Quantifying the Cerebral Hemometabolic Response to Blood Transfusion in Pediatric Sickle Cell Disease With Diffuse Optical Spectroscopies

Overview

Journal Front Neurol

Specialty Neurology

Date 2022 Jul 18

PMID 35847200

Authors

Seung Yup Lee

Rowan O Brothers

Katherine B Turrentine

Ayesha Quadri

Eashani Sathialingam

Kyle R Cowdrick

Scott Gillespie

Shasha Bai

Adam E Goldman-Yassen

Clinton H Joiner

R Clark Brown

Erin M Buckley

Affiliations

Soon will be listed here.

Abstract

Red blood cell transfusions are common in patients with sickle cell disease who are at increased risk of stroke. Unfortunately, transfusion thresholds needed to sufficiently dilute sickle red blood cells and adequately restore oxygen delivery to the brain are not well defined. Previous work has shown that transfusion is associated with a reduction in oxygen extraction fraction and cerebral blood flow, both of which are abnormally increased in sickle patients. These reductions are thought to alleviate hemometabolic stress by improving the brain's ability to respond to increased metabolic demand, thereby reducing susceptibility to ischemic injury. Monitoring the cerebral hemometabolic response to transfusion may enable individualized management of transfusion thresholds. Diffuse optical spectroscopies may present a low-cost, non-invasive means to monitor this response. In this study, children with SCD undergoing chronic transfusion therapy were recruited. Diffuse optical spectroscopies (namely, diffuse correlation spectroscopy combined with frequency domain near-infrared spectroscopy) were used to quantify oxygen extraction fraction (OEF), cerebral blood volume (CBV), an index of cerebral blood flow (CBF), and an index of cerebral oxygen metabolism (CMRO) in the frontal cortex immediately before and after transfusion. A subset of patients receiving regular monthly transfusions were measured during a subsequent transfusion. Data was captured from 35 transfusions in 23 patients. Transfusion increased median blood hemoglobin levels (Hb) from 9.1 to 11.7 g/dL ( < 0.001) and decreased median sickle hemoglobin (HbS) from 30.9 to 21.7% ( < 0.001). Transfusion decreased OEF by median 5.9% ( < 0.001), CBFi by median 21.2% ( = 0.020), and CBV by median 18.2% ( < 0.001). CMRO did not statistically change from pre-transfusion levels ( > 0.05). Multivariable analysis revealed varying degrees of associations between outcomes (i.e., OEF, CBF, CBV, and CMRO), Hb, and demographics. OEF, CBF, and CBV were all negatively associated with Hb, while CMRO was only associated with age. These results demonstrate that diffuse optical spectroscopies are sensitive to the expected decreases of oxygen extraction, blood flow, and blood volume after transfusion. Diffuse optical spectroscopies may be a promising bedside tool for real-time monitoring and goal-directed therapy to reduce stroke risk for sickle cell disease.

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