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best cardiologists in bangalore Murmurs Murmurs are produced by turbulent blood flow, and are described according to their location, intensity, timing, frequency, and radiation (Tables 15.1 to 15.3 and Figure 15.1). Innocent murmurs are due to pulmonary flow and can be heard in children, pregnancy, and high-flow states, such as hyperthyroidism and anaemia. They are heard over the left sternal edge and are ejection systolic, and there are no added sounds or thrill. The cervical venous hum is a continuous murmur, common in children and typically reduced by turning the head laterally or bending the elbows back. The mammary soufflé is a continuous murmur that may be heard in pregnancy. Dynamic auscultation manoeuvres may help bedside diagnosis of systolic murmurs (Table 15.2). 4, 5 Murmurs originating within the right-sided chambers of the heart can be differentiated from all other murmurs by augmentation of their intensity with inspiration and diminution with expiration. The murmur of hypertrophic cardiomyopathy is distinguished from all other systolic murmurs by an increase in intensity with the Valsalva manoeuvre and during squatting-to-standing, and by a decrease in intensity during standing-to-squatting action, passive leg elevation, and handgrip. The murmurs of MR and VSD have similar responses but can be differentiated from other systolic murmurs by augmentation of their intensity with handgrip and during transient arterial occlusion.
THE BEST CARDIOLOGISTS IN YELAHANKA Aortic regurgitation The incompetent aortic valve allows regurgitation of blood from the aorta to the left ventricle during diastole for as long as the aortic diastolic pressure exceeds the left ventricular diastolic pressure. Symptoms: Occur in the late stages of disease and include exertional dyspnoea, fatigue, palpitations (hyperdynamic circulation) and exertional angina. General signs: Marfan’s syndrome may be obvious. The pulse and blood pressure: The pulse is characteristically collapsing; there may be a wide pulse pressure. The neck: Prominent carotid pulsations (Corrigan’s sign). Palpation: The apex beat is characteristically displaced and hyperkinetic. A diastolic thrill may be felt at the left sternal edge when the patient sits up and breathes out. Auscultation): A2 (the aortic component of the second heart sound) may be soft; a decrescendo high-pitched diastolic murmur beginning immediately after the second heart sound and extending for a variable time into diastole—it is loudest at the third and fourth left intercostal spaces; a systolic ejection murmur is usually present (due to associated aortic stenosis or to torrential flow across a normal diameter aortic valve). Signs indicating severe chronic aortic regurgitation: Collapsing pulse; wide pulse pressure; long decrescendo diastolic murmur; left ventricular S3 (third heart sound); soft A2; signs of left ventricular failure. Causes of chronic aortic regurgitation: (i) Rheumatic (rarely the only murmur in this case), congenital; (ii) aortic root dilatation—Marfan’s syndrome, dissecting aneurysm. 8• THE PATIENT WITH A MURMUR 305 a b Valve cusps often thickened and calcified Left ventricle may be hypertrophied Ascending aorta may be dilated Systole Diastole S1 A2 P2 S1 Ejection click (Suggests congenital AS) Normal Mild S1 S1 Moderate S1 P2 A2 S1 Severe Reversed S2 Single (S2)
THE BEST CARDIOLOGIST IN YELAHANKA Mitral regurgitation A regurgitant mitral valve allows part of the left ventricular stroke volume to regurgitate into the left atrium, imposing a volume load on both the left atrium and the left ventricle. Symptoms: Dyspnoea (increased left atrial pressure); fatigue (decreased cardiac output). General signs: Tachypnoea. The pulse: Normal, or sharp upstroke due to rapid left ventricular decompression; atrial fibrillation is relatively common. Palpation: The apex beat may be displaced, diffuse and hyperdynamic if left ventricular enlargement has occurred; a pansystolic thrill may be present at the apex; a parasternal impulse (due to left atrial enlargement behind the right ventricle—the left atrium is often larger in mitral regurgitation than in mitral stenosis and can be enormous). All these signs suggest severe mitral regurgitation. Auscultation Soft or absent S1 (by the end of diastole, atrial and ventricular pressures have equalised and the valve cusps have drifted back together); left ventricular S3, due to rapid left ventricular filling in early diastole; pansystolic murmur maximal at the apex and usually radiating towards the axilla. Causes of chronic mitral regurgitation: (i) Degenerative; (ii) rheumatic; (iii) mitral valve prolapse; (iv) papillary muscle dysfunction, due to left ventricular failure or ischaemia. Mitral valve prolapse (systolic-click murmur syndrome) This syndrome can cause a systolic murmur or click, or both, at the apex. The presence of the murmur indicates that there is some mitral regurgitation present. Auscultation: Systolic click or clicks at a variable time (usually mid-systolic) may be the only abnormality audible, but a click is not always audible; systolic
