challenge to TAH implantation. In the case presented here, a 17 year-old patient with congenital transposition of the great arteries (CCTGA) experienced progressively worsening HF due to his congenital condition. He was hospitalized multiple times and received an implantable cardioverter defibrillator (ICD). However, his condition soon deteriorated to end-stage HF with multisystem organ failure. Due to the patient''s grave clinical condition and the presence of complex cardiac lesions, the decision was made to proceed with a TAH. The abnormal arrangement of the patient''s ventricles and great arteries required modifications to the TAH during implantation.With the TAH in place, the patient was able to return home and regain strength and physical well-being while awaiting a donor heart. He was successfully bridged to heart transplantation 5 months after receiving the device. This report highlights the TAH is feasible even in patients with structurally abnormal hearts, with technical modification.     

Genetics of Congenital Heart Disease: Past and Present

Congenital heart disease is the most common congenital anomaly, representing an important cause of infant morbidity and mortality. Congenital heart disease represents a group of heart anomalies that include septal defects, valve defects, and outflow tract anomalies. The exact genetic, epigenetic, or environmental basis of congenital heart disease remains poorly understood, although the exact mechanism is likely multifactorial. However, the development of new technologies including copy number variants, single-nucleotide polymorphism, next-generation sequencing are accelerating the detection of genetic causes of heart anomalies. Recent studies suggest a role of small non-coding RNAs, micro RNA, in congenital heart disease. The recently described epigenetic factors have also been found to contribute to cardiac morphogenesis. In this review, we present past and recent genetic discoveries in congenital heart disease.