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Hypotension clinical trials

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NCT ID: NCT04399486 Withdrawn - Clinical trials for Orthostatic Hypotension

Hemodynamic Effects of Aquatic vs. Land Exercise in Patients With Orthostatic Hypotension

Start date: January 15, 2022
Phase: N/A
Study type: Interventional

Orthostatic hypotension is a highly prevalent deficit in the aging population especially when coupled with stroke, frailty, diabetes, Parkinson's disease or spinal cord injuries. This population has difficulty with the autonomic regulation of blood pressure and experiences elevated risks of falls. The fall risk is greatest when the person transitions from supine or sitting to standing as this is when blood has a tendency to pool in the legs preventing adequate blood circulation to vital organs. This is a safety concern and limiting factor for rehabilitation of patients with orthostatic hypotension in the inpatient rehabilitation setting. There is low-quality evidence that compression garments such as abdominal binders and compression stockings can be helpful to manage orthostatic hypotension and the associated fall risk. However, many people with orthostatic hypotension perceive the treatment approach with compression stockings to be largely unacceptable. Aquatic immersion may provide better advantages to compression garments because hydrostatic pressure exerts a little over 22 mmHg pressure for every foot of water. Therefore, an individual standing in 4 ft depth water will have roughly 90 mmHg pressure on their feet and about 56 mmHg at their knees. These amounts of pressure are more than those induced by typical compression stockings, which provide 30-40 mm Hg pressure. In addition, immersion at level of xiphoid process or higher is known to translocate blood from the lower to the center of the body and act to increase cerebral blood flow which may be beneficial for preventing orthostatic hypotension symptoms. No studies have looked at the physiologic response to immersion and aquatic exercise for people with orthostatic hypotension. Since this population is known to have difficulty with autonomic regulation of blood pressure, it is unclear if they will experience a similar hemodynamic response during immersion than the healthy population during or after aquatic therapy due to orthostatic hypotension. Anecdotal evidence suggests that patients with orthostatic hypotension do not exhibit adverse effects due to orthostatic hypotension when standing in water or participating in aquatic exercise independent of compression garments use. They often have improved standing tolerance in the pool compared with prolonged standing on land. Steps to manage orthostatic hypotension when out of the pool, such as hydration during pool session, placing compressive garments prior to exit of pool and slow transitions out of pool setting has been adequate to prevent symptoms of orthostatic hypotension in the post exercise period in this population. The primary aim of this study is to look at heart rate and blood pressure response when going from sit to stand during physical therapy sessions on land compared to in the pool for people who have orthostatic hypotension (defined as a drop in systolic blood pressure of at least 15 mmHg or 7 mmHg drop in diastolic blood pressure from sitting to standing). The secondary aim of this study is to evaluate tolerance for physical activity during physical therapy sessions in the pool compared to on land for people with orthostatic hypotension. The third aim of the study is to investigate heart rate and blood pressure response for 3 hours following the physical therapy sessions. We hypothesize that orthostatic hypotension will be reduced and standing exercise tolerance will be increased when in the pool compared to on land. In addition, we hypothesized that there will not be a significant difference in heart rate or blood pressure response in the 3-hour post exercise period of aquatic vs. land exercise.

NCT ID: NCT04396548 Completed - Clinical trials for Hypotension After Spinal Anesthesia

Midodrine for Improving Hemodynamics After Spinal Anesthesia

Start date: June 8, 2020
Phase: N/A
Study type: Interventional

Neuraxial blockade such as spinal anaesthesia can cause severe hypotension due to pharmacological sympathectomy resulting in potential deleterious consequences for the patient. Prevention of this spinal anaesthesia induced hypotension is of utmost importance. Techniques currently in use for preventing hypotension include intravenous fluid prehydration, sympathomimetic drugs, and physical methods such as leg bindings and compression stockings. Midodrine is a direct acting α1-adrenoceptor agonist which causes venous and arterial vasoconstriction through stimulation of α1- receptors located in the vasculature. The aim of this study is to evaluate the efficacy and safety of prophylactic midodrine use with preoperative fluid hydration before spinal anesthesia in the prevention of hypotension in patients undergoing elective orthopedic surgery. We hypothesize that intraoperative hypotension would be less in patients given midodrine and intravenous fluid prehydration preoperatively before spinal anesthesia.

NCT ID: NCT04379141 Not yet recruiting - Anesthesia Clinical Trials

Ultrasonic Measurement of IVC and IJV in Predicting Hypotension After Anesthesia Induction

Start date: May 8, 2020
Phase:
Study type: Observational

This research is expected to study ultrasonic measurement of internal jugular vein and inferior vena cava, which can be used as a good index to predict hypotension after anesthesia induction, and its measurement method is simple and quick.

