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NCT07550400
Fluid replacement is considered the cornerstone of hemodynamic management in critically ill patients especially in patients with septic shock. However, only about 50% of critically ill hemodynamically unstable patients are responsive to fluids. Consequently, the resuscitation of critically ill patients requires an accurate assessment of the patients' intravascular volume status and their volume responsiveness. In this study, we will compare the efficacy of carotid artery flow to echo left ventricular end diastolic volume as a predictive value for fluid resuscitation in septic shock patients.
NCT07547020
Hemodynamic instability is a common and serious condition in patients undergoing liver transplantation and is associated with increased morbidity and mortality if not promptly recognized and treated. It results from multiple interacting factors, including blood loss, changes in vascular tone, cardiac dysfunction, and complications related to the surgical procedure. Traditional monitoring strategies focus on global hemodynamic variables such as blood pressure and cardiac output. However, these parameters may not accurately reflect tissue perfusion or oxygen delivery at the microcirculatory level. As a result, patients may appear hemodynamically stable while still experiencing inadequate tissue oxygenation. This study aims to evaluate hemodynamic instability using an integrative physiological approach based on the interaction between different components of the cardiovascular system. Specifically, the study will assess four key interfaces: the relationship between the heart and the arterial system, the coherence between macrocirculation and microcirculation, the interaction between venous return and the right atrium, and the coupling between the right ventricle and the pulmonary circulation. The main objective is to identify distinct hemodynamic profiles in patients during the immediate postoperative period following liver transplantation. In addition, the study will evaluate the incidence of tissue hypoxia within the first 24 hours and its association with clinical outcomes, including 30-day evolution. This is a prospective observational study conducted in adult patients admitted to the intensive care unit after liver transplantation who develop hemodynamic instability requiring vasoactive support. During the first 24 hours, multimodal hemodynamic monitoring will be performed, including assessment of cardiac function, vascular tone, venous congestion, pulmonary circulation, and markers of tissue perfusion such as lactate levels and capillary refill time. By integrating these variables, patients will be classified into different hemodynamic profiles according to the predominant underlying mechanism. This approach aims to improve the understanding of cardiovascular dysfunction in this setting and to support more individualized and physiologically guided management strategies.
NCT06638268
The goal of this clinical trial is to learn if acute transcatheter aortic valve implantation (TAVI) is superior to standard treatment (stabilization in an intensive care unit and TAVI subsequently) to treat cardiogenic shock in patients with critical severe aortic stenosis. The main questions it aims to answer are: • Does acute TAVI increase survival compared with standard treatment? Participants will: * Undergo either TAVI within 12 hours after admission or stabilization and TAVI 72 hours or more after admission * Visit an outpatient clinic and be evaluated for quality of life and heart function
NCT07537621
Preload responsiveness and venous congestion have largely been investigated independently in recent literature. However, recent data report a similar incidence of venous congestion regardless of fluid responsiveness status, challenging the concept of a linear continuum between preload independence and fluid intolerance. These findings support the need for a more individualized hemodynamic management strategy that takes venous congestion risk into account. The right ventricle plays a central role in this framework. Its function is to maintain an adequate venous return pressure gradient to ensure cardiac output while limiting upstream venous congestion, under strong dependence on its afterload. In physiological conditions, the right ventricle adapts to changes in afterload by increasing contractility to preserve right ventriculo-arterial coupling and optimize its performance. In chronic cardiopulmonary diseases, right ventriculo-arterial uncoupling is a well-established prognostic factor, including the presence of occult uncoupling revealed by fluid loading. In critically ill patients, right ventricular systolic dysfunction associated with venous congestion-defining right heart failure-is strongly associated with increased mortality, as is right ventriculo-arterial uncoupling itself. To support the concept of fluid tolerance, the investigators hypothesize that impairment of right ventriculo-arterial coupling may exist or occur during fluid loading in critically ill patients, independently of preload responsiveness, and may be associated with worsening upstream venous congestion.
