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Query: UMLS:C0018801 (
heart failure
)
72,216
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Patients with advanced
heart failure
commonly develop simple or mixed acid-base disturbances. The altered acid-base homeostasis can occur as a consequence of the
heart failure
itself, the therapeutic interventions, or associated conditions. The present study examined acid-base disorders in patients with
heart failure
who received successful heart transplantation. The information collected should provide light on the determinants of acid-base disorders in this patient population. Seventy status 2 UNOS (United Network Organ Sharing) patients listed for heart transplantation were enrolled in this study. All patients received loop diuretics, spironolactone, ACE inhibitors, carvedilol and digitalis as needed. Patients were studied again at discharge after transplantation, under cyclosporine, azathioprine, steroids, loop diuretics and ACE inhibitors. After heart transplantation, a significant increase of ejection fraction from 19.7 +/- 0.63 to 53.6 +/- 0.9% (p < 0.0001) occurred along with a concomitant reduction of central venous pressure (p < 0.0001) from 12.6 +/- 0.20 to 6.9 +/- 0.21 mm Hg. Before heart transplantation there was high-normal pH (7.43 +/- 0.009), slight loss of hydrogen ions (35.4 +/- 0.4 nmol/l), slightly reduced pCO(2 )(37.6 +/- 1.1 mm Hg). After heart transplantation a stability of blood pH and hydrogen ion concentrations was found but bicarbonate increased significantly (p < 0.02) from 24.2 +/- 0.61 to 26.2 +/- 0.51 mmol/l and pCO(2) from 37.6 +/- 1.1 to 39.3 +/- 0.7 mm Hg (p < 0.05). Plasma renin activity averaged 3.80 +/- 0.6 pg/ml before heart transplantation and 2.82 +/- 0.4 pg/ml after (p < 0.01). Aldosterone concentration averaged 380 +/-15 pg/ml before heart transplantation and 280 +/- 10 pg/ml after (p < 0.01). These data suggest that in patients before heart transplantation there is a mixed acid-base imbalance that includes respiratory
alkalosis
and metabolic alkalosis. After transplantation the recovery of the abnormal circulatory status erased the initial respiratory
alkalosis
but metabolic alkalosis persisted and accounted for a further rise in plasma bicarbonate.
...
PMID:Acid-base state in patients after cardiac transplantation. 1216 64
A 4-year-old Thoroughbred gelding racehorse was referred to the Onderstepoort Veterinary Academic Hospital (OVAH) with a history of post-race distress and collapse. In the absence of any obvious abnormalities in the preceding diagnostic work-up, a standard exercise test was performed to determine an underlying cause for the post-race distress reported. In this particular case oxygen desaturation became evident at speeds as slow as 6 m/s, where PO2 was measured at 82.3 mm Hg. Similarly at a blood pH of 7.28, PCO2 had dropped to 30.0 mm Hg indicating a combined metabolic acidosis and respiratory
alkalosis
. The cause of the distress was attributed to a severe hypoxia, with an associated hypocapnoea, confirmed on blood gas analyses, where PO2 levels obtained were as low as 56.6 mm Hg with a mean PCO2 level of 25.4 mm Hg during strenuous exercise. Arterial oxygenation returned to normal immediately after cessation of exercise to 106.44 mm Hg, while the hypocapnoeic
alkalosis
, PCO2 25.67 mm Hg, persisted until the animal's breathing normalized. The results obtained were indicative of a dynamic
cardiac insufficiency
present during exercise. The combination of an aortic stenosis and a mitral valve insufficiency may have resulted in a condition similar to that described as high-altitude pulmonary oedema, with respiratory changes and compensation as for acute altitude disease. The results obtained were indicative of a dynamic
cardiac insufficiency
present during exercise and substantiate the fact that an extensive diagnostic regime may be required to establish a cause for poor performance and that the standard exercise test remains an integral part of this work-up.
...
