cardiovascular-agents and Hyperventilation

Severe intracranial hypertension (IH) in the setting of fulminant hepatic failure (FHF) carries a high mortality and is a challenging disease for the critical care provider. Despite considerable improvements in the understanding of the pathophysiology of cerebral edema during liver failure, therapeutic maneuvers that are currently available to treat this disease are limited. Orthotopic liver transplantation is currently the only definitive therapeutic strategy that improves outcomes in patients with FHF. However, many patients die prior to the availability of donor organs, often because of cerebral herniation. Currently, two important theories prevail in the understanding of the pathophysiology of IH during FHF. Ammonia and glutamine causes cytotoxic cerebral injury while cerebral vasodilation caused by loss of autoregulation increases intracranial pressure (ICP) and predisposes to herniation. Although ammonia-reducing strategies are limited in humans, modulation of cerebral blood flow seems promising, at least during the early stages of hepatic encephalopathy. ICP monitoring, transcranial Doppler, and jugular venous oximetry offer valuable information regarding intracranial dynamics. Induced hypothermia, hypertonic saline, propofol sedation, and indomethacin are some of the newer therapies that have been shown to improve survival in patients with severe IH. In this article, we review the pathophysiology of IH in patients with FHF and outline various therapeutic strategies currently available in managing these patients in the critical care setting.

Topics: Ammonia; Anesthetics, Intravenous; Brain; Cardiovascular Agents; Cerebrovascular Circulation; Electroencephalography; Glutamine; Humans; Hyperventilation; Hypothermia, Induced; Indomethacin; Intracranial Hypertension; Liver Failure, Acute; Propofol; Vasodilation

Increased intracranial pressure (ICP) is a pathological state common to a variety of neurological diseases, all of which are characterized by the addition of volume to the skull contents. Elevated ICP may lead to brain damage or death by two principle mechanisms: 1) global hypoxic-ischemic injury, as a consequence of reduced cerebral perfusion pressure (CPP) and cerebral blood flow; and 2) mechanical distortion and compression of brain tissue as a result of intracranial mass effect and ICP compartmentalization. All ICP therapies have as a goal, reduction of intracranial volume. In unmonitored patients with acute neurological deterioration, head elevation, hyperventilation, and mannitol (1g/kg) can rapidly lower ICP. Fluid-coupled ventricular catheters and fiberoptic transducers are the most accurate and reliable instruments for measuring ICP. In monitored patients, the treatment of critically raised ICP should proceed in an orderly step-wise fashion: 1) consideration of neuroimaging to exclude a new surgically operable lesion; 2) intravenous sedation to attain a quiet motionless state; 3) manipulation of blood pressure to keep CPP >70 and <120; 4) mannitol infusion; 5) moderate hyperventilation (P(CO2) 26 to 30 mmHg); and 6) high-dose pentobarbital therapy. Application of moderate hypothermia (32 to 33 degrees C) shows promise as a newer method for treating refractory ICP. Placement of an ICP monitor is the critical first step in management of ICP. Treatment is best done using a stepwise protocol, with careful attention to sedation and CPP control prior to using mannitol and hyperventilation.

Topics: Blood Pressure; Cardiovascular Agents; Diuretics, Osmotic; Humans; Hyperventilation; Hypnotics and Sedatives; Intracranial Hypertension; Mannitol

The origin of dyspnea in chronic heart failure (HF) is multifactorial, and excessive ventilation is thought to play a role in inducing this symptom. Chemosensivity is augmented in HF, correlates with increased pulmonary ventilation (VE), and is an adverse prognostic marker. Despite increased blood levels of natriuretic peptides in clinical conditions associated with dyspnea, their effect on pulmonary VE and chemoreceptor activity remains unexplored.. We tested in a prospective, placebo-controlled, three-way cross-over, double-blind randomized study the effects of the recombinant form of the natural human B-type natriuretic peptide (R-BNP) in comparison with placebo and levosimendan on chemoreflex sensitivity at rest, as well as their effects on pulmonary VE, systemic blood pressure, heart rate and sympathetic serum activity both at rest and during exercise.. Eleven stable chronic HF patients were randomized to sessions of 6-min treadmill-walking tests during placebo, or levosimendan or R-BNP intravenous infusion in the following conditions: room air, hypoxia, and hypercapnia. R-BNP administration determined higher pulmonary ventilatory response at rest and during exercise (P < 0.001) consequent to a boost of respiratory rate (P < 0.001) under room air and hypoxia conditions. Norepinephrine blood levels increased from rest to exercise in all conditions without differences among placebo, levosimendan, and R-BNP effects. BNP blood levels remained unchanged.. The novelty of the present findings is that R-BNP infusion in HF patients can boost pulmonary ventilatory response at rest and during exercise.

Topics: Adult; Brazil; Cardiovascular Agents; Chemoreceptor Cells; Chronic Disease; Cross-Over Studies; Double-Blind Method; Drug Therapy, Combination; Female; Heart Failure; Hemodynamics; Humans; Hydrazones; Hypercapnia; Hyperventilation; Hypoxia; Infusions, Intravenous; Lung; Male; Middle Aged; Natriuretic Peptide, Brain; Prospective Studies; Pyridazines; Recombinant Proteins; Respiratory Rate; Simendan; Time Factors; Treatment Outcome