sodium-bicarbonate and Alkalosis--Respiratory

Experimental studies suggest that both alkalinisation and sodium loading are effective in reducing cardiotoxicity independently. Species and experimental differences may explain why sodium bicarbonate appears to work by sodium loading in some studies and by a pH change in others. In the only case series, the administration of intravenous sodium bicarbonate to achieve a systemic pH of 7.5-7.55 reduced QRS prolongation, reversed hypotension (although colloid was also given) and improved mental status in patients with moderate to severe tricyclic antidepressant poisoning. This clinical study supports the use of sodium bicarbonate in the management of the cardiovascular complications of tricyclic antidepressant poisoning. However, the clinical indications and dosing recommendations remain to be clarified. Hypotension should be managed initially by administration of colloid or crystalloid solutions, guided by central venous pressure monitoring. Based on experimental and clinical studies, sodium bicarbonate should then be administered. If hypotension persists despite adequate filling pressure and sodium bicarbonate administration, inotropic support should be initiated. In a non-randomised controlled trial in rats, epinephrine resulted in a higher survival rate and was superior to norepinephrine both when the drugs were used alone or when epinephrine was used in combination with sodium bicarbonate. Sodium bicarbonate alone resulted in a modest increase in survival rate but this increased markedly when sodium bicarbonate was used with epinephrine or norepinephrine. Clinical studies suggest benefit from norepinephrine and dopamine; in an uncontrolled study the former appeared more effective. Glucagon has also been of benefit. Experimental studies suggest extracorporeal circulation membrane oxygenation is also of potential value. The immediate treatment of arrhythmias involves correcting hypoxia, electrolyte abnormalities, hypotension and acidosis. Administration of sodium bicarbonate may resolve arrhythmias even in the absence of acidosis and, only if this therapy fails, should conventional antiarrhythmic drugs be used. The class 1b agent phenytoin may reverse conduction defects and may be used for resistant ventricular tachycardia. There is also limited evidence for benefit from magnesium infusion. However, class 1a and 1c antiarrhythmic drugs should be avoided since they worsen sodium channel blockade, further slow conduction velocity and depress contractility.

Topics: Alkalosis, Respiratory; Anti-Arrhythmia Agents; Antidepressive Agents, Tricyclic; Arrhythmias, Cardiac; Humans; Hypotension; Poisoning; Sodium Bicarbonate

Although much research has investigated the types of exercise that are enhanced with sodium bicarbonate (NaHCO3) ingestion, to date, there has been limited research on the dosage and timing of ingestion that optimizes the associated ergogenic effects. This study investigated the effects of various NaHCO3 loading protocols on the time-dependent blood-buffering profile. Eight male volunteers (age, 22.4 +/- 5.7 yr; height, 179.8 +/- 9.6 cm, body mass, 76.3 +/- 14.1 kg) completed Part A, measures of alkalosis throughout 120 minutes after ingestion of various single NaHCO3 dosages (0.3 gxkg-1, 0.2 gxkg-1, 0.1 gxkg-1, and placebo); and Part B, similar profiles after alternative NaHCO3 loading protocols (single morning dosage [SMD], single evening dosage [SED], and dosages ingested on 3 consecutive evenings [CED]). Results from Part A are as follows. Blood buffering in the 0.1 gxkg-1 condition was significantly lower than the 0.2 g.kg-1 and 0.3 gxkg-1 conditions (p < 0.002), but there was no significant differences between the 0.2 gxkg -1and 0.3 g.kg-1 conditions (p = 0.34). Although the blood buffering was relatively constant in the 0.1 and 0.2 conditions, it was significantly higher at 60 minutes than at 100 minutes and 120 minutes in the 0.3 gxkg-1 condition (p < 0.05). Results from Part B are as follows. Blood buffering for SMD was significantly higher than for SED and CED (p < 0.05). Blood buffering in the SMD condition was significantly lower at 17:00 hours than at 11:00 hours (p = 0.007). The single 0.2 and 0.3 gxkg-1 NaHCO3 dosages appeared to be the most effective for increasing blood-buffering capacity. The 0.2 gxkg-1 dosage is best ingested 40 to 50 minutes before exercise and the 0.3 gxkg-1 dosage 60 minutes before exercise.

