Benefit and Safety of Isovolemic Hemodilution Prior to Red Cell Exchange in Chronically Transfused Sickle Cell Patients

Background: Isovolemic hemodilution (IHD-RCE), an add-on to standard red cell exchange (RCE), was recently FDA-approved on select apheresis devices. Equipoise exists as to the degree of red cell unit reduction and time interval extension between procedures with IHD-RCE. Also, concern has been raised that the transient hematocrit (Hct) decrease and potential hypotension with IHD-RCE causes ischemic brain injury, especially with Moya Moya disease. Again, there is equipoise, with only one of 4 studies reporting increased hypotension and no studies of ischemic brain injury with IHD-RCE. We therefore conducted a retrospective crossover study of efficacy and safety of IHD-RCE in our sickle cell disease patients, three of whom had Moya Moya, and report follow-up brain MRI/MRA data, heretofore not reported in the literature. Study design: This was a retrospective review of patients who crossed over from standard RCE (Cobe Spectra) to IHD-RCE (Spectra Optia). The IHD phase used normal saline for replacement fluid. Minimum (post-IHD) hematocrits (Hcts) and post-procedure Hcts were based upon pre-procedure Hcts as per Matevosyan et al, JCA 2012. Pre-procedure CBCs, reticulocyte counts, and serum ferritins were drawn within 72 hours of the procedure and post-procedure CBCs drawn immediately post-procedure. All red cell units were leuko-reduced, CEK matched, and less than 15 days old when possible. Methods: The same number of procedures were analyzed for standard RCE and IHD-RCE, with the RCE procedures most recent to crossover to IHD-RCE used for comparison. Means of continuous variables were calculated for each patient; means and standard deviations of the patient means are shown, unless otherwise indicated. Paired t-testing was used to compare IHD-RCE to RCE († in tables indicates p-value < 0.05) Results: Patients: All 6 patients (3 M, 3 F) were black; 5 had HbSS and 1 had SB+thal. The indication for RCE was stroke prophylaxis in four, 3 of whom had Moya-Moya disease, and frequent vaso-occlusive crisis (VOC) in two. Mean patient age at the time of first IHD-RCE was 15 ± 2 years, and a mean 26 ± 12 procedures of each procedure type was analyzed for IHD-RCE to RCE comparisons. Patient total blood volume (TBV) significantly increased from the RCE to IHD-RCE periods and was accounted for in the analysis. Procedure-centric measures (Table 1). Despite increasing TBV, red cell unit usage did not increase, and the volume of donor red cells transfused per mL TBV significantly decreased with IHD-RCE. There was no increase in inter-procedural interval. Patient-centric efficacy measures (Table 2): Despite the decreased volume of donor red cells transfused per mL TBV, and similar post- and pre-procedure HbS %s between IHD-RCE and RCE, the pre-procedure Hct was slightly (5%) increased with IHD-RCE. Procedural safety-related measures (Table 3): Although there were statistically significant drops in systolic and diastolic blood pressures (BP) post-IHD compared to pre-procedure BP, the degrees (about -6%) were mild. By procedure end, there were no overall significant differences in BP from pre-procedure BP. In addition, there was no overall significant change in heart rate post-IHD or post-procedure. Actual patient adverse events (Table 4): One patient had a single possibly IHD-related Grade 2 symptomatic (dizziness) vasovagal event, occurring at procedure end and resolved with normal saline bolus. All 4 patients on IHD-RCE for stroke prophylaxis had follow-up MRI/MRA after switching to IHD-RCE. One patient showed new silent strokes and vasculopathy but her prior MRI/MRA predated her standard RCE period. One patient who had progressed on standard RCE had no progression on IHD-RCE. The other two patients had stable MRI/MRA. Conclusion: When reducing pre-procedure Hct by 20-24% during the IHD phase, our data confirm the 11-13% reduction in red cell unit usage with IHD-RCE reported by Sarode et al, JCA 2011 and Hequet et al, Transfusion 2019, but do not support an increased inter-procedural interval of 16 days as per Sarode et al. Most patients had a mild (< 15%) and asymptomatic drop in systolic and diastolic BPs with IHD-RCE; a minority also had a very mild (<5%) HR increase; use of 5% albumin rather than saline replacement may mitigate these drops. MRI/MRA follow-up did not show any definitive ischemic brain injury associated with IHD-RCE. Disclosures No relevant conflicts of interest to declare.

Modulation of Myocardial Oxygen Delivery in Response to Isovolemic Hemodilution

Background and Hypothesis: Prior studies have established that progressive increases in coronary blood flow are sufficient to maintain myocardial oxygen delivery in response to reductions in arterial oxygenation. However, the precise mechanisms responsible for anemic coronary vasodilation remain poorly understood. This investigation tested the hypothesis that autonomic neural pathways contribute to the maintenance of myocardial oxygen delivery in response to graded reductions in arterial hematocrit. Experimental Design: Experiments were conducted in open-chest anesthetized swine while assessing coronary blood flow and coronary arterial and venous blood gases in response to progressive hemodilution. Isovolemic hemodilution was achieved via simultaneous removal of 250mL of arterial blood and addition of 250mL of a synthetic plasma expander (Hespan) in swine that received either vehicle or a combination of atropine (0.5mg/kg) and propranolol (1mg/kg) (Atro/Pro). Results: Relative to vehicle control swine, treatment with Atro/Pro increased heart rate by ~50±4 beats/min and arterial pressure by ~10±1 mmHg. However, Atro/Pro did not significantly alter increases in coronary blood flow in response to isovolemic hemodilution (hematocrits ranging from ~35±1% to ~15±1%). Coronary venous PO2, an index of myocardial oxygenation, was also unchanged by hemodilution in both vehicle and Atro/Pro treated swine. Conclusion and Potential Impact: These data suggest that autonomic neural pathways do not play a significant role in the maintenance of myocardial oxygen delivery in response to graded reduction in arterial oxygen content. Understanding of how myocardial oxygen supply is ultimately sensed and regulated in response to reductions in tissue oxygenation remains elusive.