Conference Lectures

Intraoperative Hypotension and Perioperative Ischaemic Stroke – Strategies for Prevention and Management
Dr C L Gurudatt, Professor and Head, Mysore Medical College and Research Institute, Mysore
Stroke can be a catastrophic outcome for patients undergoing noncardiac, nonneurologic surgery and is associated with an adjusted 8-fold increase in mortality.. Unlike stroke in the community setting, the mechanistic cascade leading to perioperative stroke has a discrete and highly-predictable origin: surgical intervention.
Definition and Identifying patients at high risk of stroke
  “perioperative stroke” is defined as a brain infarction of ischaemic or haemorrhagic aetiology that occurs during surgery or within 30 days after surgery.
The incidence of stroke in a broad surgical population (excluding cardiac, carotid, major vascular and neurologic surgery) is approximately 1 per 1000 cases and approximately 6 per 1000 cases after major vascular surgery below the diaphragm.  The significant majority of perioperative strokes are ischaemic rather than haemorrhagic.  Three of the most consistent risk factors for perioperative stroke identified in the literature are advanced age, renal failure, and a history of stroke or transient ischaemic attack.  In general terms, all patients presenting for surgery with a history of cerebrovascular compromise should be regarded as high risk for perioperative stroke.
Beta -Blockers and Hypotension
The original PeriOperative Ischemic Evaluation (POISE) trial, which evaluated the cardioprotective effects of metoprolol in 8351 noncardiac surgery patients, demonstrated that patients receiving metoprolol had a significantly higher risk of stroke. Current guidelines endorse the perioperative continuation of beta blockers in surgical patients who are already taking this class of drug. To avoid perioperative stroke, anaesthesiologists should not apply high-dose beta-blockers immediately before the operation. To treat intraoperative tachycardia with beta-blockers, it has to be excluded that tachycardia is caused by hypotension, anaemia, or pain.  A meta-analysis by Bangalore et al. found an increased risk of nonfatal stroke, hypotension, and bradycardia with the use of beta-blockers in patients undergoing noncardiac surgery. Importantly, it is unclear in studies, including POISE, whether the hypotension occurred immediately before the stroke or after. POISE reports “clinically significant hypotension,” defined as a systolic blood pressure of less than 100 mmHg for an unspecified time, as an “intraoperative and postoperative predictor” of stroke, but the results do not state the temporal relationship between hypotension and the stroke, and also fail to specify if the hypotension was intraoperative or postoperative. Postoperative hypotension occurring on the ward is likely to be prolonged and therefore potentially more detrimental than intraoperative hypotension, which is usually easily detected. There is consensus that patients chronically on beta blockers should be kept on their drugs through the perioperative period, and that caution is needed when these agents are begun immediately before surgery.
It is unclear whether the stroke rate is increased with other antihypertensive or sympatholytic agents, such as clonidine and dexmedetomidine. The introduction of these drugs in the perioperative period could increase vulnerability to cerebral ischemia, as the compensatory mechanisms to cope with hypotension are attenuated because of hypovolemia and blood loss. Clinical trials will be needed to address this.

Stroke Prevention – Risk Modification
Timing of Surgery after Stroke
Patients with acute or recent stroke have impaired cerebrovascular autoregulation and chemoregulation for months, rendering them dependent on systemic pressure and passive perfusion. This dependence creates particular risk for cerebral hypoperfusion, especially in the setting of general anaesthesia and the physiologic perturbations of surgery (such as haemorrhage, anaemia, hypotension). “It has been suggested that elective surgery should be delayed from 1 to 3 months after a stroke in order to prevent a secondary cerebrovascular event.”  Known carotid disease should be treated based on current guidelines . The decision to proceed with surgery will always be a balance between the risks of perioperative stroke and the risks of delaying surgery further.
Management of Anti-coagulants and Antiplatelet Drugs
There are two common clinical scenarios in which management of anticoagulants or antiplatelet drugs can be linked to risk of perioperative stroke. The first is management of anticoagulants for patients with atrial fibrillation, a major risk factor for perioperative stroke, and the second is the management of aspirin in patients with cardiovascular or cerebrovascular disease (e.g., for primary or secondary stroke prevention). The clinical dilemma relates to balancing the risks of excessive perioperative bleeding and the risk of rebound hypercoagulability in the setting of the prothrombotic state induced by surgery.  Recently, the POISE-2 trial demonstrated that perioperative aspirin did not reduce the incidence of death or nonfatal myocardial infarction after noncardiac surgery, but did increase the risk of major bleeding.  Of note, patients who had aspirin therapy that was initiated in the course of the study had a reduced incidence of stroke compared to placebo; patients who were continuing aspirin therapy showed no reduction in stroke incidence. However, the results suggest that some patients at risk of stroke may benefit from preoperative initiation of aspirin therapy, but this must be balanced against the now well-documented risk of significant increases in bleeding and must be demonstrated in a larger trial.
