Evaluation of Almitrine Infusion During Veno-Venous Extracorporeal Membrane Oxygenation for Severe Acute Respiratory Distress Syndrome in Adults.

This single-center case series investigated the effect of almitrine infusion on PaO2/fraction of inspired oxygen (FIO2) in 25 patients on veno-venous extracorporeal membrane oxygenation for severe acute respiratory distress syndrome. A positive trial was defined as an increase of PaO2/FIO2 ratio ≥20%. Thirty-two trials were performed. Twenty (62.5%, 95% confidence interval, 37.5%-75%) trials in 18 patients were positive, with a median PaO2/FIO2 ratio increase of 35% (25%-43%). A focal acute respiratory distress syndrome and inhaled nitric oxide therapy were more frequent in patients with a positive response to almitrine. We observed no complications of almitrine use.

[Effect of almitrine/raubasine on cerebral metabolism in the elderly]. / Effet de l'almitrine/raubasine sur le métabolisme cérébral du sujet âgé.

Recent neurobiological data has led to renewed interest in oxygen (O2). The discovery of neuroglobin, protein varyingly present in the brain, has been enhanced by the elucidation of the mechanisms through which oxygen intervenes in neuronal metabolism. Almitrine/raubasine activates the metabolism of hypoxic/ischemic neurones by increasing O2 bioavailability. This mechanism supports the effects on behaviour obtained in various animal models and the benefits observed during clinical trials in elderly patients presenting with cognitive defects.

Inhaled nitric oxide and vasoconstrictors in acute respiratory distress syndrome.

It has been suggested that the increase in PO(2) observed with nitric oxide (NO) should be enhanced by the addition of a vasoconstrictor agent. The vasoconstrictor used in combination with NO should mimic or enhance hypoxic vasoconstriction. The aim of this study was to evaluate the respiratory and hemodynamic effects of norepinephrine (a nonspecific vasoconstrictor), almitrine bismesylate (a specific pulmonary vasoconstrictor), and inhaled NO, alone or together. During a 6-mo period, 16 patients presenting with ARDS were prospectively investigated. On inclusion, no patient was receiving cardiovasoactive drugs. The protocol consisted of seven consecutive phases: baseline, norepinephrine (in order to obtain a 3 mm Hg rise in mean pulmonary arterial pressure [Ppa]), almitrine bismesylate (16 micrograms/kg/min), inhaled NO (20 ppm delivered during inspiration), norepinephrine + inhaled NO, almitrine bismesylate + inhaled NO, almitrine bismesylate + norepinephrine + inhaled NO. General factorial analysis of variance showed that inhaled NO and almitrine bismesylate increased oxygenation (p < 0.0001). Norepinephrine had no effect on oxygenation. A synergistic effect between inhaled NO and almitrine bismesylate was found (p < 0.05), whereas norepinephrine did not affect the response to inhaled NO. Nitric oxide produced a significant decrease in Ppa and pulmonary vascular resistances (PVRI) (p < 0.0001). Both almitrine bismesylate and norepinephrine induced an increase in Ppa (p < 0.0001). Norepinephrine increased PVRI (p < 0.002), whereas almitrine bismesylate had no effect on PVRI. The present results support the hypothesis that a selective pulmonary vasoconstrictor enhances the increase in oxygenation induced by inhaled NO, whereas norepinephrine attenuates this effect.

Intravenous almitrine bismesylate reversibly induces lactic acidosis and hepatic dysfunction in patients with acute lung injury.

