View clinical trials related to Hypotension.
Filter by:Following surgery to remove tumours of the head and neck, patients undergo reconstruction with free flaps - tissue that is taken from elsewhere in the body and given a new blood supply by attaching it to vessels in the neck. Following this type of surgery, patients often need medication to maintain their blood pressure in the intensive care unit. The effect of these drugs on the transplanted tissues is unknown. This study investigates the effects of four commonly used drugs on free flap perfusion.
Aim of the present randomized controlled multinational trial is the comparison of a novel biofeedback system on sodium profiling applied to a endogenous hemodiafiltration therapy, with the standard (no sodium profiling) hemodiafiltration technique on the intradialytic overall and cardiovascular stability.
The investigators hypothesize that given prophylactically, intravenous ondansetron will attenuate the drop in blood pressure and heart rate frequently seen after spinal anesthesia. Eighty-six American Society of Anesthesiologists (ASA) physical status I or II in preoperative patient assessment, parturients age of 18 to 45 years scheduled to undergo elective caesarean section will be enrolled. Patients will be randomized to 2 groups: the ondansetron group, receiving 8 mg intravenous ondansetron diluted in 10 mL of saline; or the placebo group, who were administered 10 mL of saline given 5 minutes prior to performing the spinal anesthetic. Investigational Pharmacy will randomize and dispense study drug. Baseline measurements of vital signs will be taken. Otherwise standard management will then be used: - Patients must be NPO for 8 hours - Pulse oximetry, EKG monitoring, noninvasive blood pressure at a minimum of every 3 minutes, more frequently if decided by the provider. - Standard lumbar puncture in a sitting position the L3-L4 or L4-L5 - Whitacre pencil-point, 25 gauge - Injectate: 2 mL of 0.75% hyperbaric bupivacaine, 100 mcg preservative free morphine, 20 mcg fentanyl - Immediately after completing the subarachnoid injection, patients will be laid supine with left lateral uterine displacement The sensory level of anesthesia will be assessed in the standard fashion every five minutes using ice. The motor component will tested using the Bromage scale for spinal anesthesia (0, no paralysis; 1, inability to lift the thigh [only knee/feet]; 2, inability to flex the knee [only feet]; 3, inability to move any joint in the legs).
The investigators propose a dose finding study to determine the feasibility of Angiotensin II (AII) to increase mean arterial pressure in high-output shock. If AII can be shown to increase mean arterial pressure, this could lead to future pharmacologic development based on the AII hormonal pathway. The investigators propose a 20 patient, randomized, placebo-controlled, blinded study in the treatment of high-output shock. Patients with high-output shock and a cardiovascular SOFA (sequential organ failure score) score of > 4 will be eligible. In addition, patients must already be receiving cardiac output monitoring and have a cardiac index > 2.4 L/min/ 1.73 m2. Patients will be randomized to intravenous AII or saline in a blinded fashion. There will be 10 patients in each arm. This is a safety and dose finding feasibility study. The investigators are starting with a small cohort consistent with similar types of studies. The investigators estimate that ten patients in each arm will generate a basis for determining if there is sufficient signal for AII to improve blood pressure at the doses outlined. The primary endpoint in the study will be the effect of AII on the standing dose of norepinephrine which is required to maintain a mean arterial pressure (MAP) of 65 mmHg. Secondary endpoints will be the effect of AII on urine output, serum lactate, and creatinine clearance. 30 day post dose mortality will also be assessed. Subjects discharged prior to day 30 will be contacted by telephone for this assessment.
