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CARDIOLOGIST IN YELAHANKA SECOND DEGREE AV BLICK There are two basic types of second-degree AV block: AV nodal Möbitz type I (Wenckebach) heart block, and the more distal and more sinister Möbitz type II heart block. Möbitz type I heart block is much more common. In Möbitz type I block the PR interval lengthens progressively with each cardiac cycle, until an atrial wave is not conducted. There is recovery of conduction and the next a wave is conducted with a shorter interval and the cycle begins again. The QRS complex is narrow (Fig 3.10) (unless associated with pre-existing BBB). The increment is largest between the first and second conducted P wave, and the PR interval continues to increase by less and less until a P wave is dropped. Möbitz type II heart block is almost always associated with a BBB (Fig 3.11), since its origin is intraventricular (below the AV node), and it tends to lapse suddenly into extreme bradycardia or asystole. It tends to be over-diagnosed, especially in the setting of 2:1 AV block (Fig 3.12). There is no lengthening of the PR interval before an atrial wave is not conducted. At times, atropine or exercise can demonstrate the site of the block, by increasing the block from 2:1 to a higher grade when the underlying mechanism is Möbitz II. Conversely, Wenckebach conduction may improve to 3:2 or better. For a distinction to be made between Möbitz type I and Möbitz type II, at least two consecutively conducted P waves have to be evaluated. This is impossible in 2:1 conduction (block) and can only be reported as 2:1 AV block (Fig 3.12). Yet this is very commonly reported as
THE BEST CARDIOLOGISTS IN YELAHANKA Second-degree AV block There are two basic types of second-degree AV block: AV nodal Möbitz type I heart block, and the more distal and more sinister Möbitz type II heart block. Möbitz type I heart block is much more common. In Möbitz type I block the PR interval lengthens progressively with each cardiac cycle, until an atrial wave is not conducted. There is recovery of conduction and the next a wave is conducted with a shorter interval and the cycle begins again. The QRS complex is narrow (unless associated with pre-existing BBB). The increment is largest between the first and second conducted P wave, and the PR interval continues to increase by less and less until a P wave is dropped. Möbitz type II heart block is almost always associated with a BBB , since its origin is intraventricular (below the AV node), and it tends to lapse suddenly into extreme bradycardia or asystole. It tends to be over-diagnosed, especially in the setting of 2:1 AV block . There is no lengthening of the PR interval before an atrial wave is not conducted. At times, atropine or exercise can demonstrate the site of the block, by increasing the block from 2:1 to a higher grade when the underlying mechanism is Möbitz II. Conversely, Wenckebach conduction may improve to 3:2 or better. For a distinction to be made between Möbitz type I and Möbitz type II, at least two consecutively conducted P waves have to be evaluated. This is impossible in 2:1 conduction (block) and can only be reported as 2:1 AV block (Fig 3.12). Yet this is very commonly reported as Möbitz type
POPULAR CARDIOLOGIST IN AMRUTHA HALLI , BANGALORE Assessment of patients with hypertension A patient with definite or possible newly diagnosed hypertension needs at least a basic clinical assessment to look for possible aetiology, severity and signs of complications. The history Questioning should be directed towards the following areas. 1 Past history. Has hypertension been diagnosed before? What treatment was instituted? Why was it stopped? 2 Secondary causes. Important questions relate to: • a history of renal disease in the patient or his or her family, recurrent urinary tract infec-­ tions, heavy analgesic use or conditions leading to renal disease (e.g. systemic lupus erythematosus (SLE)) • symptoms suggesting phaeochromocytoma (flushing, sweats, palpitations) • symptoms suggesting sleep apnoea • muscle weakness suggesting the hypokalaemia of hyperaldosteronism • Cushing’s syndrome (weight gain, skin changes) • family history of hypertension. 3 Aggravating factors: • high salt intake • high alcohol intake • lack of exercise • use of medications: NSAIDs, appetite suppressants, nasal decongestants, monoamine oxidase inhibitors, ergotamine, cyclosporin, oestrogen-containing contraceptive pills • other: use of cocaine, liquorice, amphetamines. 4 Target organ damage: • stroke or transient ischaemic attack (TIA) • angina, dyspnoea • fatigue, oliguria • visual disturbance • claudication. 5 Coexisting risk factors: • smoking • diabetes • lipid levels, if known
POPULAR CARDIOLOGIST IN KATTIGENAHALLI, BANGALORE Cyanotic congenital heart disease Some of the more common cyanotic lesions are discussed below. There are, however, a number of problems common to patients with cyanotic heart disease. 1 Erythrocytosis. Chronic cyanosis causes an increase in red cell numbers as a way of increasing oxygen carrying capacity. The platelet count is sometimes reduced and the white cell count normal. The increased blood viscosity associated with the high red cell mass causes a slight increase in the risk of stroke.37 Most patients have a stable elevated haemoglobin level, but venesection is recommended if this is greater than 20 g/dL and the haematocrit is greater than 65%. Levels as high as this can be associated with the hyperviscosity syndrome: headache, fatigue and difficulty concentrating. Recurrent venesection can cause iron depletion and the production of microcytic red cells, which are stiffer than normal cells and so increase viscosity further. 