Topics: Acid-Base Equilibrium; Alkalosis, Respiratory; Dose-Response Relationship, Drug; Drug Administration Schedule; Humans; Male; Plasma; Single-Blind Method; Sodium Bicarbonate; Time Factors; Young Adult

An 82-year-old man presented with 6 months of difficulties of falling asleep. He described a feeling of fading breath culminating in breathing arrest when he becomes drowsy. These recurrent events prevented him from falling asleep. Symptoms would only appear when he went to sleep but not during wakefulness. Medical history comprised several episodes of acute decompensated heart failure due to supraventricular tachyarrhythmia with need for hospitalization during the last 2 years. He additionally had two-vessel coronary artery disease with myocardial infarction, pulmonary hypertension, chronic atrial fibrillation, peripheral arterial disease, and chronic kidney disease (stage 3). Medication included diuretics, sodium bicarbonate, angiotensin II receptor antagonist, beta-blocker, statin, clopidogrel, and phenprocoumon without sedatives or analgesics.

Topics: Aged, 80 and over; Alkalosis, Respiratory; Heart Failure; Humans; Male; Sleep Apnea, Central; Sleep Initiation and Maintenance Disorders; Sodium Bicarbonate

Topics: Acidosis; Adult; Alkalosis, Respiratory; Bicarbonates; Charcoal; Female; Humans; Poisoning; Salicylates; Sodium; Sodium Bicarbonate; Suicide, Attempted

It has recently been demonstrated that, compared to normal conditions, ventilation (VE) was increased during exercise after glycogen depletion, in spite of a marked increase in plasma pH (pHP). It was further demonstrated that VE in patients with McArdle's syndrome was reduced when substrate availability was improved. In the present experiments, six endurance trained men performed two successive cyclo-ergometric incremental exercise tests (tests A, B) after normal nutrition (N) and after a fatty meal in conjunction with a sodium bicarbonate (NaHCO3) solution (FSB) or without NaHCO3 (F), and the relationship between VE, plasma potassium concentration ([K+]P), and pHP was checked. Plasma free fatty acid concentration ([FFA]P) was markedly increased in the F and FSB trials (P < 0.001). In FSB pHP was significantly increased, compared to N and F (P < 0.001). In all the B tests, pHP increased during moderate and intense exercise and in FSB, remained alkalotic even during maximal exercise intensity. In contrast, VE and [K+]P changes were almost equal in all the trials and in tests A and B. It was found that exercise-induced changes of VE and [K+]P in the present experiments were not markedly affected by [FFA]P or pHP values and that these changes also occurred independently of changes in pHP or plasma bicarbonate concentration. The often used glycogen depletion strategy may have slightly increased VE but apparently did not overcompensate for a possible decrease in VE due to increased pHP.(ABSTRACT TRUNCATED AT 250 WORDS)

Topics: Acid-Base Equilibrium; Adult; Alkalosis, Respiratory; Bicarbonates; Exercise; Exercise Test; Fatty Acids, Nonesterified; Glycogen; Humans; Hydrogen-Ion Concentration; Male; Muscles; Nutritional Physiological Phenomena; Potassium; Respiration; Sodium; Sodium Bicarbonate