NCT ID: NCT04369131 Enrolling by invitation - Clinical trials for Spinal Cord Injury Cervical

Controlling Orthostatic Hypotension in People With Cervical Spinal Cord Injury

Start date: December 1, 2021
Phase: N/A
Study type: Interventional

A common therapeutic intervention after spinal cord injury (SCI) is prolonged standing in a standing frame. For people with SCI, standing for 40 minutes or more, three to four times weekly improves several health-related issues including well-being, circulation, skin integrity, reflex activity, bowel and bladder function, digestion, sleep, pain, and fatigue. However, a person who experiences orthostatic hypotension (OH)-defined as a decrease of 20mm hg in systolic blood pressure or a decrease of 10mm hg in diastolic pressure within 3 minutes of standing from a sitting or supine position-secondary to SCI may not tolerate positioning in a standing frame, thus resulting in a loss of access to these health benefits. OH is common for people with SCI. It results from central nervous system dysregulation causing pooling of blood in the lower extremities that can lead to dizziness, light-headedness, blurred vision, weakness, fatigue, nausea, palpitations, headache, and/or syncope. Although an array of physical and pharmacologic interventions are available to people in the general population for managing OH, few such interventions have been evaluated for use by people with SCI, especially when the level of injury is C5 or above. One possible intervention that may be effective for people with OH secondary to SCI is functional electrical stimulation (FES) because its application results in a dose-dependent increase in blood pressure. An unanswered question is whether the placement of FES electrodes on various parts of the body has differential effects. Therefore, the purpose of this study is to evaluate blood pressure responses among people with OH secondary to cervical SCI when receiving FES intervention involving the placement of electrodes in three different positions as well as when receiving no FES intervention during tilt table sessions. The selected positions for electrode placement are: (a) the calves, (b) the quads and abdominals, and (c) the quads, abdominals, and calves. The researchers hypothesize that FES intervention, regardless of placement, will result in better control of OH than no FES intervention and that no significant blood pressure difference will occur across the three FES placements.

NCT ID: NCT04367103 Completed - Hypotension Clinical Trials

Norepinephrine for Hypotension in Cesarean Section

Start date: April 10, 2021
Phase: N/A
Study type: Interventional

Hypotension is a very common consequence of the sympathetic vasomotor block caused by spinal anesthesia for cesarean section. Maternal symptoms such as nausea, vomiting and dyspnea frequently accompany severe hypotension, and adverse effects on the fetus, including depressed APGAR scores and umbilical acidosis, have been correlated with severity and duration of hypotension. Because hypotension is frequent, vasopressors should be used routinely and preferably prophylactically.

NCT ID: NCT04320823 Completed - Clinical trials for Apheresis Related Hypotension

IMPACT (Improving Plasma Collection) Clinical Trial

IMPACT
Start date: January 6, 2020
Phase: N/A
Study type: Interventional

Prospective, multi-center, randomized, controlled clinical trial to study the safety and effectiveness of a novel plasma collection system software.

NCT ID: NCT04301830 Not yet recruiting - Clinical trials for Intracranial Hypotension

Postoperative Changes in Optic Nerve Sheath Diameter in Patients Undergoing Spinal Anesthesia for Cesarean Delivery

Start date: April 2020
Phase:
Study type: Observational

This is observational study. The investigator will measure optic nerve sheath diameter by ultrasound on the eye after cesarean section under spinal anesthesia.

NCT ID: NCT04301102 Completed - Clinical trials for Intraoperative Hypotension

The Predict H Trial

Start date: November 1, 2020
Phase: N/A
Study type: Interventional

The aim of the study is to determine whether a goal-directed algorithm based on the prevention of arterial hypotension using the Hypotension Prediction Index reduces the duration and severity of intraoperative hypotension when compared with the recommended standard therapy and if this intraoperative strategy affects tissue oxygenation and organ perfusion.

NCT ID: NCT04299776 Withdrawn - Clinical trials for Hypotension on Induction

CirQPOD Shoulder Study

Start date: January 28, 2020
Phase: N/A
Study type: Interventional

Intrathoracic pressure regulation (IPR) therapy, delivered by impedance threshold devices (ITDs) or intrathoracic pressure regulators (ITPRs), increases venous return, preload, cardiac output, blood pressure, and cerebral perfusion pressure by intermittently creating negative intrathoracic pressure, which improves circulation in hypotensive animals and humans. By increasing systemic pressure and cerebral perfusion as well as promoting venous return, IPR therapy potentially improves cerebral oxygenation. The lower intrathoracic pressures may also reduce pulmonary artery pressure, although there is currently little evidence one way or the other. Use of an ITPR can counteract the multifactorial intraoperative hypotension common during surgeries under general anesthesia, and reduce the need for other measures to treat such hypotension; however, they might simultaneously promote pulmonary complications. The investigators will therefore assess whether the use of intrathoracic pressure regulation in adults having shoulder surgery under general anesthesia in the sitting position reduces vasoactive medication requirements compared with routine clinical practice. Simultaneously, the investigators will assess the effect of intrathoracic pressure regulation on pulmonary circulation, cerebral oxygenation, and postoperative atelectasis.

NCT ID: NCT04291794 Not yet recruiting - Clinical trials for Hypotension on Induction

Mean Arterial Pressure Reduction Anesthesia Induction Using Propofol Bolus or Tritiated Target-infusion

Start date: March 1, 2020
Phase: Phase 4
Study type: Interventional

To compare haemodynamics and bispectral index values between conventional bolus propofol induction and target-controlled propofol infusion.