2 Bleeding. Reduced platelet numbers, abnormal platelet function and clotting factor deficiencies mean these patients have an increased risk of haemorrhage. The most dangerous problem is pulmonary haemorrhage but bleeding from the gums and menorrhagia are more common. The use of anticoagulation must be restricted to those with a strong indication for treatment. 3 Gallstones. Chronic cyanosis and increased haem turnover are associated with an increased incidence of pigment gallstones. 4 Renal dysfunction and gout. Congestion of the renal glomeruli is associated with a reduced glomerular filtration rate and proteinuria. This and the increased turnover of red cells lead to urate accumulation and gout. 5 Pulmonary hypertension. Lesions associated with increased flow through the pulmonary circulation (e.g. a large atrial septal defect) can lead to a reactive rise in pulmonary arterial resistance. This is more likely to occur if the left to right shunt is large. Eventually these pulmonary vascular changes become irreversible, pulmonary pressures equal or exceed systemic pressures, and central cyanosis occurs because the intra-cardiac shunt reverses (Eisenmenger’s syndrome). Flow is now from right to left. There is then no benefit in attempting to correct the underlying cardiac abnormality. Earlier and more successful treatment of children with congenital heart disease has reduced the number of patients with this inexorable disease. Careful management of these conditions can nevertheless improve patients’ symptoms and survival. Reasonable exercise tolerance is usually maintained into adult life for most patients but progressive deterioration then occurs. Haemorrhagic complications, especially haemoptysis, are common. Thrombotic stroke, cerebral abscess and pulmonary infarction can also occur.
CARDIOLOGISTS IN H S R LAYOUT BANGALORE Cyanotic congenital heart disease Some of the more common cyanotic lesions are discussed below. There are, however, a number of problems common to patients with cyanotic heart disease. 1 Erythrocytosis. Chronic cyanosis causes an increase in red cell numbers as a way of increasing oxygen carrying capacity. The platelet count is sometimes reduced and the white cell count normal. The increased blood viscosity associated with the high red cell mass causes a slight increase in the risk of stroke.37 Most patients have a stable elevated haemoglobin level, but venesection is recommended if this is greater than 20 g/dL and the haematocrit is greater than 65%. Levels as high as this can be associated with the hyperviscosity syndrome: headache, fatigue and difficulty concentrating. Recurrent venesection can cause iron depletion and the production of microcytic red cells, which are stiffer than normal cells and so increase viscosity further. 2 Bleeding. Reduced platelet numbers, abnormal platelet function and clotting factor deficiencies mean these patients have an increased risk of haemorrhage. The most dangerous problem is pulmonary haemorrhage but bleeding from the gums and menorrhagia are more common. The use of anticoagulation must be restricted to those with a strong indication for treatment. 3 Gallstones. Chronic cyanosis and increased haem turnover are associated with an increased incidence of pigment gallstones. 4 Renal dysfunction and gout. Congestion of the renal glomeruli is associated with a reduced glomerular filtration rate and proteinuria. This and the increased turnover of red cells lead to urate accumulation and gout. 5 Pulmonary hypertension. Lesions associated with increased flow through the pulmonary circulation (e.g. a large atrial septal defect) can lead to a reactive rise in pulmonary arterial resistance. This is more likely to occur if the left to right shunt is large. Eventually these pulmonary vascular changes become irreversible, pulmonary pressures equal or exceed systemic pressures, and central cyanosis occurs because the intra-cardiac shunt reverses (Eisenmenger’s syndrome). Flow is now from right to left. There is then no benefit in attempting to correct the underlying cardiac abnormality. Earlier and more successful treatment of children with congenital heart disease has reduced the number of patients with this inexorable disease. Careful management of these conditions can nevertheless improve patients’ symptoms and survival. Reasonable exercise tolerance is usually maintained into adult life for most patients but progressive deterioration then occurs. Haemorrhagic complications, especially haemoptysis, are common. Thrombotic stroke, cerebral abscess and pulmonary infarction can also occur. 364 PRACTICAL CARDIOLOGY In a recent European survey, survival for patients with simple defects and Eisenmenger’s was to 32.5 years, but only 25.8 years for those with Eisenmenger’s resulting from complex abnormalities.38 There is a 50% maternal mortality risk with pregnancy. Quite minor surgical procedures are associated with high risk. Trials with endothelin antagonists are being conducted and continuous oxygen treatment can provide symptomatic relief. Lung and heart lung transplant should be considered for some of these patients. 6 Endocarditis. Most patients with congenital heart disease have a lifelong risk of infective endocarditis. Constant reminders of this risk should be given to the patients and their usual doctors. As well as appropriate antibiotic prophylaxis . before procedures, a high index of suspicion is very important. A febrile illness should not be treated with antibiotics until at least two sets of blood cultures have been taken. Early referral
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