THE BEST CARDIOLOGISTS NEAR HSR LAYOUT Coronary angiography (cardiac catheterisation) This procedure enables the cardiologist to visualise the coronary arteries . It is the standard against which other less-invasive investigations are assessed. Selective catheterisation of the right and left coronary ostia is performed. Contrast is then injected into the vessels and digital tape or disc storage of the images obtained. In most hospitals the patient is admitted on the morning of the test and allowed to go home that afternoon. The procedure is most often performed through the femoral artery (Judkins technique) . This artery can be punctured through the skin under local anaesthetic. A fine softtipped guide wire is then advanced into the artery and the needle withdrawn (Seldinger method). A short guiding sheath can then be placed over the wire and long cardiac catheters advanced through this sheath along a long guide wire into the femoral artery and up via the aorta to the aortic arch. The catheter and wire are advanced under X-ray control. Usually one catheter with a curved tip (pig-tail catheter; is advanced across the aortic valve into the left ventricle where left ventricular pressures are measured via a pressure transducer connected to the other end of the catheter. Measurement of the left ventricular end-diastolic pressure gives an indication of left ventricular function. Raised end-diastolic pressure (over 15 mmHg) suggests left ventricular dysfunction . The catheter is then connected to a pressure injector. This enables injection of a large volume of contrast over a few seconds; for example, 35 mL at 15 mL/second. X-ray recording during injection produces a left ventriculogram , Here left ventricular contraction can be assessed and the ejection fraction (percentage of end-diastolic volume ejected with each systole) estimated. The normal is 60% or more. The figure obtained by this method tends to be higher than that produced by the nuclear imaging method—gated blood pool scanning. The guide wire is reintroduced and the catheter withdrawn to be replaced by one shaped to fit into the right or left coronary orifice...
CADIOLOGISTS IN VIDHYARANYAPURA Coronary angiography (cardiac catheterisation) This procedure enables the cardiologist to visualise the coronary arteries It is the standard against which other less-invasive investigations are assessed. Selective catheterisation of the right and left coronary ostia is performed. Contrast is then injected into the vessels and digital tape or disc storage of the images obtained. In most hospitals the patient is admitted on the morning of the test and allowed to go home that afternoon. The procedure is most often performed through the femoral artery (Judkins technique) This artery can be punctured through the skin under local anaesthetic. A fine softtipped guide wire is then advanced into the artery and the needle withdrawn (Seldinger method). A short guiding sheath can then be placed over the wire and long cardiac catheters advanced through this sheath along a long guide wire into the femoral artery and up via the aorta to the aortic arch. The catheter and wire are advanced under X-ray control. Usually one catheter with a curved tip (pig-tail catheter; is advanced across the aortic valve into the left ventricle where left ventricular pressures are measured via a pressure transducer connected to the other end of the catheter. Measurement of the left ventricular end-diastolic pressure gives an indication of left ventricular function. Raised end-diastolic pressure (over 15 mmHg) suggests left ventricular dysfunction The catheter is then connected to a pressure injector. This enables injection of a large volume of contrast over a few seconds; for example, 35 mL at 15 mL/second. X-ray recording during injection produces a left ventriculogram . Here left ventricular contraction can be assessed and the ejection fraction (percentage of end-diastolic volume ejected with each systole) estimated. The normal is 60% or more. The figure obtained by this method tends to be higher than that produced by the nuclear imaging method—gated blood pool scanning. The guide wire is reintroduced and the catheter withdrawn to be replaced by one shaped to fit into the right or left coronary orifice. Hand injections of 5–10 mL of contrast are then made. Modern equipment enables numerous views of the coronaries to be obtained in both right and 4• THE PATIENT WITH CHEST PAIN 129 left oblique and caudal and cranial angulated views. The left system (left main, left anterior descending and circumflex arteries) is more complicated than the right, and more views are obtained ) It is also possible to catheterise the heart by direct puncture of the radial artery at the wrist, using a long sheath and a technique similar to the Judkins. Problems may be encountered advancing the catheters around the shoulder or if spasm of the radial or brachial artery occurs.