BACKGROUND: Intravenous almitrine, which augments hypoxic pulmonary vasoconstriction, is used for short-term improvement of arterial oxygenation. However, recent research has suggested a potentially harmful effect on lactate metabolism and hepatic function. METHODS: Arterial oxygenation, hemodynamic parameters, plasma lactate, and hepatic function were monitored prospectively in 25 patients with acute lung injury (defined as a ratio of arterial oxygen pressure to inspiratory oxygen fraction < or = 150 mmHg) who where treated with intravenous almitrine. In 21 of 25 patients, acute lung injury was related to primary lung lesions, including pneumonia, postcardiosurgical atelectasis, and lung contusions. RESULTS: Intravenous almitrine increased the ratio of arterial oxygen pressure to inspiratory oxygen fraction from 93 +/- 33 mmHg to 207 +/- 107 mmHg (mean +/- SD). In eight patients (three men), the plasma lactate concentration increased by an average of +3.5 +/- 1.8 mM, and the pH and bicarbonate concentration both decreased during the first 24 h of treatment. In this group of patients, the total bilirubin concentration was elevated before almitrine administration, and the results of other hepatic function tests, such as aspartate aminotransferase, alanine aminotransferase, and prothrombin time, were altered by almitrine administration. Therefore, intravenous almitrine was discontinued. Lactic acidosis and hepatic dysfunction improved. In the other 17 patients (14 men), the plasma lactate concentration and the hepatic function tests remained unaltered during intravenous almitrine therapy for > 60 h. Univariate and multivariate analyses revealed that an abnormal plasma concentration of total bilirubin before almitrine administration and female gender were the two factors significantly linked with lactic acidosis during almitrine infusion. CONCLUSIONS: This study confirms that intravenous almitrine greatly improves arterial oxygenation in patients with acute lung injury but may also induce lactic acidosis and hepatic dysfunction. The coexistence of lactic acidosis and hepatic dysfunction in the same patients strongly suggests that the liver is the primary source of intravenous almitrine-induced lactic acidosis.

The hypoxaemia in chronic obstructive pulmonary disease (COPD) and its management.

Chronic hypoxaemia < or = 55 mmHg, induces various clinical and physiological consequences in patients with stable COPD: dyspnoea, decrease in exercise performances, erythrocytosis impairment of neuropsychological functions, pulmonary hypertension, right ventricular heart failure, all of these troubles impairing quality of life and vital prognosis. To restore a PaO2 > 60 mmHg (or SaO2 > 90%), long term oxygen therapy (LTOT) is the best method in the management of COPD with severe chronic respiratory failure. For patients with PaO2 55-70 mmHg. Almitrine bismesylate a piperazine derivative improving the ventilation/perfusion matching, used in low dosage and in sequential administration, is a useful drug to increase the PaO2 and so, to delay but not to avoid LTOT in responder patients when PaO2 remains < or = 55 mmHg.

[Almitrine in therapy of chronic obstructive respiratory tract diseases with hypoxemia--a clinical multicenter study comparing 2 dosages]. / Almitrin in der Therapie chronisch-obstruktiver Atemwegserkrankungen mit Hypoxämie-eine klinische Multicenter-Studie zum Vergleich zweier Dosierungen.

In an 8-month prospective, placebo-controlled multi-centre trial involving 64 hypoxaemic COPD patients (mean +/- SD age, 64 +/- 8 years, paO2, 57 +/- 7 mmHg, paCO2, 41 +/- 6 mmHg), we compared the efficacy and acceptability of two different dosages of almitrine, 75 and 100 mg. 21 patients received continuous treatment with almitrine (75 mg), 23 sequential treatment (100 mg, one month of placebo after three months treatment), and 20 were in the placebo group. As defined by the inclusion criteria, none of the patients had clinical or subclinical signs of peripheral neuropathy. Clinical examinations, blood gas analyses and determinations of plasma almitrine levels were performed monthly. Patients underwent spirometry and detailed neurological examination upon entry and at the end of the trial. The percentage of drop-outs was considerably higher among patients under medication (59%) as compared to placebo (10%, p < 0.001) which was particularly due to impaired compliance in the almitrine groups. Comparing arterial paO2 or paCO2 over time by analysis of variance, there was no significant effect of medication on blood gases. However, in patients receiving 100 mg almitrine daily, paO2 was significantly increased vs. placebo after four and six months of treatment, and in patients receiving 75 mg almitrine, mean paCO2 was significantly lowered vs. placebo after four months of medication (t-test, p < 0.05). Neurological findings did not differ between treatments and over time. In conclusion, only certain individual patients may benefit from a treatment with 100 mg almitrine whereas the effect of the 75 mg dosage on paO2 did not differ from placebo.