Studies were performed on previously nephrectomized dogs to examine roles of hormonal factors in plasma potassium alterations in acute alkalosis. Respiratory and metabolic alkalosis were induced by hyperventilation and intravenous NaHCO3 or tris(hydroxymethyl)aminomethane (Tris) infusion, respectively. Respiratory and NaHCO3-induced alkalosis provoked decreases in plasma potassium from the control value of 5.12 +/- 0.68 (SE) to 4.21 +/- 0.55 meq/l (P less than 0.01) and from 4.65 +/- 0.26 to 3.91 +/- 0.16 meq/l (P less than 0.01) within 180 min, respectively. In contrast, Tris-induced alkalosis elicited an increase in plasma potassium from the control value of 4.56 +/- 0.30 to 5.31 +/- 0.30 meq/l (P less than 0.01). Hypokalemia in respiratory alkalosis was associated with a decrease in the plasma norepinephrine concentration from the control level of 377 +/- 104 to 155 +/- 41 pg/ml (P less than 0.05) but not with changes in plasma levels of epinephrine, insulin, glucagon, cortisol, and aldosterone. However, this hypokalemia was not affected by phentolamine. Also, somatostatin did not modify the hypokalemic response. NaHCO3-induced hypokalemia was associated with a decline in the plasma aldosterone and norepinephrine concentrations. The decline in plasma norepinephrine in NaHCO3-induced alkalosis followed the decrease in plasma potassium. In Tris-induced alkalosis, plasma insulin increased but norepinephrine decreased. The findings do not suggest fundamental roles of the hormonal factors in the plasma potassium alterations in bilaterally nephrectomized dogs with acute alkalosis.

Topics: Acid-Base Equilibrium; Acute Disease; Alkalosis; Alkalosis, Respiratory; Animals; Bicarbonates; Dogs; Female; Hormones; Hydrogen-Ion Concentration; Male; Nephrectomy; Norepinephrine; Potassium; Saline Solution, Hypertonic; Sodium; Sodium Bicarbonate

Metabolic alkalosis has previously been shown to have an antimagnesiuric influence. To further clarify this phenomenon, short-term clearance studies were performed on intact anesthetized rats subjected to 0.9% saline infusion, 0.15 M NaHCO3 infusion or acute respiratory alkalosis. The experimental protocols resulted in a similar degree of natriuresis in each of the three groups. The increase in plasma pH value was similar both in animals treated with NaHCO3 and animals with respiratory alkalosis. Filtered loads of Mg did not differ in the three experimental groups. However, only acute metabolic alkalosis was associated with a reduction in the absolute rate of Mg excretion (saline: 0.49 +/- 0.05 mu Eq/min; 0.15 M NaHCO3: 0.29 +/- 0.04 mu Eq/min; acute respiratory alkalosis: 0.48 +/- 0.03 mu Eq/min) and fractional Mg excretion (saline: 40.3 +/- 5.3%; 0.15 NaHCO3: 18.7 +/- 1.4%; acute respiratory alkalosis: 37.2 +/- 6.9%). A similar decrease in urinary Mg excretion in animals treated with bicarbonate infusion was observed following removal of the parathyroid gland. Moreover, for any given rate of urinary Na excretion, Mg excretion was lower in bicarbonate-treated animals than in rats infused with saline solution. Intact animals treated with increasing doses of NaHCO3 revealed a statistically significant inverse correlation between the Mg to Na clearance ratio and urinary and plasma bicarbonate concentration. In contrast, such a correlation was not observed during respiratory alkalosis. The findings suggest that bicarbonate ion directly stimulates tubular magnesium reabsorption independent of the presence or absence of parathyroid hormone.

Topics: Alkalosis; Alkalosis, Respiratory; Animals; Bicarbonates; Carbon Dioxide; Magnesium; Male; Natriuresis; Parathyroid Glands; Parathyroid Hormone; Rats; Sodium; Sodium Bicarbonate; Thyroidectomy

Conduction slowing is the major in vivo effect of sodium channel blocking drugs. Although this action may promote arrhythmia suppression, apparently paradoxical arrhythmia aggravation does occur. The latter outcome is most frequently seen during treatment with the class IC agents such as encainide or flecainide, which are potent depressors of conduction even at usual plasma concentrations and heart rates. Anecdotal reports in patients with such drug toxicity have suggested a beneficial effect of sodium lactate or NaHCO3 administration. The purpose of this study, therefore, was to examine the changes induced by sodium loading on the electrophysiologic properties of the canine ventricle pretreated with a class IC drug. Thirty dogs received loading and maintenance infusions of O-desmethyl encainide (ODE), an encainide metabolite that as a sodium channel blocker is approximately 10 times more potent than the parent drug. Interventions were administered during the maintenance phase when stable plasma ODE concentrations of 448 +/- 68 (SEM) ng/ml were present, and QRS was prolonged from 62 +/- 1 to 89 +/- 2 msec, and HV was prolonged from 28 +/- 1 to 50 +/- 1 msec. NaHCO3 (5 meq/kg during 1 minute) shortened QRS from 92 +/- 6 to 76 +/- 3 msec and shortened HV from 44 +/- 3 to 37 +/- 3 msec within 10 minutes (both p less than 0.01). NaHCO3 also significantly prolonged endocardial monophasic action potential duration from 231 +/- 22 to 272 +/- 33 msec and decreased serum [K+] from 3.8 +/- 0.2 to 3.0 +/- 0.2 meq/l, but it did not alter plasma ODE concentration.(ABSTRACT TRUNCATED AT 250 WORDS)