PMID:The use of the standard exercise test to establish the clinical significance of mild echocardiographic changes in a Thoroughbred poor performer. 1545 67
In end-stage
heart failure
, various acid-base disorders can be discovered due to the renal loss of hydrogen ions and hydrogen ion movements into cells, the reduction of the effective circulating volume, hypoxemia and renal failure. This justifies the occurrence of metabolic alkalosis, metabolic acidosis, respiratory
alkalosis
, as well as respiratory acidosis alone or in combination. Several studies have been published on the acid-base state in
heart failure
. In a 1951 study, Squires et al analyzed the distribution of body fluid in congestive heart failure by taking into consideration the abnormalities in serum electrolyte concentration and in acid-base equilibrium. A recent study by Milionis et al, analyzed 86 patients with congestive heart failure receiving conventional treatment; the majority of these patients exhibited hypokalemia, hyponatremia, hypocalcemia and hypophosphatemia. Disorders in acid-base balance were noted in 37.2% of patients. In a recent study, 70 patients with severe congestive heart failure before heart transplantation showed high-normal pH, slightly reduced pCO 2 and a slight loss of hydrogen ions. After heart transplantation, stability of blood pH and hydrogen ion concentrations was found. In contrast, bicarbonate and pCO 2 increased significantly. The data led us to formulate the diagnosis of a mixed acid-base disorder that includes respiratory
alkalosis
and metabolic alkalosis before heart transplantation. In
heart failure
, the presence of acid-base imbalance associated with the activation of mechanisms that lead to salt and water retention reveals evidence concerning the pivotal role of the kidney in determining the outcome of these patients.
...
PMID:Acid-base balance in heart failure. 1673 34
Human skeletal muscles contain the largest single pool of K+ in the body (2600 mmol, 46 times the total K+ content of the extracellular space). Intense exercise may double arterial plasma K+ in one min. This is because of excitation-induced release of K+ from the working muscle cells via K+ channels. This hyperkalemia is rapidly corrected by reaccumulation of K+ into the muscle cells via Na+,K+ pumps, often leading to hypokalemia. Hyperkalemia may also arise from muscle cell damage, excessive oral or intravenous administration of K+, acidosis, renal failure, depolarization of muscle cells with succinyl choline, activation of K+ channels by fluoride poisoning, hyperkalemic periodic paralysis, malignant hyperthermia, inhibition of the Na+,K+ pumps by digitalis glycosides or treatment with nonselective beta blockers. Hyperkalemia may cause arrhythmia and can be treated with beta2 agonists, insulin or hemodialysis. Hypokalemia may be induced by the stimulation of the Na+,K+ pumps in skeletal muscles seen postexercise, or by catecholamines, beta2 agonists, pheochromocytoma, theophylline, caffeine or insulin, by sepsis, myocardial infarction, trauma, burns and
heart failure
. Rare causes are hypokalemic periodic paralysis, inhibition of K+ channels by barium, chloroquine or barbiturates. Hypokalemia often reflects dietary K+ deficiency,
alkalosis
, renal or gastrointestinal loss of K+. Hypokalemia is more likely to cause arrhythmia than hyperkalemia and can be treated by oral or intravenous administration of K+ under frequent control of electrocardiogram and plasma K+. Because of their size and high contents of K+, Na+,K+ pumps and K+ channels, the skeletal muscles play a central role in the acute, from min-to-min ongoing regulation of plasma K+. This is decisive for the maintenance of muscle contractility and heart function.
...
PMID:Hormonal and pharmacological modification of plasma potassium homeostasis. 2061 71
A 43-year-old white woman presented to the emergency department with confusion, agitation, and progressive dyspnea. Chest x-ray revealed pulmonary edema. Initial diagnostic considerations were pneumonia, pulmonary embolism, sepsis, central nervous system infection, substance toxicity, and
heart failure
. Her salicylate level was 92.6 mg/dL, and an arterial blood gas revealed a respiratory
alkalosis
and nonanion gap metabolic acidosis, consistent with salicylate poisoning. Noncardiogenic pulmonary edema is an atypical presentation of salicylate toxicity, and this case highlights the importance of an early toxicology screen to make a time-critical diagnosis and provide specific treatment.
...