NCT04295252
The study will provide data on profile, management, outcome, and evolution over time of cardiogenic shock patients admitted to the Intensive Coronary Care Units
NCT07230041
The purpose of this study is to measure the change in plasma concentrations of antibiotics used during passage through the CRRT filter and hemadsorption cartridge in patients with septic shock and renal failure requiring CRRT. All patients aged \> 18 years, admitted to the ICU, diagnosed with septic shock and renal failure requiring CRRT, receiving antibiotic therapy with at least one of the following drugs: meropenem, linezolid, and daptomycin, who provided informed consent, are included in the study. Patients not admitted to the ICU, patients with renal failure not requiring CRRT, patients aged \< 18 years, or those who did not provide informed consent are excluded. The enrollment period will last 12 months and will run from September 2024 to September 2025. The expected number of patients enrolled is twenty. To proceed with the study, after starting antibiotic therapy, a 4 ml dose of blood will be drawn (Vacuette tube ref. 454092) before the cartridge, immediately after, and after the dialysis filter. This measurement will be repeated after 4, 8, and 12 hours, which represents the maximum usage time of the cartridge. After 12 hours, the cartridge becomes saturated and loses its adsorption capacity. The CRRT filter, however, remains in place for at least 72 hours before being replaced. Treatment is maintained until clinically necessary. For patients in intensive care, several blood samples are required throughout the day, both with a blood sample sent to the biochemistry laboratory every 6-8 hours to check clinical conditions, and with an arterial blood sample (blood gas) to check respiratory and metabolic status in patients on mechanical ventilation. Furthermore, in patients undergoing CRRT, electrolyte balance must be monitored every 4 hours. Therefore, the blood sample for the study inevitably coincides with one of the routine blood samples. The test tube, labeled with a unique code, will be sent to the central laboratory, which will centrifuge the blood and extract the plasma. This aliquot will then be stored at -80°C in a dedicated space and sent to the designated laboratory upon analysis. Determination of the plasma dosage of the antibiotic in use is commonly performed on patients admitted to the Intensive Care Unit, where clinically necessary. Participation in the study does not change current clinical practices.
NCT01473498
Sepsis is the most severe complication of infections. Sepsis-associated Acute kidney injury (AKI) is commonly encountered in critically ill patients and independently predicts poor outcome. Unfortunately, no drug or management strategy was able to reduce incidence of AKI. To adapt the level of mean arterial pressure according to local renal hemodynamic evaluated by renal Doppler could lead to a better renal perfusion, and then less AKI.
NCT07367113
This prospective, randomized, controlled trial aimed to evaluate whether fluid resuscitation guided by the Peripheral Perfusion Index (PPI) could reduce the incidence of Acute Skin Failure (ASF) in elderly critically ill patients. A total of 216 patients aged ≥65 years with sepsis or other types of shock requiring early aggressive fluid resuscitation were enrolled and randomly assigned in a 1:1 ratio to either the PPI-guided resuscitation group or the conventional resuscitation group. The intervention group targeted maintaining PPI ≥1.4 in addition to conventional hemodynamic goals, while the control group followed standard resuscitation protocols. The primary outcome was the incidence of ASF within 7 days of ICU admission, diagnosed according to NPUAP/EPUAP (2014) criteria. Secondary outcomes included time to ASF occurrence, lactate clearance, cumulative fluid balance, organ function, and long-term prognosis.
NCT07516236
This prospective observational diagnostic accuracy study investigates the efficacy of dynamic central venous oxygen saturation in predicting fluid responsiveness in septic shock, compared to measurements obtained using echocardiography (VTI) and cardiometry. We will correlate the changes in measuring cardiac output by both echocardiography and cardiometry with the changes in dynamic central venous oxygen saturation both at baseline and after fluid challenge to investigate the efficacy of dynamic central venous oxygen saturation in predicting fluid responsiveness in septic shock.
NCT07515508
The goal of this observational study is to learn whether information collected during routine hospital care, together with blood and urine samples, can help doctors better identify different types of cardiogenic shock and better predict outcomes in adults hospitalized with acute heart failure and cardiogenic shock. The main question is whether clinical findings, imaging results, and biomarkers, including sex-specific factors, are associated with the risk of death within 30 days. Participants will not receive an experimental treatment. Researchers will collect data from routine care, collect additional blood and urine samples for biobanking, and follow participants after hospital discharge
NCT05953376
Calcium helps blood to clot and thereby stop bleeding. Trauma patients who experience large volume blood loss often require blood transfusions and bleeding is the most common cause of death. The purpose of this study is to see if giving intravenous calcium immediately to patients who require large volume blood transfusion will decrease transfusion requirements, vasopressor use and mortality in bleeding trauma patients.
NCT05168462
Rationale: Pump failure due to acute myocardial infarction (AMI) can lead to cardiogenic shock (CS): a state of low blood flow to end-organs with subsequent multi-organ failure that is associated with high mortality rated. The first line pharmacologic treatment strategy in CS is noradrenaline. This vasopressor drug is used to maintain adequate blood pressures. The assumption is that a mean arterial blood pressure (MAP) ≥ 65 mmHg will improve flow and thereby tissue perfusion of myocardium and other tissues (e.g. renal). However, there is no evidence that an increase in MAP, if achieved by noradrenaline, leads to greater end-organ blood flow and better outcomes. Objective: With this study the investigators aim to investigate the (cost-)effectiveness of reduced noradrenaline in patients with CS by using a lower MAP target of ≥ 55 mmHg, compared to ≥ 65 mmHg. The investigators hypothesize that reduced use of noradrenaline will improve overall survival and decrease renal failure requiring renal replacement therapy. Study design: Open label, randomized controlled multicenter trial Study population: Adults patients with CS due to AMI Intervention: Treatment strategy of reduced noradrenaline, by using a lower MAP target ( ≥ 55 mmHg). Main study endpoint: composite of all-cause mortality and severe renal failure leading to renal replacement therapy within 30-days after randomization.
