Electromechanical Alterations in the Cerebrovasculature of Stroke-Prone Rats

Abstract

Background and Purpose —Cerebrovascular pressure-dependent constriction (PDC) is associated with smooth muscle (SM) depolarization and Ca ²⁺ influx through voltage-gated channels. We studied the alterations in electromechanical contraction in the middle cerebral arteries (MCAs) of stroke-prone Wistar-Kyoto spontaneously hypertensive rats (SHRsp) in relation to the stroke-related loss of PDC. Methods —Constriction to pressure, elevated [K ⁺ ] _o and/or [Ca ²⁺ ] _o , and SM membrane potentials (E _m ) were measured in isolated pressurized MCAs of SHRsp and stroke-resistant SHR. Results —MCAs of SHRsp exhibited an age-related decrease in PDC before hemorrhagic stroke and a loss of PDC after stroke. At 100 mm Hg, the MCAs of poststroke SHRsp maintained partial constriction that was not altered with pressure but was inhibited by nifedipine (1 μmol/L). The MCAs of poststroke SHRsp constricted to vasopressin (0.17 μmol/L) but not to elevated [K ⁺ ] _o . When pressure was reduced from 100 to 0 mm Hg, the MCAs from young prestroke SHRsp exhibited SM hyperpolarization (−38 to −46 mV), whereas those of poststroke SHRsp maintained a constant, depolarized E _m (−34 mV). Alterations in E _m with varying [K ⁺ ] _o suggested that there was a decrease in SM K ⁺ conductance in the MCAs of poststroke SHRsp. Conclusions —The observation that the MCAs of poststroke SHRsp depolarize but do not constrict to elevated [K ⁺ ] _o suggests the presence of dysfunctional voltage-gated Ca ²⁺ channels. The inability to alter E _m with pressure or to constrict to depolarization could partially contribute to the loss of PDC in the MCAs of poststroke SHRsp.