Low-dose almitrine bismesylate in the treatment of hypoxemia due to chronic obstructive pulmonary disease.

STUDY OBJECTIVE: Assessment of acute and chronic effects of low-dose almitrine bismesylate (AB) in stable chronic obstructive pulmonary disease (COPD). STUDY DESIGN: Oral administration of AB, 25 mg three times a day, for 6 months in all patients. Pulmonary function, blood gases, and peripheral nerve conduction velocity were measured at baseline and after long-term administration of AB. In addition, oral pharmacokinetics and effects on pulmonary circulation at rest were studied in half of the patients. Intravenous pharmacokinetics were measured after a single intravenous dose of 60 mg of AB 3 months before the start of oral AB treatment in the other seven patients. SETTING: Outpatient clinic of a community hospital in a coal mining district in southwest Germany. PATIENTS: Fourteen patients with clinically stable COPD and hypoxemia. RESULTS: Acute effects of AB were as follows: a significant increase in arterial oxygen tension (PaO2) from 61 +/- 7 mm Hg to 74 +/- 8 mm Hg (p < 0.001), a decrease in arterial carbon dioxide tension (PaCO2) from 41 +/- 8 mm Hg to 38 +/- 7 mm Hg (p < 0.01), a rise of pH from 7.45 +/- 0.04 to 7.48 +/- 0.04 (p < 0.01), and a transient increase in mean pulmonary artery pressure from 26 +/- 7 to 29 +/- 6 mm Hg (not significant). After long-term treatment, once tissues were saturated with almitrine, improvement in gas exchange persisted with a PaO2 of 70 +/- 10 mm Hg (p < 0.001) and a PaCO2 of 39 +/- 6 mm Hg (not significant) without elevation of pH (7.45 +/- 0.04) or of pulmonary artery pressure (26 +/- 8 mm Hg). The terminal half-life of AB was 56 +/- 45 days after a single intravenous administration, and 55 +/- 16 days after long-term oral dosing. None of the patients developed clinically manifest peripheral neuropathy. Impaired asymptomatic peripheral motor nerve function was prevalent in 4 (29 percent) of the patients and remained unchanged during long-term AB administration. However, asymptomatic impairment of motor nerve conduction velocity developed in two patients with inadequate high AB plasma levels despite low-dose therapy. Both patients were known to have additional conditions predisposing for neuropathy. CONCLUSIONS: Low-dose AB therapy, 75 mg daily, resulted in sustained elevation of arterial oxygen tension in hypoxemic patients with COPD. Although pulmonary artery pressure increased transiently after the first dose, it remained unchanged with long-term treatment despite persistent improvement of pulmonary gas exchange.(ABSTRACT TRUNCATED AT 250 WORDS)

Almitrine and doxapram in experimental lung injury.

Almitrine and doxapram, two structurally unrelated peripheral chemoreceptor agonists, have been shown to enhance hypoxic pulmonary vasoconstriction in anesthetized dogs. We hypothesized that these drugs would increase pulmonary vascular tone and improve gas exchange in canine lung injury caused by oleic acid (OA). Pulmonary hemodynamics and gas exchange were investigated in pentobarbital-anesthetized dogs before and after intravenously administered OA 0.09 ml/kg and again after placebo (n = 6), almitrine 2 micrograms/kg/min (n = 6), or doxapram 20 micrograms/kg/min (n = 6) in a randomized order. Cardiac output (Q) was manipulated using a femoral arteriovenous bypass and an inferior vena cava balloon catheter to construct mean pulmonary artery pressure (Ppa)-Q plots in order to discriminate active from passive changes in Ppa. Gas exchange was assessed by measuring arterial PO2 and intrapulmonary shunt, determined using a sulfur hexafluoride infusion. OA increased Ppa over the range of Q studied, and it deteriorated gas exchange by an increase in intrapulmonary shunt. After OA, placebo had no effect on Ppa, arterial PO2, or intrapulmonary shunt. Both almitrine and doxapram further increased Ppa at all levels of Q studied, but they did not affect indices of gas exchange after OA. We conclude that in this experimental model of acute lung injury, almitrine and doxapram induce pulmonary vasoconstriction without, however, diverting blood flow toward better oxygenated lung regions.