NCT07488689
Microcirculatory dysfunction is a key driver of organ failure and mortality in septic shock, characterized by endothelial injury and impaired vasoregulation. Despite its strong prognostic value, it remains unaddressed by current therapies. SGLT-2 inhibitors (SGLT-2i) have shown promising vasculoprotective, anti-inflammatory, and glucose-lowering effects that may help restore endothelial function, reduce vascular leakage, and manage stress-induced hyperglycemia-factors central to septic shock pathophysiology. Preclinical and clinical observational studies suggest potential benefits, but clinical research in this specific context is lacking. This trial aims to evaluate the efficacy and safety of SGLT-2i in septic shock patients with clinical signs of microcirculatory failure, addressing a critical unmet medical need. Septic shock management relies on rapid infection control, hemodynamic stabilization with fluids and vasopressors, and supportive care, with corticosteroids used in select cases. However, this standardized approach faces major limitations due to patient heterogeneity, treatment-related complications (e.g., fluid overload, vasopressor side effects), and rising antimicrobial resistance. Adjunctive therapies have largely failed to improve outcomes, reflecting the complex pathophysiology of septic shock. These challenges highlight a pressing need for novel, targeted interventions and a shift toward personalized treatment strategies. The investigators hypothesize that early administration of SGLT-2 inhibitors within 14 hours of septic shock onset in patients showing signs of microcirculatory dysfunction will improve 28-day outcomes mainly by targeting endothelial and microvascular injury. Expected benefits include reduced mortality and organ dysfunction, faster recovery with lower resource use, a favorable safety profile, and potential for global implementation as a cost-effective adjunctive therapy. This study will be a multicenter, prospective, randomized, and comparative double-blind trial. All patients admitted with septic shock in the ICU will be screened for trial eligibility criteria. After verifying the eligibility criteria and obtaining patient or family consent, or after an emergency inclusion procedure, eligible patients will be randomized in a 1:1 ratio to receive either Dapagliflozin (10 mg once daily) or matching placebo in addition to standard-of-care. Patients will be followed up for 1 year or until death, whichever occurs first.
NCT04031573
Septic shock is a major health problem, with several million cases annually worldwide and a mortality approaching 45%. Tachycardia is associated with excess mortality during septic shock. This pejorative effect could be related to the increase in cardiac metabolic demand, impaired cardiac diastolic function, and/or poorer tolerance of administered exogenous catecholamines. Recent studies suggest that controlling the heart rate with the use of beta blockers has beneficial effects on the morbidity and mortality of septic shock. However, the negative effects of beta-blockers on cardiac contractility and blood pressure complicate their use during septic shock, particularly because about one-half of patients exhibit a septic-associated systolic dysfunction, which often requires the use of inotropes. Ivabradine is a selective inhibitor of If channels in the sinoatrial node. It is a pure bradycardic agent with no deleterious effect on other aspects of cardiac function (contractility, conduction and repolarization) nor on blood pressure. Ivabradine can therefore alleviate sinus tachycardia without negative inotropic effects nor hypotension. Moreover, the improvement in diastolic function (ventricular filling) with ivabradine may increase stroke volume, even in case of severe impairment of systolic function. Controlling sinus tachycardia with ivabradine during septic shock would allow reducing cardiac metabolic demand (and potentially associated ischemic events) and improving the chronotropic tolerance of exogenous catecholamines. The effectiveness of ivabradine in controlling the heart rate was demonstrated in various clinical settings such as coronary artery disease, chronic heart failure and cardiogenic shock. Encouraging preliminary data are reported in critically ill patients.
NCT07482865
A prospective, multi-center, open label, randomized controlled, superiority trial to compare clinical outcomes between routine distal perfusion catheter (DPC) insertion versus provisional distal perfusion catheter (DPC) insertion in the occurrence of sign or symptom of acute limb ischemia in patients undergoing mechanical circulatory support (MCS) through femoral artery approach.
NCT04569942
This multicentre, randomised controlled trial will enrol 1000 patients presenting with septic shock to the emergency department (ED) of participating hospitals in Australia and New Zealand. Participants will receive haemodynamic resuscitation with either a restricted fluids and early vasopressor regimen or a larger initial IV fluid volume with later introduction of vasopressors if required. Clinical care including the type of resuscitation fluid and vasopressor agent, will otherwise be in accordance with accepted standard care and according to clinician discretion. The study intervention will be delivered for at least 6 hours and up to 24 hours post-randomisation. Participants will be followed for up to 12 months and outcomes analysed on an intention-to-treat basis.