ANAESTHESIA TECHNIQUE
A recent retrospective review of 57,000 patients revealed no difference in stroke risk between regional and general anesthesia in noncardiac patients. However, a large database study (>200,000 patients) focusing on knee and hip arthroplasty found that neuraxial anesthesia was associated with a lower incidence of stroke (0.07%) compared to combined neuraxial/general anesthesia (0.12%) and general anesthesia (0.13%, p=0.006). Good anaesthetic technique may play a role in reducing the incidence of cerebral complications. This may include careful positioning of the head and neck, and the early treatment of hypotensive episodes. Patients at risk should be well hydrated throughout the perioperative period.
VENTILATION STRATEGIES
Intraoperative hyperventilation has multiple systemic deleterious effects including: reduced lung compliance and potential for reduced oxygenation (from impaired V/Q mismatch and increased shunt); increased myocardial  oxygen demand and reduced supply (coronary vasoconstriction); potential dysrhythmias; and reduced cerebral blood flow; It seems likely that hypocapnia, because of the reduction in cerebral blood flow, is undesirable in patients with risk factors for perioperative stroke and may be one of several factors that negatively affect outcome in those patients who suffer stroke perioperatively.
HAEMOGLOBIN CONCENTRATION
For noncardiac, nonneurologic surgical patients already taking a beta blocker, a haemoglobin <9.0 gm/dl should be avoided in order to minimize risk of stroke. Haemodilution has been suggested as a therapy after ischaemic brain injury. Oxygen delivery has been shown to improve with a decrease in haematocrit to 30% via a reduction in viscosity. Unfortunately, current data do not support the routine use of haemodilution, except as an adjunct in the treatment of vasospastic ischaemia. Given the importance of haemoglobin in determining the oxygen carrying capacity of the blood, profound anaemia may contribute to cell energy dysfunction during cerebral hypoperfusion. Consequently, major perioperative haemorrhage is linearly associated with subsequent stroke in noncardiac and non-neurosurgical operations. Therefore, expert opinion suggests maintaining haemoglobin level of 10mg/dl or higher in all patients with a medium or high risk for perioperative stroke.
INTRAOPERATIVE GLUCOSE MANAGEMENT
Most authors recommend an intervention with serum glucose exceeding 150 mg/dL, with an absolute upper limit of 180 mg/dL, in hyperglycemic patients undergoing major surgery. Care should be taken to avoid hyperglycemia and hypoglycemia and to keep blood glucose concentration in an optimal range. It is suggested that insulin therapy should be started when blood glucose concentration exceeds 150mg/dl with an absolute upper limit of 180mg/dl.  In patients at high risk for perioperative stroke undergoing surgery, glucose monitoring is recommended, with a target range of 60-180 mg/dL .

INTRA OPERATIVE HYPOTENSION
More recently, Bijker et al conducted a retrospective case-control study reviewing 48,241 consecutive noncardiac and nonneurosurgical patients and found an overall stroke incidence of 0.09% within 10 days of surgery. They determined that a decrease in intraoperative mean arterial pressure of more than 30% below baseline was associated with postoperative stroke. However, the odds ratio of 1.013 reveals an effect size of unclear clinical significance. They concluded that the most widely proposed mechanism of a postoperative stroke is arterial embolism. Nonetheless, the results of the study supported the hypothesis that hypotension can influence the evolution of a postoperative stroke by compromising (collateral) blood flow to ischemic areas. In this context, hypotension is best defined as a decrease in mean blood pressure relative to a preoperative baseline, rather than an absolute low blood pressure value. The authors posit that unrecognized or poorly quantified hypotension in the postoperative period may be more important to stroke genesis than hypotension during the highly monitored and regulated intraoperative period and suggest that intraoperative hypotension may be predictive of postoperative haemodynamic instability rather than an independent cause of postoperative stroke.