[Sequential administration of a reduced dose of almitrine to patients with chronic obstructive bronchopneumopathies. A controlled multicenter study]. / Administration séquentielle d'une posologie réduite d'almitrine à des malades BPCO. Etude multicentrique contrôlée.

Recent multi-centre studies have shown that high doses of Almitrine (100-200 mg per day), lead to a significant improvement in the hypoxaemia of patients presenting with chronic airflow obstruction, but that a high blood level (greater than 500 ng/ml) is often seen after 1 year, sometimes associated with signs of peripheral neuropathy. In order to maintain Almitrine blood levels in the range 200-300 ng/ml we have used an intermittent regime (with a "window" of 1 month every 3 months) and a dose limited to 100 mg per day. 102 hypoxic patients with chronic airflow obstruction, who were in a stable state were included. 65 patients were in the Almitrine group (A) and 37 patients in the placebo group (P). The treatment lasted for 1 year. In addition there was a 3 monthly follow up with arterial blood gases and spirometry, a clinical neurological examination and also electrophysiology, initially and after 6 and 12 months. 43% of patients in group A and 32% of patients in group P, left the study, most often due to poor cooperation, but sometimes as a result of side effects. After 12 months the PaO2 rose significantly in group A from 59.1 +/- 0.7 to 65.8 +/- 1.6 mmHg (p less than 0.001) whilst it was not changed in group P. The PaCO2 did not change in either group. On the other hand there was a significant fall in the subgroup of patients with hypercapnia in group A (p less than 0.001). The outcome of the neurological and electrophysiological assessments did not show any significant difference between the two groups.(ABSTRACT TRUNCATED AT 250 WORDS)

Two years treatment with almitrine bismesylate in patients with hypoxic chronic obstructive airways disease.

Eighty nine patients with hypoxic chronic obstructive airways disease (COAD) were enrolled into the 1 year Vectarion International Multicentre Study-VIMS in 4 centres, Sheffield (UK), and Antwerp, Liege and Namur (Belgium). At the end of the year the remainder were invited to continue taking placebo or almitrine bismesylate (100-200 mg daily) in the same double blind manner for a further 12 months. In the almitrine treated patients mean arterial oxygen tension (Pao2) at the end of the treatment period improved from 7.5 (0.5) kPa to 8.2 (1.3) kPa (p less than 0.01) and arterial carbon dioxide tension (Paco2) fell from 6.1 (0.8) kPa to 5.8 (0.9) kPa (p less than 0.01). Forced expiratory volume in one second (FEV1), forced vital capacity (FVC) and measurements of breathlessness were unchanged. In the placebo treated group changes in the above variables were not significant. Twenty nine patients withdrew from the almitrine group with seven deaths and six cases of peripheral neuropathy, and 22 patients withdrew from the placebo group with six deaths and two cases of peripheral neuropathy. Death rates between the groups were not significantly different. In conclusion, 2 yrs of almitrine treatment (100-200 mg daily) leads to a persistent slight improvement in PaO2 and PaCO2 but no benefit in survival was demonstrated. Patients in this study had a high incidence of drug related side-effects. Lower dose schedules should be investigated.

[Almitrine: a peripheral respiratory stimulant in chronic obstructive pulmonary disease]. / Almitrina: un estimulante respiratorio periférico en la enfermedad pulmonar obstructiva crónica.

Almitrine dimesylate is a peripheral respiratory stimulant which is effective both on long and short term treatment of chronic obstructive lung disease. The individual therapeutic response, however, is very variable and approximately 25% of patients might not respond to treatment. The recommended doses are 50-100 mg per day during two months, followed by a resting month. Higher doses or longer treatments could provoke high serum levels which in turn would increase the risk of pulmonary hypertension and peripheral neuropathies. Almitrine is not commercialized in Spain as a single drug or for the cited indications.

