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Perioperative Visual Loss

Perioperative Visual Loss. Kevin Driscoll Matt Mitchell Carolyn Srinivasan. Epidemiology Anatomy Physiology Pathophysiology Treatment Prevention Considerations. Objectives. Vision Loss: Epidemiology & Anatomy. Incidence of perioperative visual loss (POVL) after non-ocular surgery

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Perioperative Visual Loss

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  1. Perioperative Visual Loss Kevin Driscoll Matt Mitchell Carolyn Srinivasan

  2. Epidemiology Anatomy Physiology Pathophysiology Treatment Prevention Considerations Objectives

  3. Vision Loss: Epidemiology & Anatomy

  4. Incidence of perioperative visual loss (POVL) after non-ocular surgery 0.002% of all surgeries (Newman, 2008) 0.2% of cardiac and spine surgeries (Newman, 2008) Any portion of the visual pathway may be involved Cornea to the occipital lobe Optic nerve Most common site of permanent injury Presumed mechanism is ischemia Anterior ischemic optic neuropathy (AION) Cardiac surgery patients Posterior ischemic optic neuropathy (PION) Spine and neck procedures. Age 5 to 81 years Vision Loss

  5. Roth S, et al. Eye injuries after nonocular surgery: a study of 60,965 anesthetics from 1988 to 1992. Anesthesiology 1996;85:1020 –1027. University of Chicago (1988-1992) 60,965 patients undergoing non-ocular surgery 1 patient (0.002%) suffered non-corneal POVL Warner ME, et al. The frequency of perioperative vision loss. Anesth Analg 2001;93:1417–1421. Mayo Clinic, retrospective study, excluded cardiac surgeries 501,342 non-cardiac surgeries 4 patients (0.0008%) developed POVL for longer than 30 days Nuttall GA, et al. Risk factors for ischemic optic neuropathy after cardiopulmonary bypass: a matched case/control study. Anesth Analg 2001;93:1410–1416. Mayo Clinic, retrospective study 27,915 cardiopulmonary bypass (CABG) procedures 17 (0.06%) patients were identified with peri-operative ION Vision Loss: Review of Literature

  6. Stevens WR, et al. Ophthalmic complications after spinal surgery. Spine1997;22:1319 –1324. 3 centers (1985-1994) 3,450 spine surgeries 7 cases (0.2%) with visual loss (2 patients with occipital infarctions, 4 patients with ION, and 1 patient with a central retinal vein occlusion) Roth S, et al. Postoperative visual loss: still no answers– yet. Anesthesiology 2001;95:575–577. 15 year study of nearly 225,000 surgeries 3 of 3,351 patients (0.09%) developed POVL after spinal surgery 50-fold higher rate compared with all other non-ocular procedures Chang SH, et al. The incidence of vision loss due to perioperative ischemic optic neuropathy associated with Spine surgery: the Johns Hopkins Hospital Experience. Spine 2005;30:1299 –1302. 20 year retrospective review at Johns Hopkins Hospital 14,102 spine surgeries ION was identified in four cases (0.028%) Vision Loss: Review of Literature

  7. In 1999, the ASA POVL Registry was established in response to concerns that POVL seemed to be increasing Purpose: Meaningful analysis Identify risk factors Develop preventive measures The database consists of: Voluntary, anonymously reported cases Visual loss within seven days of non-ocular surgery Standardized form that includes: detailed demographic, historical, examination, and intraoperative information www.asaclosedclaims.org ASA POVL Registry

  8. June 2005 - 131 cases of POVL reported 95 spine cases 12 cardiac cases 6 major vascular cases 5 orthopedic cases 13 miscellaneous cases 2006 ASA Interim Report – in-depth analysis of 93 cases of POVL associated with spine surgery 83 cases of ION 67% were PION 23% AION 10% unspecified ION 10 cases of central retinal artery occlusion 73% of all cases in the setting of spine surgery Age range: 5 to 81 years MALES predominated among the spine cases 82% had one pre-existing vascular risk factor 64% had an ASA physical status I or II (healthy) ASA POVL Registry

  9. Vision Loss: Anterior Segment • The cornea is the most commonly reported location of ocular injury during anesthesia • Corneal abrasions and or exposure • Usually NOT a cause of permanent visual loss