NCT04419480
Pilot Prospective Randomized Unblinded Pragmatic Trial of Pulmonary Artery Hemodynamic Monitoring Following Hospitalization for Cardiogenic Shock
NCT07470814
Acute myocardial infarction complicated by cardiogenic shock (AMI-CS) represents the most life-threatening subtype of acute cardiovascular diseases. Current clinical management of AMI-CS in China is plagued by multiple structural challenges, including a rapidly aging patient population, inequitable distribution of medical resources, the absence of standardized care models, and poor applicability of international risk stratification tools. Owing to ethnic disparities in disease presentation and the low penetration of mechanical circulatory support (MCS) devices in China, international clinical evidence for AMI-CS diagnosis and treatment cannot be directly translated into local clinical practice. Furthermore, the lack of a standardized multidisciplinary collaborative care system has become a critical bottleneck hindering the reduction of AMI-CS mortality. To address these unmet clinical needs, this study aims to develop a tailored multidisciplinary collaborative care system adapted to China's healthcare landscape and to evaluate its clinical efficacy and safety via a prospective multicenter registry study. The study will establish a tiered collaborative network encompassing healthcare institutions of all levels and formulate standardized clinical pathways and risk stratification strategies for AMI-CS. A total of at least 1,000 AMI-CS patients will be enrolled in the study, with systematic collection of their clinical characteristics, multidisciplinary interventions, MCS utilization, and prognostic outcomes to build a high-quality real-world database. Based on the registry data, a China-specific risk stratification model for AMI-CS will be developed by integrating clinical metrics, biomarkers, and imaging features. This study will assess the benefits and risks of MCS devices used alone or in combination, and evaluate the implementation effectiveness of the multidisciplinary collaborative care system by comparing core outcomes-including 30/180-day all-cause mortality, severe complication rates, and door-to-balloon times-before and after the system's rollout and across healthcare institutions of different tiers. Additionally, this study will explore the key factors influencing the efficacy of multidisciplinary collaboration to inform the optimization of the care system. This study is expected to validate the feasibility and effectiveness of the multidisciplinary collaborative care system in the Chinese clinical setting, reduce AMI-CS mortality, narrow the gap in care capacity across different-tier hospitals, and fill the evidence gap in multidisciplinary AMI-CS management for the Chinese population.
NCT07179276
Sepsis is a dysregulated host response to infection that leads to life-threatening organ dysfunction and represents a major healthcare problem. Septic shock is the most severe form, characterized by increased capillary permeability and vasodilation, resulting in hypotension and tissue hypoxia. Early identification and treatment of tissue hypoperfusion are pivotal components of initial resuscitation to limit progression to multiple organ dysfunction and death. The 2021 Surviving Sepsis Guidelines recommend guiding initial resuscitation by targeting decreases in serum lactate levels in patients with elevated lactate. However, although elevated lactate levels may reflect tissue hypoxia, serum lactate is not a direct marker of tissue perfusion. Hyperlactatemia may be attributable to mechanisms other than tissue hypoperfusion, such as accelerated aerobic glycolysis driven by excessive β-adrenergic stimulation or impaired clearance (e.g., in liver failure). The venous-to-arterial carbon dioxide partial pressure difference (CO₂ gap), which is inversely related to cardiac output, has been shown to reflect the adequacy of venous blood flow to remove CO₂ from tissues. The CO₂ gap is closely linked to microcirculatory blood flow during the early resuscitation phase of septic shock and may effectively identify persistent tissue hypoperfusion in shock states. A persistently high CO₂ gap during early resuscitation has been associated with significantly higher 28-day mortality and increased Sequential Organ Failure Assessment (SOFA) scores. Moreover, the CO₂ gap has been shown to respond to changes in cardiac output during inotrope infusion in patients with low blood flow, suggesting that its assessment could be useful for therapeutic adjustments. Therefore, there are compelling arguments to evaluate the usefulness of the CO₂ gap in guiding early resuscitation in patients with septic shock. The investigators postulated that CO₂ gap-guided early resuscitation may be more effective in improving outcomes than lactate-guided resuscitation.
NCT06709573
The goal of the CASPER-Pilot study is to develop clinical decision support (CDS) technology within Epic to randomize patients with septic shock to early versus standard of care vasopressin initiation. The primary aim of this study will be to test the hypothesis that CDS technology can be utilized to create two distinct cohorts of patients reflecting different times of vasopressin initiation based on norepinephrine dose requirements. Secondarily, this study will evaluate the proportion of patients whose norepinephrine dose at the time of vasopressin initiation is within the specified range for the intervention arm they were randomized to. Other outcomes of evaluation will include adherence to the developed CDS technology and comparison of clinical outcomes between the two treatment arms.