The purpose of this study is to assess cerebral blood flow velocity (CBFV) following regional anesthesia for shoulder surgery. The results of this study will help to further understand the physiologic effect of the interscalene nerve block on cerebral blood flow.
Traditionally, cerebral blood flow (CBF) is believed to decline when mean arterial pressure (MAP) is below the lower limit of cerebral autoregulation. Cerebral blood flow autoregulation refers to the capacity of the central nervous system to maintain blood flow within a wide range of mean arterial blood pressure. The habitual thinking is that the brain is perfused merely dependent by the blood pressure and that above or below the limits of cerebral autoregularion CBF is pressure passive. Despite this notion, there is evidence showing that parameters other than MAP influence cerebral hemodynamics independent of cerebral autoregulation. One of the physiologic processes that contribute to CBF regulation is cardiac output (CO). However, exactly how an alteration in CO, in the face of a stable blood pressure, leads to a change in CBF is not entirely clear. One of the suggested mechanisms in play is the sympathetic nervous system (SNS)-mediated vasoconstriction of extracranial and proximal intracranial vessels. Cerebral arteries are abundantly innervated by sympathetic nerve fibers originating from the superior cervical ganglion. Studies have shown that CBF reduction is attenuated by pharmacologic blockade or extirpation of the cervical sympathetic chain. The anesthetic protocol for patients undergoing major shoulder surgery include an interscalene nerve block (ISNB) combined with general anesthesia in the sitting position. The ISNB involves injecting local anesthetic at the level of the cervical spinal roots. One of the most common side effects encountered after ISNB is Horner syndrome, which is characterized by ptosis, myosis, and enopthalmia. Horner's syndrome results from the diffusion of the local anesthetic solution to the ipsilateral sympathetic cervical chain (stellate ganglion). The presence of Horner's syndrome indicates spread of local anesthetic to the sympathetic chain. Whether this degree of sympatholytic following interscalene block is associated with an observable change in CBF is unknown. Studies in baboon have shown that cervical surgical sympathectomy maintained CBF in the face of hemorrhagic hypotension and CBF did not decrease until MAP was 35% of the baseline value. These results suggest that sympathectomy induced by the block of the sympathetic chain by the local anesthetic injected for the ISNB might alter CBF. Therefore, the aim of our study is to evaluate the effect of unilateral interscalene nerve block on CBF by measuring CBF velocity non-invasively with Transcranial doppler (TCD).
Study Type
OBSERVATIONAL
Enrollment
10
CBFV measurements will be acquired continuously with the patient supine and the head neutral. Analysis of CBFV measurements will be undertaken at 3 timepoints: 1. Patient awake and supine in the holding area 2. After sedation 3. After interscalene nerve block
Stanford University School of Medicine
Stanford, California, United States
Cerebral Blood Flow Velocity before and after interscalene nerve block
The TCD automatically measures blood flow velocity in the main cerebral arteries of the circle of Willis. We will target the MCA which is the closest to the temporal bone therefore the most easily accessible for insonation and monitoring. We will do a bilateral monitoring.
Time frame: baseline, after 30 minutes
Systolic, diastolic, mean blood pressure changes before and after interscalene nerve block
Will be measured before/during/after interscalene nerve block placement
Time frame: baseline, after 30 minutes
Heart Rate
Will be measured before/during/after interscalene nerve block placement
Time frame: baseline, after 30 minutes
Respiratory Rate changes before and after interscalene nerve block
Will be measured before/during/after interscalene nerve block placement
Time frame: baseline, after 30 minutes
EtCO2 changes before and after interscalene nerve block
Will be measured before/during/after interscalene nerve block placement
Time frame: baseline, after 30 minutes
SpO2 changes before and after interscalene nerve block
Will be measured before/during/after interscalene nerve block placement
Time frame: baseline, after 30 minutes
Type of local anesthetic
Local anesthetic characteristics will be collected after interscalene block placement.
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Time frame: 30 minutes after the nerve block
Position of the needle on the cervical trunk for interscalene nerve block
Needle position for interscalene nerve block insertion will be assessed at the time of interscalene block placement
Time frame: Baseline
Volume of of local anesthetic
Local anesthetic characteristics will be collected after interscalene block placement.
Time frame: 30 minutes after the nerve block
Concentration of local anesthetic
Local anesthetic characteristics will be collected after interscalene block placement.
Time frame: 30 minutes after the nerve block