  10. Vision Loss: Retina • Most common retinal cause of visual loss is central retinal artery occlusion (CRAO) • Due to systemic or local arterial embolism • Cardiac and other vascular surgeries • Prone position spine surgeries • external compression of the globe due to malposition of head • ASA POVL Registry • 93 spine surgery cases with postoperative visual loss • 10 patients had CRAO • all unilateral • 7 (of the 10) had additional evidence of peri-ocular trauma, (ipsilateral decreased supraorbital sensation, ptosis, erythema, corneal abrasion, and ophthalmoplegia)

  11. Vision Loss: Optic Nerve • Most common site of permanent injury to the visual pathways in the setting of general anesthesia for non-ocular surgery is the optic nerves • Most often presumed mechanism of injury in this location is ischemia • Pupillary reactions are abnormal • ION is the most frequent condition associated with permanent POVL • The most common surgical setting is spine surgery in the prone position • Anterior ION • Acute disk edema • Cardiac Surgery • Posterior ION • Acute fundoscopic appearance: normal • Spinal (Prone) and Radical Neck Surgeries • Incidence increasing

  12. Vision Loss: Retrochiasmal Visual Pathways • Homonymous hemianopsia (unilateral) versus cortical visual impairment (bilateral) • Pupillary reactions are normal • Usually ischemic in origin - embolic cerebral infarction (posterior cerebral arteries) • Other mechanisms - neck trauma during intubation • Risk of stroke after general, noncardiac procedures is 0.08% to 0.7% • Resection of head and neck tumors and cardiac and vascular surgeries are associated with higher risks • Most peri-operative strokes are infarctions and are embolic in origin • Incidence of visual loss from retro-chiasmal infarction in the peri-operative period isunknown

  13. Physiology and Pathophysiology

  14. Review • We don’t see with our eyes but the interpreted visual signal to the cortex (occipital lobe). • Information is transmitted to the brain via the optic nerve. • Each of the optic nerves receives blood supply from branches of the ophthalmic artery within each eye socket. The optic disc has a unique blood supply (the posterior ciliary arteries).

  15. A Closer look at the blood supply • Blood supply to the chorid is thru the opthalmic artery (1) • one branches becomes the central retinal artery(2). • 2 branches which become the posterior ciliary arteries (3). • These are the main arteries indicated for peri-operative visual loss 3 2 3 1

  16. Perioperative Vision loss • Corneal Damage • Central Retinal Artery Occlusion (CRAO) • Ischemic Optic Neuropathy (ION) • Defined by where the lesion occurs on the optic nerve: • Anterior ION • Posterior ION

  17. Direct Corneal Damage • Most Common preventable reason for Unilateral Vision Loss

  18. www.surgical-pathology.com/retinal_artery.htm Central Retinal Artery Occlusion (CRAO) • The neurons of the retina, like those in the rest of the nervous system, are extremely susceptible to hypoxia. • Central retinal artery occlusions may follow thrombosis of the retinal artery, as in atherosclerosis or giant cell arteritis, or emboli of various types. Intracellular edema, manifested by retinal pallor, is prominent, especially in the macula where the ganglion cells are most numerous. • The vacularized choroid beneath the center of the macula (foveola) stands out in sharp contrast as a prominent “cherry red spot”.

  19. Central Retinal Artery Occlusion (CRAO) • Usually caused by external pressure on the globe (positioning) • Common findings are unilateral vision loss with signs of external periorbital swelling or ecchymosis. • Prone position causes increase in intraocular pressure. Coupled with malposition this insult may lead susceptible patient populations to vision loss. • Direct Compression has been implicate. Mimics an accelerated glaucoma. pressure from malposition or direct pressure on the globe is translated from the Optic disk to the Central Retinal Artery.

  20. Ischemic Optic Neuropathy (ION) • Etiology is still unclear. But there is a decreased delivery of O2 to the optic nerve. • Procedural dependent factors associated with ION elicited from the ASA closed claims: • Anemia • Prolonged procedures (>6.5hrs) • Sustained blood loss (44.7% of EBV) • Combination of the above • ION is further defined by where the lesion occurs and findings on retinal exam.

  21. Ischemic Optic Neuropathy (ION) • Anterior ION: • Occurs in watershed area of Posterior Ciliary Artery (2 branches) • Anterior Optic Nerve supplied by multiple sources • Located in or near optic disk visible on retinal exam as edema.