PMID:Salicylate-induced pulmonary edema--a near-miss diagnosis. 2436 Nov 38
The retrotrapezoid nucleus (RTN) regulates breathing in a CO
2
- and state-dependent manner. RTN neurons are glutamatergic and innervate principally the respiratory pattern generator; they regulate multiple aspects of breathing, including active expiration, and maintain breathing automaticity during non-REM sleep. RTN neurons encode arterial
P
C
O
2
/pH via cell-autonomous and paracrine mechanisms, and via input from other CO
2
-responsive neurons. In short, RTN neurons are a pivotal structure for breathing automaticity and arterial
P
C
O
2
homeostasis. The carotid bodies stimulate the respiratory pattern generator directly and indirectly by activating RTN via a neuronal projection originating within the solitary tract nucleus. The indirect pathway operates under normo- or hypercapnic conditions; under respiratory
alkalosis
(e.g. hypoxia) RTN neurons are silent and the excitatory input from the carotid bodies is suppressed. Also, silencing RTN neurons optogenetically quickly triggers a compensatory increase in carotid body activity. Thus, in conscious mammals, breathing is subject to a dual and interdependent feedback regulation by chemoreceptors. Depending on the circumstance, the activity of the carotid bodies and that of RTN vary in the same or the opposite directions, producing additive or countervailing effects on breathing. These interactions are mediated either via changes in blood gases or by brainstem neuronal connections, but their ultimate effect is invariably to minimize arterial
P
C
O
2
fluctuations. We discuss the potential relevance of this dual chemoreceptor feedback to cardiorespiratory abnormalities present in diseases in which the carotid bodies are hyperactive at rest, e.g. essential hypertension, obstructive sleep apnoea and
heart failure
.
...
PMID:Interdependent feedback regulation of breathing by the carotid bodies and the retrotrapezoid nucleus. 2916 67
The paper in early history of pulmonary medicine deals with studies of hypocapnia as a result of hyperventilation. Hyperventilation hypocapnia provokes respiratory
alkalosis
, subsequent ion changes in blood may cause disorders of myocardium conductivity and excitability resulted in arrhythmiae and even
heart failure
. Besides, hypocapnia limits the cerebral circulation which may be manifested in euphoria and even loss of consciousness. It is dangerous component of high altitude disease. Earliest medical descriptions of hyperventilation hypocapnia and its cardiac consequences are traditionally related with publications by an American physician of XIX age J.M. Da Costa and British doctor A.B.R. Myers. There exists a generally accepted eponym of "Da Costa syndrome". Hereby the authors for the first time coin data that disorders related to hyperventilation were described more than 360 years prior to Da Costa - by an Italian polymath of Renaissance epoch Leonardo da Vinci and suggest new eponym of "Leonardo da Vinci's syndrome". The article also briefly analyzes the medical studies of Leonardo da Vinci and his early contribution into Human Anatomy and Thyroidology.
...
PMID:Hyperventilation Hypocapnia as The Leonardo da Vinci's Syndrome. 3094 23
Critical congenital heart disease (cCHD) is the most common reason for acute
cardiac failure
in the neonatal period. cCHD, defined by systemic low cardiac output (LCO) and requiring surgery or catheter-based intervention in the first year of life, has an incidence of approximately 15% of CHD and is responsible for up to 25% fatalities of newborn infants. Clinical deterioration develops in most cases due to rapid closure of the ductus arteriosus (DA). Early diagnosis and immediate treatment determinate beneficial outcome. Critical CHD can be classified in duct-dependent systemic flow, duct-dependent pulmonary flow and transposition of the great arteries. The latter two manifest themselves in oxygen resistant cyanosis, whereas CHD with duct-dependent systemic flow may present itself with cardiogenic shock, which can be difficult to differentiate from other causes of shock such as sepsis. Besides prostaglandin therapy for reopening the arterial duct, a balanced parallel pulmonary and systemic circulation should be a therapeutic goal. In CHD with duct-dependent systemic flow a decrease of pulmonary resistance should be avoided; therefore inadequate oxygen therapy, hyperventilation and
alkalosis
due to excessive treatment of acidosis, should be averted. Volume therapy should be performed carefully. In CHD with duct-dependent pulmonary flow, pulmonary resistance can be decreased, in case of poor pulmonary flow systemic resistance should be increased, mild
alkalosis
is recommended. Intense volume therapy is in most cases necessary, except if a restrictive atrial communication is present. In addition to intensive care measures, an arsenal of catheter- and surgery-based procedures need to be hold available as back-up for emergency procedures. Transcatheter interventions are nowadays decisive. Atrial-septostomy was the first and still the most utilized high-urgency procedure; DA-stenting is used in prostaglandin-refractory duct stenosis. In the presence of critical aortic valve stenosis, palliation consists of balloon valvuloplasty. In critical aortic coarctation with
myocardial failure
and no response to prostaglandin, palliative balloon angioplasty may be the method of choice as bridging for corrective surgery.
...
PMID:Acute therapy of newborns with critical congenital heart disease. 3116 Oct 78
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