View clinical trials related to Shock.
Filter by:Effective chest compressions are essential to survival in an arrest patient receiving CPR (cardiopulmonary resuscitation). A challenge in providing effective chest compressions is frequent interruption of compressions. A major cause of a recurrent interruption of chest compressions is pulse checks. Pulse checks are difficult to quickly and accurately perform in the AHA recommended time interval of under 10 seconds for reasons ranging from inexperience to body habitus. Unnecessarily long pulse checks often delay reinitiating chest compressions leading to a fall in perfusion pressure to the coronary arteries lowering the chances of return of spontaneous circulation (ROSC). To potentially solve the issues of evaluating the chest compression effectiveness and minimize the time interval of pulse checks, the authors have constructed a novel device that can be rapidly applied to an arresting patient and evaluate the current state of the circulatory system. The device is called the Rapid Pulse Confirmation (RPC) device. It is designed to applied over a major artery (radial, ulnar, brachial, carotid, and femoral) and detect Doppler shift of red blood cells to gauge red blood cell velocity and rate of pulsation. Feasibility testing on the device was carried out using patients requiring cardiopulmonary bypass. Arrest and return of spontaneous circulation during cardiopulmonary bypass is predictable and provided an ideal environment to test the initial performance of a device meant to detect return of spontaneous circulation. The primary working hypothesis was that there would be no significant difference in time of detection of ROSC between the arterial line catheter and the RPC device at the end of cardiopulmonary bypass. The secondary hypothesis was that there would be no difference in pulse rate reading between the arterial line catheter and the RPC device.
this study is conducted to evaluate the role of the novel triple therapy combination in reducing the mortality rate, reducing the shock time, and reversal of organ damage. the study includes two arms, the first arm is the control which received hydrocortisone monotherapy and the second arm is the intervention arm which received the triple therapy regimen. calculation of 28 days in-hospital mortality is the primary outcome. shock time, vasopressor doses, infection markers, and organ function tests are the secondary outcomes. the data will be analyzed by student t-test or Mann Whitney test, Fischer exact or chi-square test for numbers, repeated measures ANOVA will be used to consider confounders and other parameters, mortality will be expressed by Kaplan Meier and ROC curve. For Multivariate analysis of repeated quantitative outcomes, linear mixed models were used to quantify the relationship between one dependent variable (SOFA, SCr, doses of vasopressors) and many independent variables including group type and sepsis phenotype adjusted to other clinical and demographic factors.
HYPOTHESIS: During anesthetic pre-oxygenation with high FiO2, pulmonary atelectasis occur, especially in patients < 6 years old, where FRC and pulmonary closing volume may overlap. New borns and children <1 year old are especially vulnerable. OBJECTIVES: 1. Validate "air test" as a individualized and non-invasive diagnostic method of clinically significant atelectasis in pediatrics. 2. Determine what other factors contribute to atelectasis development in pediatrics METHODS: 30 pediatric patients will be studied with ages ranged between 45 postconceptional weeks and16 years old. Baseline SpO2 and lung ultrasound will be performed for each patient upon arrival at the operating theatre before preoxygenation with FiO2 of 1.0 SpO2 will be measured 15 min after intubation during a 5 min long "air test" trial (FiO2 0.25). lung collapse will be verified by lung ultrasound at the end of the 15 min trial. Lung collapse will be eventually granted upon lung US verification by a blind researcher.
The effect of early, prehospital norepinephrine use in patients with traumatic shock on mortality is unknown. Recent existing observational evidence from single system data (US, France, Japan) are conflicting. The investigators hypothesize that prehospital norepinephrine is associated with decreased mortality when used in patients with traumatic shock.
The purpose of this study is to determine the most suitable dose of Fludrocortisone in reversal of sepsis and shock associated with sepsis in patients who are admitted to the ICU. The investigators will be looking to see whether patients receiving Fludrocortisone at different doses recover quicker and spend less time in hospital and in ICU, and to understand the reasons why this happens at certain doses. Sepsis is caused by toxic substances (toxins) from bacteria and other organism entering the bloodstream from a site of infection. In some people, the infection can progress to sepsis and septic shock where the functions of organs in the body are affected. Patients suffering from sepsis and septic shock are commonly managed in the intensive care unit (ICU) where they are prescribed antibiotics as standard therapy, as well as other therapies to support the functions of the body. Fludrocortisone is a steroid that has previously shown to be beneficial to help in shock in patients in ICU, but more information is required about the exact dose that is required to achieve this. This has been shown by previous research. However, the exact role of Fludrocortisone and the best dose has not been studied adequately to date as well as the ways in how it works within the body. The study aims to look tat the dose and the way it works.