Rapid administration of crystalloid immediately after induction of spinal anesthesia (coload) to be more effective in terms of managing hypotension as compared to administering crystalloid before spinal anesthesia (preload). Phenylehrine infusion is a safe and effective way to reduce incidence and frequency of hypotension during SA for cesarean delivery. Hypotension was virtually eliminated by use of high-dose prophylactic phenylephrine infusion at a rate of 100 µg/min and rapid crystalloid coload up to two liters (administration at the time of SA). However, incidence of reactive hypertension was frequent up to 47% with decrease in maternal heart rate (HR). This may raise concern in patients in whom increase of blood pressure may be detrimental, like chronic hypertension and in the presence of a compromised uteroplacental blood flow. A recent study found that infusing phenylephrine at a fixed rate of 75 and 100 ug/min is associated with more episodes of hypertension than placebo or the lower infusion rates of 25 and 50 ug/min respectively. However, there was no reduction in the number of physician interventions (phenylephrine boluses and stopping the infusion) needed to maintain maternal systolic blood pressure within 20% of baseline among all groups. Prophylactic fixed rate infusions may have limited application in clinical practice, and a variable rate (i.e. modifying the rate according to hemodynamics) has been advocated. The bolus administration of phenylephrine to treat hypotension is still commonly used, but requests multiple interventions from the anesthesiologists and is time consuming. Eighty patients scheduled for cesarean delivery under spinal anesthesia will be assigned to one of two groups. Immediately after spinal injection, rapid crystalloid colaod of lactated Ringer of 15 mL/kg over a period of 10-15 min will be initiated. Patients in Group I will receive infusion of normal saline (placebo) and patients in group II variable infusion rate of phenylephrine started at 0.75 ug/kg (close to the dose of 50 ug/min recommended for fixed infusion rate). The number of interventions needed to maintain maternal systolic blood pressure within 20% of baseline, hemodynamic performance, intraoperative nausea and vomiting, and umbilical cord blood gases will be compared between the two groups. We will define a reliable and safe method to ensure maternal hemodynamic stability during spinal anesthesia for cesarean delivery with the least physician interference.
In this study the investigators aimed 1. to investigate the prevalence of orthostatic hypotension in elderly nursing home residents. 2. to investigate whether the presence of orthostatic hypotension influences the chance of successful rehabilitation.
The investigators seek to determine the efficacy, duration of action and safety of escalating dose of droxidopa on systemic blood pressure, cerebral blood flow and vasoactive hormones and catecholamines during upright seated posture. Primary Question: 1. What is the lowest dose of droxidopa that increases seated SBP to 115±5 mmHg in men and 105±5 mmHg in women? - When does the defined increase in SBP occur after oral ingestion of droxidopa? - How long does this dose of droxidopa sustain SBP at these levels? - What are the vital signs and the subjective symptomology following droxidopa administration? Secondary Question: 1. What is the MFV response to droxidopa administration in hypotensive individuals with SCI? - Does an increase in SBP correspond to an increase in MCA MFV? Tertiary Question: 1. What is the vasoactive hormone and catecholamine response to droxidopa administration in hypotensive individuals with SCI? - Does droxidopa administration result in a change in APR, Aldo or NE in hypotensive individuals with SCI?
Low blood pressure or hypotension is a very important problem that is often seen in premature babies, especially those with low birth weight. Severe hypotension leads to significant problems including brain bleeds, developmental delays, kidney and liver problems, and other issues that can affect babies for the rest of their lives. An important aspect in the management of infants with hypotension is the decision of when to treat and with what agent. Research is being conducted to try to find the best medication to use in these situations. Dopamine is often used first, but it does not always prove to be effective, and it has several concerning side effects. This study will look at vasopressin, which has fewer side effects, as a first-line medication for low blood pressure in extremely low birth weight infants. Hypotheses and Specific Aims: This study will show superiority of vasopressin to dopamine in preterm, extremely low birth weight infants who have hypotension within the first 24 hours of life. We will specifically look at its ability to raise blood pressure values, improve clinical symptoms seen, any adverse effects, and clinical outcomes of babies being treated.
The autonomic or automatic nervous system helps control blood pressure. Diseases of the autonomic nervous system may result in a drop in blood pressure on standing in many cases leading to fainting. Diseases that affect the autonomic nervous system include pure autonomic failure, multiple system atrophy and Parkinson's disease, and can present with very similar symptoms and it is sometimes difficult to determine an exact diagnosis. The purpose of the study is to find out if the blood pressure response from taking a single dose of the medication atomoxetine can help in the diagnosis of these diseases.
Inadequate identification of and subsequent delayed therapy for patients with hypoperfusion (including hypovolemia, congestive heart failure and sepsis) is a common problem faced by physicians and intensivists caring for critically ill patients. Bedside clinical assessment is notoriously inaccurate in diagnosing complex etiologies of hemodynamic disturbances and in deciding on the appropriate therapy. Invasive techniques which are often required to guide diagnosis and therapy have significant risks associated with them, are costly, and are time consuming. New technology has been developed that allows for instantaneous, noninvasive monitoring of key hemodynamic parameters, like stroke volume, peak velocity and cardiac output. This new technology has the potential to improve recognition of the etiology of hemodynamic disturbances and assist the clinician in optimizing therapy based on changes in hemodynamic parameters. There is significant potential for this to be translated into improved outcomes in critically ill patients, but this has never been studied.