Postural hypotension may also play a role in stroke after noncardiac surgery. In 2005, Pohl and Cullen  reported four cases of ischemic brain and spinal cord injury after shoulder surgery in the beach chair position. Since that time, significant attention has been given to the risk of unrecognized reduced cerebral perfusion pressures and resultant neurologic injury in the beach chair position. Neurologic injuries have occurred in the beach chair position at recorded blood pressures that most anesthesiologists would consider acceptable.  Assuming a 0.8mm Hg decrease in MAP for every 1 cm gradient, and a 15-30 cm gradient between the brachial artery (cuff measurement) and the brainstem, the Mean Arterial Pressure(MAP) at the level of the brainstem could be 12-24mm Hg lower than the pressure measured by cuff on the nonoperative arm. Clearly this relationship is greatly worsened if the cuff is placed on the lower extremity. This differential should also be kept in mind when leveling a transducer if invasive blood pressure monitoring is used.
It seems that there is an association between intraoperative hypotension and perioperative stroke, but the clinical significance of this association is poorly defined. Further prospective research is clearly necessary to make strong evidence-based recommendations regarding intraoperative blood pressure management. It is probable that there are subsets of patients at increased risk for stroke who clearly are harmed by hypotension or low flow states. Some of these populations may include patients with unrecognized critical stenosis of carotid or intracranial arteries or congenital anomalies of the cerebral circulation.
There are data to support an association between intraoperative hypotension and perioperative stroke. As such, intraoperative hypotension should be avoided in patients at high risk of perioperative stroke. Blood pressure be maintained within 20% of the patient’s normal range with a cerebral perfusion pressure greater than 70 mm Hg if possible. Intraoperative hypotension should be defined as a percent reduction from baseline blood pressure rather than an absolute value.  For surgery in the beach chair position, noninvasive blood pressure measurement by cuff should always be performed on the nonoperative upper arm (as opposed to lower extremity) and consideration should be given to the blood pressure gradient between the brachial artery and brain.  Induced hypotension for shoulder surgery in the beach chair position should always be approached with caution; especially in patients at risk for stroke. Monitoring
Intraoperative neuromonitoring should be able to detect an insufficient supply of the brain with blood/oxygen before a stroke occurs. Noninvasive neuromonitors play an important role in reducing the perioperative stroke rate. The value of transcranial Doppler sonography (TCD) and electroencephalography (EEG) is already well established in high-risk operations such as carotid endarterectomy.  It is essential to detect perioperative stroke as soon as possible and, thereby, treat the patient early. If the patient is awake after anaesthesia, the Face Arm Speech Test (FAST) seems to be sufficient to detect an acute stroke.
Management
Techniques that are used to minimize the injury to the brain in the event of an ischemic insult can be thought of as having three broad purposes: to increase the supply of oxygen to the injured tissue, to reduce the metabolic demands, or to affect specific pathways in the ischemic cascade to reduce the production of unwanted metabolites.
In the event of an acute stroke, preventing secondary injury and achieving optimal outcome are based on rapid recognition, communication and management. Evaluation and treatment of acute perioperative stroke, which is typically ischaemic, should be consistent with the most recent American Heart Association Guidelines for the Management of Patients with Acute Ischemic Stroke.
Various physiologic, pharmacologic and pathologic factors in the postanaesthetic period can mask symptoms of intraoperative or postoperative stroke. Careful evaluation and resolution of pharmacologic contributions to a neurologic deficit is paramount to reduce delay in stroke diagnosis.  Certain drugs that are commonly used during the intraoperative period can be reversed, including narcotics (with naloxone), benzodiazepines (with flumazenil), and neuromuscular blockers (with a cholinesterase inhibitor or sugammadex, where available). Although the presence of residual inhaled anesthetics can be quantified routinely in the operating room at the end of a surgical case, the effect of drugs such as propofol and dexmedetomidine cannot be conveniently measured in real time. Delayed emergence, altered mental status and/or the presence of new focal neurologic deficit in the absence of convincing confounders should raise suspicion for stroke.
Immediate diagnostic studies of all patients with suspected stroke should include noncontrast computed tomography (CT) or magnetic resonance imaging (MRI) of the brain to determine
whether the stroke is ischemic or hemorrhagic in origin and to correlate neurologic deficit with radiologic findings. The role of CT angiography and CT perfusion imaging is to provide supplementary information, especially in determining the need for urgent endovascular
intervention. The presence of a large ischemic penumbra or thrombus in a major vessel (e.g., middle cerebral artery) would prompt consideration of endovascular therapy.