During Infection, oflfending microbes interact with the host immune system producing a downstream inflammatory cascade involving cytokines and other mediators, which in turn triggers a systemic response. The resultant effects linclude vasodilation, increased vascular permeability, myocardial depression, and impairment of the coagulation cascade, resulting in global imbalance of systemic oxygen supply and demand. During the late stage of sepsis, immunosuppression predominates, leading to multi-organ dysfunction and further clinical deterioration . Sepsis is defined as life-threatening organ dysfunction caused by a dysregulated host response to infection with two or three on Quick Sepsis-related organ failure assessment score (qSOFA). Septic shock is defined as the presence of sepsis and refractory hypotension to fluid management. Vasopressors are needed to maintain systolic blood pressure more than 90mmHg or mean blood pressure more than 65 mmHg . Experimental and Clinical evidence suggests that sepsis is associated with dysregulated response of Hypothalamic-pituitary-adrenal axis that may involve any of the steps from cortisol production to cortisol use by cells . Glucocorticoid therapy for the treatment of septic shock remains controversial, with conflicting evidence regarding a mortality benefit. It has been used in patients with septic shock who remained hypotensive after fluid and vasopressor resuscitation. Fludrocortisone is a corticosteroid and acts as a powerful mineralocorticoid along with some additional but comparatively very weak glucocorticoid activity. Relative to cortisol, it is to 10 times the glucocorticoid potency but 250 to 800 times the mineralocorticoid potency . Fludrocortisone is added to hydrocortisone to provide additional mineralocorticoid potency. The rationale for adding mineralocorticoid treatment is that an experimental sepsis study showed marked nuclear factor NF-κB mediated down regulation of vascular mineralocorticoid receptors . Corticosteroids attenuate inflammation in various organs an effect partly related to inhibition of nuclear factor NF-κB. Improve cardiovascular function by restoring effective blood volume through increased mineralocorticoid activity and by increasing systemic vascular resistance through vascular α-Adrenergic responsiveness and reduces inflammation-mediated vasodilation .
Vasopressors are medications that are given intravenously to increase the blood pressure of patients with illnesses that cause dangerous blood pressure drops. When a doctor prescribes a vasopressor, they ask that the dose be adjusted to achieve a specific blood pressure. This kind of medical support with intravenous (IV) vasopressors are usual treatments in intensive care unit (ICU) settings. Oral vasopressors, such as midodrine, have been historically used to maintain blood pressure in non-critically ill patients. In this study, the investigators will be using midodrine to reduce the need for IV vasopressors as blood pressure improves during the stay in the ICU The LIBERATE pilot study will evaluate the role of midodrine for patients with low blood pressure in the ICU. The investigators are planning on enrolling up to 20 study participants to evaluate this question in the General Systems ICU at the University of Alberta Hospital.
For the emergency physicians and critical care specialists, how to quickly recognize shock from diverse clinical features and immediately treat shock patients to prevent progression to irreversible organ dysfunction from initially reversible shock condition are important issues and challenges. In recent years, ultrasonography had been extensively used in clinical practice recently, and well-trained medical staffs can quickly and easily apply ultrasound to evaluate, examine, diagnose, and even treat the patients. The clinical application of point-of-care ultrasound can help the first-line physicians rapidly evaluate and diagnose the main symptoms and signs of the patients at bedside, and further initially stabilize and appropriately treat the patients subsequently. The aim of this program is to prospectively collection of the findings of point-of-care ultrasonography in shock patients at emergency room in NTUH. The clinical manifestations, and followed up the examinations, treatments, and prognosis will also be collected. The effect of bedside ultrasound on differential diagnosis and treatment of shock patients will be analyzed. The results of the current study can provide the base for further clinical trials and set up of shock team.
Fluid responsiveness prediction prior to fluid challenge administration is a topic of interest, which has been extensively investigated, but remains challenging. In clinical practice, functional hemodynamic tests (FHT) consisting of maneuvers that affect cardiac function and/or heart-lung interaction, have been introduced in order to identify fluid responders and non-responders without fluid challenge administration. Changes in cardiac output induced by the Passive Leg Raising (PLR) test reliably predicted the increase in cardiac output to volume expansion. New approaches have been recently developed based on changes in respiratory dynamics, such as a transient increase in tidal volume, or a lung recruitment maneuver or an end-expiratory occlusion (EEO) test. The EEO leaded to an increase in venous return, cardiac preload and stroke volume in preload-responsive patients. The authors found that an increase in cardiac output ≥ 5% during a 15-s EEO reliably predicted its response to a 500-ml saline infusion. However, in order to identify the rapid and transient increase in cardiac index during the EEO, continuous and instantaneous cardiac output monitoring is necessary. Pulse contour analysis methods provide a beat-to-beat estimation of cardiac output and had been used in most of studies validating the EEO test. Carotid doppler is a non-invasive, bedside, easy to use ultrasound technique that measuring blood flow peak velocity (CDPV) and duration of systolic component of each cardiac cycle (from the onset to dicrotic notch- Flow time - FT) allows a reliable estimation of fluid status and could be an interesting alternative to track changes in SV and cardiac output.
The sepsis and septic shock remain major causes of child morbidity and mortality, despite the use of modern antibiotics and resuscitation therapies. Recent interest has focused on biomarkers for early diagnosis, and evaluation the outcomes of sepsis; but there is a still lack of early diagnosis and timely intervention for sepsis in the emergency department (ED). The primary aim was to investigate the role of C-Reactive Protein(CRP), Procalcitonin(PCT), soluble-urokinase plasminogen activator receptor(suPAR) and Presepsin in the early stratification of patients with sepsis. The usefulness of pediatric Sequential Organ Failure Assessment (pSOFA) for predicting of the mortality and the rate of PICU admission in children with septik shock were also investigated. This prospective pilot study was conducted at academic pediatric ED between September 2017-June 2018. All children who met sepsis criteria admitted to ED were involved to study. They kept following up after ED management and their blood samples were taken upon admission on day 0, 1, 2, 4 and 7. The definition made as sepsis, severe sepsis and septic shock. At the same period, 100 healthy children chosen as the control group. The patient characteristics, clinical features, diagnosis, co-morbidities, source of infection, laboratory results (CRP, PCT, lactate, suPAR and Presepsin) and treatments were recorded. The pSOFA score was calculated during first hour of admission. Length of stay in ED and hospital was noted. The main outcome measure was in 7 and 30-day mortality.