Topics: Alkalosis, Respiratory; Anilides; Animals; Bicarbonates; Dogs; Electroencephalography; Electrophysiology; Encainide; Female; Heart; Heart Conduction System; Heart Rate; Hyperventilation; Male; Sodium; Sodium Bicarbonate; Sodium Chloride; Time Factors

Determination of the appropriateness of the compensatory response is essential in evaluation of any acid-base disturbance. Adequate compensation supports the presence of a single acid-base event. Inadequate compensation may indicate that a second primary acid-base event is present or, in some circumstances, that time has been inadequate for maximal physiologic compensation. When acid-base disturbances are mixed, treatment of one disorder may unmask the full pH-altering potential of the second disorder. Close monitoring of patients at risk for the development of acid-base disorders permits detection of problems at a time when intervention may prevent serious complications. Relatively inexpensive and easy-to-use chemical analytic systems to assist early diagnosis are now present in many office-based laboratories.

Topics: Acid-Base Imbalance; Acidosis; Alkalosis; Alkalosis, Respiratory; Bicarbonates; Diabetic Ketoacidosis; Humans; Potassium Chloride; Primary Health Care; Risk Factors; Sodium; Sodium Bicarbonate; Sodium Chloride

The occurrence of respiratory alkalosis and potential benefit derived from treatment were examined in thermostressed 4-week-old broiler chicks. Blood pH was greater (P less than .05) in heat-stressed (32 C) panting birds (7.395) than either nonpanting (7.28) or birds raised at 24 C (7.28). Acute thermostress, obtained by elevating ambient temperature from 32 to 41 C over a 20-min period further elevated (P less than .05) blood pH to 7.521. Chronic heat-stressed broiler chicks suffer from intermittent respiratory alkalosis during panting; with acute heat stress, chicks pant continuously and suffer from alkalosis. Including .5% sodium bicarbonate (NaHCO3) in the diet of birds subjected to chronic heat stress enhanced body weight gain by 9% even though it tended (P less than .10) to increase blood pH in nonpanting birds. Adding .3 or 1% ammonium chloride (NH4Cl) to diets decreased blood pH (P less than .01) to 7.194 and increased (P less than .05) body weight gains by 9.5 and 25%, respectively. Effects appeared linear with NH4Cl dose to 1% NH4Cl, but 3% NH4Cl elevated weight gains by only 8% and precipitated blood acidosis (pH 7.09) in nonpanting birds. Supplementing the 1% NH4Cl diet with .5% NaHCO3 increased weight gains an additional 9%. Manipulating sodium: chloride ratios by addition of calcium chloride increased body weight gain 8% and slightly reduced severity of alkalosis. Data indicate that blood alkalosis limits growth rate of broiler chicks reared under chronic thermostress and that the respiratory alkalosis and weight gain depressions attributed to thermostress can be partially alleviated dietarily.

Topics: Alkalosis, Respiratory; Ammonium Chloride; Animals; Bicarbonates; Blood Chemical Analysis; Body Weight; Calcium Chloride; Carbon Dioxide; Chickens; Chronic Disease; Hot Temperature; Hydrogen-Ion Concentration; Poultry Diseases; Sodium; Sodium Bicarbonate; Stress, Physiological

Sodium bicarbonate has been recommended for the treatment of arrhythmias induced by tricyclic antidepressants. It is unclear, however, whether this therapy is effective only in the presence of acidosis. A case is presented in which there was an immediate response to sodium bicarbonate in three episodes of ventricular tachycardia despite the presence of alkalosis on two of the three occasions. Given the poor response to conventional therapy of arrhythmias induced by tricyclic antidepressants the use of sodium bicarbonate may be reasonable even in the presence of alkalosis. However, in the presence of pre-existing respiratory or metabolic alkalosis, such therapy is not without risk, and it is suggested that it be reserved for life-threatening situations when the arrhythmia has failed to respond to hyperventilation or antiarrhythmics or both.

