EAST 2016 Plenary Papers

Adipose tissue location and contribution to postinjury hypercoagulability

Winfield, Robert D. MD; Mellnick, Vincent M. MD; Chamieh, Jad MD; Nohra, Eden MD; Tan, Wen-Hui MD; Ramirez, Ricardo MD; Raptis, Constantine MD; Turnbull, Isaiah R. MD, PhD; Bochicchio, Kelly RN; Reese, Stacey MS, RN; Spinella, Philip C. MD; Bochicchio, Grant V. MD, MPH

Author Information

From the Department of Surgery (R.D.W.), University of Kansas Medical Center; Department of Radiology (V.M.M., C.R.), Washington University School of Medicine; Department of Surgery (J.C., E.N., W-H.T., R.R., I.R.T., K.B., S.R., G.V.B.), Washington University School of Medicine; and Department of Pediatrics (P.C.S.), Washington University School of Medicine, St. Louis, Missouri.

Submitted: November 30, 2015, Revised: February 23, 2016, Accepted: March 7, 2016, Published online: April 27, 2016.

This study was presented at the 29th annual meeting of the Eastern Association for the Surgery of Trauma, January 12–16, 2016, in San Antonio, Texas.

Address for reprints: Robert D. Winfield, MD, University of Kansas Medical Center, Mail Stop 2005, 3901 Rainbow Blvd, Kansas City, KS 66160; email: [email protected].

Journal of Trauma and Acute Care Surgery 81(1):p 79-85, July 2016. | DOI: 10.1097/TA.0000000000001096

Abstract

OBJECTIVES

Obesity is associated with a hypercoagulable state at baseline and following injury. The anatomic location of adipose deposition may influence the type of thrombotic event, with visceral adipose tissue (VAT) associated with arterial thrombosis and subcutaneous adipose tissue (SAT) predisposing to venous thrombosis. We sought to determine whether adipose tissue amount and location correlated with measures of coagulation.

METHODS

All adult Level I trauma activations at our institution between January 2013 and August 2014 who underwent admission abdominal computed tomography scan and had admission rotational thromboelastometry measurements were included. Patients were excluded for history of anticoagulant use and known coagulopathy/hypercoagulable state. Admission computed tomography was used to obtain cross-sectional VAT and SAT areas at the umbilicus utilizing a novel software system; VAT and SAT measurements were associated with markers of coagulation utilizing Spearman correlation and stepwise linear regression with significance set at p < 0.05.

RESULTS

Two hundred forty-two patients met inclusion and exclusion criteria. Sixty-nine percent of patients sustained blunt injury, 79% were male, mean age was 40 years, 25% were obese or morbidly obese, and mean Injury Severity Scale score was 17. Seventeen percent of patients had acute deep venous thrombosis or pulmonary embolism during hospitalization. Neither SAT nor VAT correlated with prothrombin time, international normalized ratio, or partial thromboplastin time. Subcutaneous adipose tissue correlated positively with platelet count. Visceral adipose tissue and SAT correlated negatively with clot formation time and positively with TEM fibrinogen, α angle, maximum clot firmness, and lysis at 30 minutes; stronger correlations and greater significance were seen between SAT and these measures except for lysis at 30 minutes. Stepwise linear regression confirmed significant relationships between SAT and clot formation time, AA, and maximum clot firmness; VAT showed a significant relationship with TEM fibrinogen.

CONCLUSIONS

Increased adipose tissue correlates with relative hypercoagulability following trauma. Subcutaneous adipose tissue shows a stronger relationship with functional measures of coagulation, suggesting that SAT may be associated with hemorrhage resistance and hypercoagulability after injury.

LEVEL OF EVIDENCE

Prognostic study, level IV.

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Adipose tissue location and contribution to postinjury hypercoagulability