The initial treatment of stroke is usually best achieved in a subspecialty acute care setting such as a neurocritical care or stroke unit. Maintaining appropriate physiologic stability is critical during acute stroke care.  Hypoxaemia is associated with poor neurologic/ outcomes and should therefore be monitored with pulse oximetry; supplemental oxygen should be used to maintain SpO2 saturation greater than 94%. The airway should be secured in patients with depressed levels of consciousness (Glasgow Coma Scale <8), signs of brainstem dysfunction, or inability to protect the airway. Tracheal intubation and mechanical ventilation may also be helpful in the management of increased intracranial pressure or for those who have suspected malignant
brain edema. Both hypertension and hypotension are associated with poor outcome after stroke. Urgent correction of common postoperative causes of hypotension, including volume depletion, blood loss, myocardial ischemia, or arrhythmias, may improve neurologic outcomes.
Patients with acute cerebral ischaemia should have cardiac monitoring for at least the first 24 hours, and any serious arrhythmia should be treated.  Myocardial ischaemia and cardiac arrhythmias are potential sequelae of acute cerebrovascular disease and systemic hypertension is common after stroke. Common postoperative conditions that may contribute to hypertension include stress response to surgery, pain, nausea, hypervolaemia, full bladder, or physiological response to hypoxia. Every effort should be made to preserve cerebral perfusion pressure during the first 24 hours. Unless the patient is eligible for acute reperfusion intervention, systolic blood pressure is usually treated only if it is greater than 220mm Hg, and diastolic pressure is treated only if it is greater than 120mm Hg.
Intravenous recombinant tissue plasminogen activator(rtPA) is the drug of choice for thrombotic strokes, but it is contraindicated in a number of situations .  Importantly, major surgery with the exception of intracranial or spinal surgery is a relative rather than absolute contraindication, but there is a paucity of literature regarding the management of stroke after a noncardiac, nonvascular or nonneurologic procedure.

CONCLUSION
Recognition of patients at high risk for stroke during or after noncardiac, nonneurologic surgery is critical. Consistent risk factors include advanced age, renal disease and history of stroke or transient ischemic attack. Continuation of beta blockers and statins is important for prevention; Recent evidence suggests that continuation of aspirin in patients at risk of stroke after noncardiac surgery is not indicated and may increase bleeding risk. Intraoperative hypotension should be avoided in surgical patients at high risk of perioperative stroke and for those in the beach chair position. For surgical patients manifesting symptoms or signs of stroke, timely neurology/stroke consultation and emergent neuroimaging are essential. Major noncardiac, nonneurologic surgery is not an absolute contraindication to intravascular administration of rtPa; mechanical thrombolysis is also an option for those at high risk of surgery-related haemorrhage.
 References

1. Mashour G A, Moore L E, Lele A V, Robicsek S A, and Gelb A W, Perioperative Care of Patients at High Risk for Stroke during or after Non-Cardiac, Non-Neurologic Surgery: Consensus Statement from the Society for Neuroscience in Anesthesiology and Critical Care J Neurosurg Anesthesiol 2014;00:000–000) 
2.  Talke PO, Sharma D, Heyer EJ, et al. Society for Neuroscience in Anesthesiology and Critical Care expert consensus statement: Anesthetic management of endovascular treatment of acute ischemic stroke. J Neurosurg Anesthesiol. 2014;26:95–108.)
3. Sharifpour M, Moore LE, Shanks AM, et al. Incidence, predictors, and outcomes of perioperative stroke in noncarotid major vascular surgery. Anesth Analg. 2013;116:424–434.
4.  Ng JL, Chan MT, Gelb AW. Perioperative stroke in noncardiac, nonneurosurgical surgery. Anesthesiology. 2011;115:879–890.
5. Bangalore S, Wetterslev J, Pranesh S, et al. Perioperative beta blockers in patients having non-cardiac surgery: A meta-analysis. Lancet. 2008;372:1962–1976.)
6.   Bijker JB, Persoon S, Peelen LM, et al. Intraoperative hypotension and perioperative ischemic stroke after general surgery: A nested case-control study. Anesthesiology. 2012;116:658–664.
7.  Pohl A, Cullen DJ. Cerebral ischemia during shoulder surgery in the upright position: A case series. J Clin Anesth. 2005;17:463–469