Topics: Adult; Alkalosis; Alkalosis, Respiratory; Arrhythmias, Cardiac; Bicarbonates; Electrocardiography; Female; Humans; Hydrogen-Ion Concentration; Imipramine; Sodium Bicarbonate

Previous workers have shown that metabolic acidosis increases the apparent space through which administered bicarbonate is distributed. This finding has been ascribed to the accompanying acidemia and to the consequent availability of a large quantity of hydrogen ion that accumulates on nonbicarbonate tissue buffers during the development of acidosis. To test this hypothesis, bicarbonate space was measured in dogs with a broad range of steady-state plasma [HCO-3] in association with alkalemia as well as with acidemia. Appropriate combinations of pH and plasma [HCO-3] were achieved by pretreating the animals to produce graded degrees of each of the four cardinal, chronic acid-base disorders. Metabolic acidosis (n = 15) was produced by prolonged HCl-feeding; metabolic alkalosis (n = 17) by diuretics and a chloride-free diet; and respiratory acidosis (n = 9) and alkalosis (n = 8) by means of an environmental chamber. Animals with normal acid-base status (n = 4) were also studied. Sodium bicarbonate (5 mmol/kg) was infused over 10 min to the unanesthetized animals; observations were carried out over 90 min. The results obtained from animals with metabolic acid-base disturbances demonstrated an inverse relationship between bicarbonate space and initial plasma pH, confirming the previous findings of others. By contrast, the results obtained in animals with respiratory acid-base disturbances demonstrated a direct relationship between bicarbonate space and initial plasma pH. The pooled data revealed that bicarbonate space is, in fact, quite independent of the initial pH but is highly correlated with the initial level of extracellular [HCO-3]; dogs with low extracellular [HCO-3] (congruent to 10 meq/liter) whether acidemic or alkalemic, have a bicarbonate space that is 25% larger than normal and some 50% larger than in dogs with high extracellular [HCO-3] (congruent to 50 meq/liter). We conclude from these results that the increased bicarbonate space in metabolic acidosis (and respiratory alkalosis) does not reflect the availability of more hydrogen ions for release during bicarbonate administration, but merely evidences the wider range of titration (delta pH) of nonbicarbonate buffers that occurs during alkali loading whenever plasma [HCO-3] is low.

Topics: Acid-Base Equilibrium; Acidosis, Respiratory; Alkalosis, Respiratory; Animals; Bicarbonates; Carbon Dioxide; Chronic Disease; Dogs; Extracellular Space; Female; Hydrogen-Ion Concentration; Sodium Bicarbonate

In anaesthetized dogs, a mixed acid-base disturbance was induced by adding a pronounced metabolic alkaline to an established respiratory acidosis or alkalosis. Cerebral blood flow (CBF) was measured by the radioisotope washout method. In the hypocapnic dogs, the addition of metabolic alkalosis did not significantly change cerebral blood flow. In the hypercapnic dogs, the intravenous infusion of alkali led to a substantial reduction of cerebral blood flow, parallelled by a reduction of cerebrovenous oxygen tension. Acid-base analysis of cerebrospinal fluid (CSF) indicated an increased bicarbonate concentration. Hypercapnia is suggested to facilitate the passage of bicarbonate over the blood-brain barrier, leading to cerebral vasoconstriction by means of increased extravascular pH.

Topics: Acidosis, Respiratory; Alkalosis; Alkalosis, Respiratory; Animals; Bicarbonates; Carbon Dioxide; Cerebrovascular Circulation; Dogs; Homeostasis; Infusions, Parenteral; Oxygen; Sodium Bicarbonate