Volume-related Weight Gain As an Independent Indication for Renal Replacement Therapy in the Intensive Care Units

Overview

Journal J Renal Inj Prev

Specialty Nephrology

Date 2017 May 11

PMID 28487870

Citations 2

Authors

Tibor Fulop

Lajos Zsom

Mihaly B Tapolyai

Miklos Z Molnar

Laszlo Rosivall

Affiliations

Soon will be listed here.

Abstract

Attempts to identify specific therapies to reverse acute kidney injury (AKI) have been unsuccessful in the past; only modifying risk profile or addressing the underlying disease processes leading to AKI proved efficacious. The current thinking on recognizing AKI is compromised by a "kidney function percent-centered" viewpoint, a paradigm further reinforced by the emergence of serum creatinine-based automated glomerular filtration reporting over the last two decades. Such thinking is, however, grossly corrupted for AKI and poorly applicable in critically ill patients in general. Conventional indications for renal replacement therapy (RRT) may have limited applicability in critically ill patients and there has been a relative lack of progress on RRT modalities in these patients. AKI in critically ill patients is a highly complex syndrome and it may be counterproductive to produce complex clinical practice guidelines, which are labor and resource-intensive to maintain, difficult to memorize or may not be immediately available in all settings all over the world. Additionally, despite attempts to develop reliable and reproducible biomarkers to replace serum creatinine as a guide to therapy such biomarkers failed to materialize. Under such circumstances, there is an ongoing need to reassess the practical value of simple measures, such as volume-related weight gain (VRWG) and urine output, both for prognostic markers and clinical indicators for the need for RRT. This current paper reviews the practical utility of VRWG as an independent indication for RRT in face of reduced urine output and hemodynamic instability.

Citing Articles

Effect of furosemide on body composition and urinary proteins that mediate tubular sodium and sodium transport-A randomized controlled trial.

Mose F, Oczachowska-Kulik A, Fenton R, Bech J Physiol Rep. 2020; 8(24):e14653.

PMID: 33356004 PMC: 7757674. DOI: 10.14814/phy2.14653.

Therapeutic hypernatremia management during continuous renal replacement therapy with elevated intracranial pressures and respiratory failure.

Fulop T, Zsom L, Rodriguez R, Chabrier-Rosello J, Hamrahian M, Koch C Rev Endocr Metab Disord. 2019; 20(1):65-75.

PMID: 30848433 DOI: 10.1007/s11154-019-09483-2.

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