The Reciprocal Relationship Between Cardiac Baroreceptor Sensitivity and Cerebral Autoregulation During Simulated Hemorrhage in Humans

Abstract

Tolerance to reduced central blood volume (e.g., via hemorrhage) depends upon cardiovascular and cerebrovascular mediated compensatory mechanisms to preserve cerebral perfusion. Prior studies have demonstrated a reciprocal relationship between the arterial baroreflex and cerebral autoregulation (CA) at rest and in response to acute hypotension. It is unknown if this reciprocal relationship persists during progressive and sustained hypotension simulating hemorrhage. We hypothesized that the reciprocal relationship between cardiac baroreceptor sensitivity (BRS) and CA would be maintained during a simulated hemorrhage induced by maximal lower body negative pressure (LBNP), and that the strength of this relationship would be greater in subjects with higher tolerance to this stress. Healthy young adults (n=51; 23F/28M, 26 ± 4 y) completed a step-wise LBNP protocol until the onset of presyncope. Subjects were classified as high tolerant (HT) if they completed at least the -60 mmHg stage of LBNP (≥ 20-min), and low tolerant (LT) if they became presyncopal prior to completing the -60 mmHg stage of LBNP (< 20-min), as previously defined by our group. Heart rate (HR), mean arterial pressure (MAP), stroke volume (SV), and middle cerebral artery velocity (MCAv) were measured continuously. The absolute change from baseline to presyncope (Δ) was calculated for each variable. Cardiac BRS was calculated as ΔHR divided by ΔMAP, and CA was calculated as ΔMCAv divided by ΔMAP. The relationship between BRS and CA was assessed with Pearson's correlation coefficients for the entire group of 51 subjects, and within the HT and LT sub-groups. Absolute change values for the hemodynamic responses were also compared between the two tolerance groups. By design, tolerance to LBNP was different between the groups (HT (n=30): 1775 ± 225 s vs. LT (n=21): 1184 ± 253 s; P<0.0001). Accordingly, HT subjects demonstrated a greater ΔSV (HT: -51 ± 17 ml vs. LT: -41 ± 13 ml; P=0.03) and a greater ΔHR (HT: +56 ± 17 bpm vs. LT: +34 ± 20 bpm; P<0.0001) in response to maximal LBNP. Interestingly, ΔMAP (HT: -18 ± 7 mmHg vs. LT: -19 ± 9 mmHg; P=0.51), ΔMCAv (HT: -17 ± 8 cm/s vs. LT: -19 ± 10 cm/s; P=0.52), BRS (HT: 4 ± 3 bpm/mmHg vs. LT: 3 ± 4 bpm/mmHg; P=0.24), and CA (HT: 1.2 ± 0.9 cm/s.mmHg-1 vs. LT: 1.5 ± 1.8 cm/s.mmHg-1; P=0.45) were similar between HT and LT subjects. In support of our hypothesis, there was a strong reciprocal relationship (R=0.77; P<0.0001) between BRS and CA in the group of 51 subjects. When independently assessing this relationship within each tolerance group, however, there was a stronger relationship in LT subjects (R=0.94; P<0.0001) compared to HT subjects (R=0.57; P<0.001). In support of our hypothesis, the reciprocal relationship between cardiac BRS and CA was maintained during sustained and progressive hypotension, but this relationship was stronger in subjects with lower tolerance to this stress. These findings suggest that despite a strong overall relationship in the interaction between BRS and CA, it may not be a primary compensatory mechanism that dictates tolerance to simulated hemorrhage in young healthy adults.