Acute Kidney Failure Stage 3 Clinical Trial
Official title:
Venous Excess and Lung Ultrasound During Continuous Kidney Replacement Therapy in Critically Ill Patients (VExLUS-KRT)
Hemodynamic management of critically ill patients has long been focused on the arterial side of the vasculature by assessing adequate perfusion pressure. However, the venous pressure is also of critical importance. Venous congestion can occur in patients with right ventricular failure, pulmonary hypertension or fluid overload. Fluid overload has harmful effects to end organs causing acute kidney injury (AKI), lung edema, multiorgan dysfunction and death. Vice versa, AKI can aggravate fluid retention and inflammation. The measurement of venous pressure usually relies on central venous pressure (CVP) and inferior vena cava diameter (IVC). However, CVP measurement has been associated with measurement errors and has low accuracy in predicting fluid responsiveness. Moreover, IVC collapsibility or distensibility is a static parameter and is associated with subjective variability. Multiorgan Point-of-Care ultrasound (POCUS) can enhance the management of AKI by enabling the evaluation of renal structural abnormalities and hemodynamic status . POCUS allows the clinician to assess intravascular and pulmonary fluid overload. It has been shown that POCUS is a good parameter to predict global fluid status of the patient . Venous Excess Ultrasound (VEXUS) consists of the evaluation of IVC, hepatic vein, portal vein and intrarenal vein flow pattern. Previous studies showed significant correlation between VExUS score with RRT-free days and guide fluid management in critically ill patients with AKI . VExUS is useful in predicting patients at risk to develop AKI post cardiac surgery . Adding modified lung ultrasound score to the VExUS protocol could help clinician to adjust fluid administration and achieve proper fluid balance during continuous kidney replacement therapy (CKRT). However, the role of using combined VExUS and lung ultrasound in the assessment and guidance of fluid management during CKRT is unknown.
Lung and cardiac ultrasonography can augment the definite diagnosis of volume overload. Thoracic ultrasound demonstrating B-lines which suggest thickened interstitial or fluid filled alveoli or increased vena cava diameter by ultrasound can also be used to assess volume status. Recently, the venous excess ultrasound grading system (VExUS) has been introduced to be used in conjunction with POCUS to assess significant congestion. This technique was developed by Beaubien-Souligue in order to classify the level of venous congestion by assessing the abdominal blood flow, including hepatic veins (HVs), portal veins (PVs) and intrarenal veins (IRVs). Abnormal patterns of flow in these organs can enhance the clinical evaluation of venous congestion in addition to Inferior vena cava (IVC) ultrasound since organ dysfunction occurring with venous congestion can also be from the transmission of pressure from right atrium (right atrial pressure, RAP) to the peripheral organ. Venous congestion is classified into four grades , ranging from grade 0 (no congestion) to the most severe form, grade 3 (severe congestion) or VExUS "A" through "E" Lung ultrasound and AKI Volume overload is associated with interstitial edema which increases the diffusion distance for oxygen and induces an increase in interstitial fluid pressure, impairing capillary blood flow and exacerbating organ dysfunction . A prospective pilot observational study with 45 adult patients with AKI at any time during ICU stay employed the FALLS (Fluid Administration Limited by Lung Ultrasound) protocol in which they use the LUS for assessing volume status. A new onset of the B-lines was considered as the endpoint of fluid administration. The study demonstrated a linear correlation between baseline B-line scores and PaO2/FiO2 ratio in ICU patients VExUS and lung ultrasound during CKRT Previous studies have shown that VExUS and lung ultrasound may play a role in predicting AKI severity and may aid fluid de-escalation in critically ill patients. However, no studies have evaluated the role of both VExUS and lung ultrasound in guiding fluid management during CKRT. Our research aims to evaluate the prevalence of venous congestion by VExUS and lung ultrasound (VExLUS) during CKRT and its association with clinical outcomes. ;
| Status | Clinical Trial | Phase | |
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| Completed |
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