CARDIOLOGISTS IN HEBBALA Risk stratification using myocardial perfusion scans A normal perfusion scan is associated with a good prognosis. The annual rate of myocardial infarction of cardiac death is < 1%, at least for some years. Stress echocardiography Ischaemic areas of myocardium are known to have reduced contraction compared with normal areas. This can be demonstrated by high-quality echocardiograms. A number of standard views of the heart are obtained and the wall is divided into regions that are assessed for reduced motion. The echo equipment must be designed to store rest images and to present them next to stress images on a split screen so that direct comparison can be made. The stress can be provided by exercise or dobutamine infusion. Exercise echocardiography is difficult to perform because of movement problems and there is quite high inter-reporter variability, but both techniques can approach the accuracy of sestamibi testing in experienced hands. It is not possible to obtain images of adequate quality in all patients. Coronary angiography (cardiac catheterisation) This procedure enables the cardiologist to visualise the coronary arteries It is the standard against which other less-invasive investigations are assessed. Selective catheterisation of the right and left coronary ostia is performed. Contrast is then injected into the vessels and digital tape or disc storage of the images obtained. In most hospitals the patient is admitted on the morning of the test and allowed to go home that afternoon. The procedure is most often performed through the femoral artery (Judkins technique) . This artery can be punctured through the skin under local anaesthetic. A fine softtipped guide wire is then advanced into the artery and the needle withdrawn (Seldinger method). A short guiding sheath can then be placed over the wire and long cardiac catheters advanced through this sheath along a long guide wire into the femoral artery and up via the aorta to the aortic arch. The catheter and wire are advanced under X-ray control. Usually one catheter with a curved tip (pig-tail catheter;is advanced across the aortic valve into the left ventricle where left ventricular pressures are measured via a pressure transducer connected to the other end of the catheter. Measurement of the left ventricular end-diastolic pressure gives an indication of left ventricular function. Raised end-diastolic pressure (over 15 mmHg) suggests left ventricular dysfunction . The catheter is then connected to a pressure injector. This enables injection of a large volume of contrast over a few seconds; for example, 35 mL at 15 mL/second. X-ray recording during injection produces a left ventriculogram Here left ventricular contraction can be assessed and the ejection fraction (percentage of end-diastolic volume ejected with each systole) estimated. The normal is 60% or more. The figure obtained by this method tends to be higher than that produced by the nuclear imaging method—gated blood pool scanning. The guide wire is reintroduced and the catheter withdrawn to be replaced by one shaped to
Left Ventricular Failure Single most important predictor of mortality following STEMI in patients with STEMI Systolic dysfunction alone or both systolic and diastolic dysfunction can occur. LVDD leads to pulmonary venous hypertension and pulmonary congestion. Systolic dysfunction - ↓ cardiac output and of the ejection fraction. Predictors of LVF infarct size, advanced age and diabetes.[190] Mortality increases in association with the severity of the hemodynamic deficit.
