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Target Concepts:
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Query: UMLS:C0027497 (
nausea
)
23,468
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
It is now recognized that the majority of patients on
epoetin
therapy require intravenous (IV) iron supplementation to maximize the response to treatment. Of the IV iron preparations available, iron sucrose has proved its efficacy and safety; however, there are no guidelines or systematic studies examining the optimum safe dosage regimen for this compound. The aim of the present study was to investigate prospectively a variety of dosing regimens for IV iron sucrose in patients with renal failure to develop treatment strategies for this preparation. A total of 335 iron infusions was administered to 249 patients in this study, which was conducted in four phases. In phase I, 89 patients were administered a dose of 200 mg as an IV infusion over 2 hours. No adverse events were seen. A 500-mg dose by 2-hour infusion was then assessed, but was abandoned after 8 of 22 patients developed reactions characterized by dizziness, hypotension, and
nausea
. The dose was then reduced to 300 mg by 2-hour infusion for the next 189 patients, and again, no adverse reactions were witnessed. Finally, a 400-mg dose by 2-hour infusion was examined in 35 patients, but 2 patients experienced such symptoms as hypotension,
nausea
, and lower back pain. Both the 200- and 300-mg doses of IV iron sucrose administered over 2 hours appear to be safe. The incidence of adverse events with the 400- and 500-mg doses administered as a 2-hour infusion seems too high to recommend their routine use, although it may be possible to administer these doses over a longer period.
...
PMID:Intravenous iron sucrose: establishing a safe dose. 1168 51
Syncope is defined as a temporary interruption of cerebral perfusion with a sudden and transient loss of consciousness and spontaneous recovery. Approximately one third of the population experiences syncope at least once during a lifetime. Presyncopal signs and symptoms, including weakness, headache, blurred vision, diaphoresis,
nausea
, and vomiting are sometimes present for seconds or minutes prior to loss of consciousness. After syncope, the patients may present with persisting drowsiness, headache, dizziness,
nausea
, but not usually confusion. Causes of syncope have been categorized as cardiovascular, non-cardiovascular, and unexplained. Cardiovascular causes can be subdivided into structural heart disease, coronary heart disease, and arrhythmia. Non-cardiovascular causes include neurological, metabolic, psychiatric and other disorders.Orthostatic hypotension - one of the most frequent causes of syncope - has manifold etiologies comprising various neurological and internal diseases. Orthostatic hypotension usually can be attributed to an impairment of peripheral vasoconstriction or to a reduction of the intravascular volume. Signs and symptoms, including the above prodromi are often present just after rising from a supine or sitting position. Frequently, blood pressure decreases significantly without an increase in heart rate. Autonomic cardiovascular modulation is often reduced. Many of the patients with "unexplained" syncope experience neurally mediated (i. e. neurocardiogenic or vasovagal) syncope. In these patients, cardiovascular control may be stable for an extended period of time during orthostatic stress, then there is a sudden decrease in blood pressure and heart rate. Neurocardiogenic or neurally mediated syncope can be associated with painful or emotionally stressful situations such as anxiety or fear, with prolonged standing or specific trigger situations such as micturition, defecation, coughing or sneezing, visceral or carotid sinus stimulation, or with trigeminal or glossopharyngeal neuralgia. So far, the mechanisms of neurocardiogenic syncope are not completely understood. The passive 60 degrees to 70 degrees head-up tilt test is useful for the diagnosis of orthostatic and neurally mediated syncope. The sensitivity of the test can be improved by additional pharmacological provocation, e. g. by isoproterenol, or by increased orthostatic stress using lower body negative pressure stimulation. For the treatment of syncope one should first consider non-pharmacological options. Patients with orthostatic hypotension should avoid rapid changes of the body position from supine to standing, as well as high room temperature or other situations inducing peripheral vasodilatation. An increased intake of sodium and fluids, mild physical exercise or so-called postural counter-maneuvers can improve orthostatic tolerance. Among the drugs recommended for pharmacologic treatment are mineralocorticoids (e. g. fludrocortisone), vasoconstrictor agents (e. g. ephedrine, midodrine), adenosine receptor blockers (theophylline) and beta2-blockers (propanolol), anticholinergic agents, e. g. scopolamine or disopyramide, and negative cardiac inotropes, e. g. beta1-adrenergic blockers or disopyramide. Serotonin reuptake inhibitors (e. g. fluoxetine, sertraline), alpha2-adrenergic agonists (clonidine), central nervous system stimulants such as methylphenidate or phentermine are thought to be beneficial in specific cases. Cardiac pacemakers often seem to be recommended without adequate indication. The antidiuretic, V2-receptor specific, vasopressin analogue desmopressin increases the intravascular volume.
Erythropoietin
improves anemia and red blood cell decrease and augments blood pressure and cerebral oxygenation. In postprandial hypotension, octreotide, a somatostatin analogue, prostaglandin inhibitors such as indomethacin or ibuprofen, as well as metoclopramide or two cups of coffee per day might be beneficial.
...
PMID:[Syncope - a systematic overview of classification, pathogenesis, diagnosis and management]. 1182 26
Myelotoxicity induced by chemotherapy may become life-threatening. Neutropenia may be prevented by granulocyte colony-stimulating factors (GCSF), and
epoetin
may prevent anemia, but both cause substantial side effects and increased costs. According to non-established data, wheat grass juice (WGJ) may prevent myelotoxicity when applied with chemotherapy. In this prospective matched control study, 60 patients with breast carcinoma on chemotherapy were enrolled and assigned to an intervention or control arm. Those in the intervention arm (A) were given 60 cc of WGJ orally daily during the first three cycles of chemotherapy, while those in the control arm (B) received only regular supportive therapy. Premature termination of treatment, dose reduction, and starting GCSF or
epoetin
were considered as "censoring events." Response rate to chemotherapy was calculated in patients with evaluable disease. Analysis of the results showed that five censoring events occurred in Arm A and 15 in Arm B (P = 0.01). Of the 15 events in Arm B, 11 were related to hematological events. No reduction in response rate was observed in patients who could be assessed for response. Side effects related to WGJ were minimal, including worsening of
nausea
in six patients, causing cessation of WGJ intake. In conclusion, it was found that WGJ taken during FAC chemotherapy may reduce myelotoxicity, dose reductions, and need for GCSF support, without diminishing efficacy of chemotherapy. These preliminary results need confirmation in a phase III study.
...
PMID:Wheat grass juice may improve hematological toxicity related to chemotherapy in breast cancer patients: a pilot study. 1757 66
