Extremity trauma exacerbates acute kidney injury following prolonged hemorrhagic hypotension

Lusha Xiang; Alfredo S Calderon; Harold G Klemcke; Ian L Hudson; Carmen Hinojosa-Laborde; Kevin K Chung; Kathy L Ryan

doi:10.1097/TA.0000000000003311

Extremity trauma exacerbates acute kidney injury following prolonged hemorrhagic hypotension

J Trauma Acute Care Surg. 2021 Aug 1;91(2S Suppl 2):S113-S123. doi: 10.1097/TA.0000000000003311.

Authors

Lusha Xiang¹, Alfredo S Calderon, Harold G Klemcke, Ian L Hudson, Carmen Hinojosa-Laborde, Kevin K Chung, Kathy L Ryan

Affiliation

¹ From the US Army Institute of Surgical Research (L.X., A.S.C., H.G.K., I.L.H., C.H.-L., K.L.R.), JBSA-Fort Sam Houston, Texas; and Uniformed Services University (K.K.C.), Bethesda, Maryland.

PMID: 34086661
DOI: 10.1097/TA.0000000000003311

Abstract

Background: The incidence of and mortality due to acute kidney injury is high in patients with traumatic shock. However, it is unclear how hemorrhage and trauma synergistically affect renal function, especially when timely volume resuscitation is not available.

Method: We hypothesized that trauma impairs renal tolerance to prolonged hemorrhagic hypotension. Sprague-Dawley rats were randomized into six groups: control, extremity trauma (ET), hemorrhage at 70 mm Hg (70-H), hemorrhage at 55 mm Hg (55-H), ET + 70 mm Hg (70-ETH), and ET + 55 mm Hg (55-ETH). Animals were anesthetized, and ET was induced via soft tissue injury and closed fibula fracture. Hemorrhage was performed via catheters 5 minutes after ET with target mean arterial pressure (MAP) clamped at 70 mm Hg or 55 mm Hg for up to 3 hours. Blood and urine samples were collected to analyze plasma creatinine (Cr), Cr clearance (CCr), renal oxygen delivery (DO2), urinary albumin, and kidney injury molecule-1 (KIM-1).

Results: Extremity trauma alone did not alter renal hemodynamics, DO2, or function. In 70-H, CCr was increased following hemorrhage, while Cr, renal vascular resistance (RVR), KIM-1, and albumin levels remained unchanged. Compared with 70-H, ET + 70 mm Hg exhibited increases in Cr and RVR with decreases in CCr and DO2. In addition, ET decreased the blood volume loss required to maintain MAP = 70 mm Hg by approximately 50%. Hemorrhage at 55 mm Hg and ET + 55 mm Hg exhibited a marked and similar decrease in CCr and increases in RVR, Cr, KIM-1, and albumin. However, ET greatly decreased the blood volume loss required to maintain MAP at 55 mm Hg and led to 50% mortality.

Conclusion: These results suggest that ET impairs renal and systemic tolerance to prolonged hemorrhagic hypotension. Thus, traumatic injury should be considered as a critical component of experimental studies investigating outcomes and treatment following hemorrhagic shock.

Level of evidence: This is an original article on basic science and does not require a level of evidence.

Publication types

Research Support, U.S. Gov't, Non-P.H.S.

MeSH terms

Acute Kidney Injury / etiology*
Animals
Blood Pressure
Extremities
Heart Rate
Hemorrhage / complications
Hemorrhage / etiology
Hindlimb / injuries*
Hypotension / complications
Hypotension / etiology
Male
Rats
Rats, Sprague-Dawley
Renal Circulation
Urodynamics