ECHOCARDIOLOGIST IN GANGAMMA CIRCLE Mitral regurgitation A regurgitant mitral valve allows part of the left ventricular stroke volume to regurgitate into the left atrium, imposing a volume load on both the left atrium and the left ventricle. Symptoms: Dyspnoea (increased left atrial pressure); fatigue (decreased cardiac output). General signs: Tachypnoea. The pulse: Normal, or sharp upstroke due to rapid left ventricular decompression; atrial fibrillation is relatively common. Palpation: The apex beat may be displaced, diffuse and hyperdynamic if left ventricular enlargement has occurred; a pansystolic thrill may be present at the apex; a parasternal impulse (due to left atrial enlargement behind the right ventricle—the left atrium is often larger in mitral regurgitation than in mitral stenosis and can be enormous). All these signs suggest severe mitral regurgitation. Auscultation Soft or absent S1 (by the end of diastole, atrial and ventricular pressures have equalised and the valve cusps have drifted back together); left ventricular S3, due to rapid left ventricular filling in early diastole; pansystolic murmur maximal at the apex and usually radiating towards the axilla. Causes of chronic mitral regurgitation: (i) Degenerative; (ii) rheumatic; (iii) mitral valve prolapse; (iv) papillary muscle dysfunction, due to left ventricular failure or ischaemia.
THE BEST CARDIOLOGIST IN HEBBALA Hypertension as a risk factor Hypertension is a risk factor for coronary disease, but even more so for cerebrovascular disease and left ventricular failure.1 Control of blood pressure reduces this risk. Large randomised trials have shown that every 10–14 mmHg reduction in systolic and 5 mmHg reduction in diastolic blood pressure confers a 29% reduction in CHD risk and a 40% reduction in stroke risk. The risk of a coronary event in a man with blood pressure greater than 160/95 is five times the risk in a man with blood pressure of 140/90 or less. Hypertension can be diagnosed only by blood pressure measurements. There is little evidence that high blood pressure causes symptoms, except for malignant hypertension with cerebral oedema. The symptoms often ascribed to hypertension—epistaxis, dizziness, headache and fainting—are no more common in hypertensives than in normotensives. Anxiety (often about the blood pressure) and hyperventilation may explain some of these symptoms.2 The trials providing the above figures have been carried out using diuretics or beta-­blockers in the treatment of hypertension. Because these drugs may adversely affect lipid profiles and therefore coronary risk, it has been suggested that newer agents may produce a greater reduction in the risk of CHD events. However, this has not been proven. There is evidence from metaanalyses of blood pressure lowering trials that beta-blockers are less protective against stroke than other agents. They are more effective than placebo in providing protection against stroke. The reduction in blood pressure that is achieved is still more important than the choice of drug. The trials have shown that blood pressure reduction in the elderly, including those over the age of 80, is associated with reduced cardiovascular morbidity but not all-cause (overall) mortality. Treatment of isolated systolic hypertension, common in the elderly, has also shown benefit in terms of the reduced risk of stroke, cardiac failure and coronary disease.3 As in the case of other risk factors, the greatest absolute benefit in the treatment of hyper-­ tension is gained in those patients with existing heart disease, diabetes or multiple risk factors. Blood pressure is an important component of the total risk score . The effects of hypertension Cardiovascular Sustained hypertension results in increased left ventricular wall thickness (left ventricular hypertro-­ phy, LVH) and may ultimately lead to left ventricular dilatation and cardiac failure. LVH results in higher oxygen demands by the ventricle, making angina more likely. The mechanism by which hypertension is thought to increase CHD risk is mechanical damage to the endothelium, leading to increased permeability and therefore increased atherogenesis. Elevated blood pressure interacts with other hereditary and acquired risk factors, all of which are associated with endothelial dysfunction; some are probably implicated in the genesis of hypertension in the first place.4 Neurological Hypertension
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