Double-blind placebo controlled clinical trial of almitrine bismesylate in patients with chronic respiratory insufficiency.

The efficacy and safety of almitrine bismesylate, a new respiratory stimulant, in patients with the hypoxaemic form of chronic respiratory insufficiency caused by chronic bronchitis and emphysema has been assessed. The multicentre trial of 12 weeks duration was double-blind and placebo controlled, with individual and group comparisons. Twenty three patients received almitrine 50 mg b.d. p.o. and 17 took placebo. In the almitrine group a significant increase in PaO2 was achieved (control value 54.4 mm Hg, rising to 59.1 mm Hg after 6 weeks, and to 59.4 mm Hg after 12 weeks). There was also a significant decrease in PaCO2 in the almitrine group after 12 weeks. No correlation was found between the plasma almitrine concentration, PaO2 and PaCO2. Lung function (FVC, FEV1, FEV1/FVC, Raw, TLC, RV, FRC) did not change in either group, but the degree of dyspnoea and performance in the 6 min walking test were significantly improved in the almitrine group. Adverse reactions appeared in 6 out of 23 patients on almitrine bismesylate (headache, urticaria, breathlessness, diarrhoea, chest pain, nausea and vomiting), causing drop out of 4 patients. Thus, almitrine bismesylate can be considered useful in the treatment of patients with chronic respiratory insufficiency.

Long-term effects and safety of almitrine-raubasine in age-associated cognitive decline.

Twenty elderly patients (8 men, 12 women, mean age 67.5 years, range 59-74 years) with age-associated cognitive decline (memory impairment, slowing of thought and inability to concentrate, mean Mini Mental State score 22.0, range 18-24) were included by their general practitioners in an open study of the efficacy and safety of long-term combination therapy with almitrine and raubasine. After a 2-week washout period, patients received almitrine-raubasine for 13 months. Efficacy was evaluated at 2-month intervals using two well-being scales (visual analog and psychoaffective profile) and two behavioral scales (Widlocher's scale, and a scale derived from the Sandoz Clinical Assessment Geriatric scale). Memory was assessed every 6 months. Safety was evaluated by full medical examination and routine laboratory parameters at 2- and 6-month intervals, respectively. On treatment, scores on all scales improved significantly (two-way analysis of variance) throughout the study, as did scores in the two objective memory tests (Friedman test). Safety was demonstrated by the lack of any changes in clinical or laboratory parameters outside the normal range.

Long-term effect of almitrine bismesylate in patients with hypoxemic chronic obstructive pulmonary disease.

A long-term evaluation of the therapeutic efficacy and safety of oral almitrine bismesylate (AB) (50 mg twice daily) was made on 25 patients with COPD and moderate hypoxemia residing at an altitude of 1,500 m in a double-blind placebo-controlled study. Thirteen patients receiving AB (baseline PaO2, 54.3 +/- 4.9 mm Hg; mean +/- SD) and 12 patients receiving placebo (baseline PaO2, 53.0 +/- 4.1 mmHg) were periodically followed by arterial blood gas and other pulmonary function studies and plasma levels of AB. Eight patients receiving AB and nine patients receiving placebo were followed for 1 yr; all patients were followed for at least 90 days. AB administration resulted in an increase in PaO2 to 62.2 +/- 9.3 mm Hg (p less than 0.01) on Day 28. The increase was maintained until Day 360 (63.8 +/- 4.6 mm Hg; p less than 0.01). The mean plasma concentration of AB on Day 28 was approximately one-half that on Day 90 when the plasma level reached a near maximum. AB was associated with weight loss (five of 13 patients receiving AB lost more than 10% of their baseline body weight) and peripheral paresthesias of the lower extremities (three patients), both occurring at the peak plasma levels of the drug. We conclude that AB causes a long-term improvement in arterial oxygenation in hypoxemic patients with COPD residing at an altitude of 1,500 m. Our data suggest that lower doses of AB might produce the same effect on PaO2 with less adverse associated effects, and this should be tested in future studies.