  22. Ischemic Optic Neuropathy (ION) • Posterior ION: • Pial branches from Internal Carotid supply mid-orbital optic nerve • Pial branches are found with variable density and in an unusual T-shaped perpendicular fashion. • This arrangement is characteristic of a low pressure system • Lumbar operations high incidence (LION)

  23. Contributing factors to ION • Hypotension • Hypovolemia • Hypoxemia • Hemodilution • Facial edema • Use of Vasopressors • Prone • Head down • Increase in venous pressure

  24. Treatment & Prevention

  25. Prevention starts with: Understanding of etiology Understanding of Pathophysiology Understanding of Risk Factors Understanding the modalities to truly prevent POVL UTILIZING the modalities to treat POVL Prevention is a good thing

  26. Understanding the risk factors Procedure dependent risk factors CABG, prone cases, neck, nose and sinus surgery, Intra-operative events- large EBL, systemic Hypotension, long duration of procedure (>5 hrs), and anemia How to appropriately prevent POVL

  27. How to appropriately prevent POVL • Understanding the risk factors • Patient dependent risk factors • Hypertension • Atherosclerosis • Tobacco use • Diabetes Mellitus • Morbid obesity

  28. Understanding the risk factors Procedural issues related to decrease oxygen delivery to the optic nerve large EBL, prolonged Hypotension(52%), anemia, OR (9.9hrs) ASA POVL registry as of 2000 had 23 incidents of POVL Prone spine cases most common position (57%) CABG (22%) Ischemic optic neuropathy was the chief diagnosis in 20/23 reported cases How to appropriately prevent POVL

  29. Patient dependent related risk factors Variable All Cases (n=23) Median Age (range) 58 (24-73) years Obesity (percent cases) 13 (56 percent) Hypertension 11 (48 percent) Diabetes Mellitus 5 (22 percent) Smoking History 12 (52 percent) Atherosclerosis 12 (52 percent) Lee, LA: Postoperative visual loss data gathered and analyzed. ASA Newsletter 64(9): 25-27, 2000. ASA POVL Registry

  30. Variablesn (% of 83 cases) Mean age 50 +/- 14yrs Obesity 44 (53%) Hypertension 34 (41%) Diabetes Mellitus 13 (16%) Smoking History 38 (46%) Atherosclerosis (CAD) 8 (10%) Cerebrovascular disease 3 ( 4%) Increased Cholesterol/Lipids 11 (13%) 1 Coexesting diseases 68 (82%) Lee, L. et al. (2006). The American society of anesthesiologist postoperative visual loss registry. Anesthesiology. 105, 652-9. Lee, L. et al. (2006). The American society of anesthesiologist postoperative visual loss registry. Anesthesiology. 105, 652-9. ASA POVL Registry 2006

  31. Considerations

  32. Current recommendations for major spine surgery Consider risk explanation in consenting process Use arterial catheters to monitor BP, consider CVP monitoring with CVC Use colloids along with Crystalloids for replacement of volume Position Head of Bed so that it is EQUAL or ABOVE the level of the HEART. Consider staging surgeries. (decrease anesthesia time) Lee, L. (2008). Solutions to POVL mystery requires research. The Official Journal of the Anesthesia Patient Safety Foundation. 23(1), P.3 Current recommendations from ASA Task Force on Peri-operative Blindness

  33. Prone position Related Devices

  34. Anesthesia Related Prone Position Devices

  35. Remember the Etiology of POVL Remember the Case/Anesthetic specific considerations of POVL Remember the Patient specific considerations APSF recommendations based on current literature to reduce the incidence of POVL Summary

  36. Baig M, Lubow M, Immesoete P, et al. Vision loss after spine surgery: review of the literature and recommendations. Neurosurgery Focus. 2007; 23 1-9. Chang SH, Miller NR. The incidence of vision loss due to perioperative ischemic optic neuropathy associated with Spine surgery: the Johns Hopkins Hospital Experience. Spine 2005;30:1299 –1302. Hayreh, SS. Posterior ischemic optic neuropathy: clinical features, pathogenesis, and management. Eye. 2004; 18:1188-1206. Lee, LA: Postoperative visual loss data gathered and analyzed. ASA Newsletter.2000;64:25-27. Lee, L. Solutions to POVL mystery requires research. The Official Journal of the Anesthesia Patient Safety Foundation. 2008;23:p.3. Newman, NJ. Perioperative Visual Loss After Nonocular Surgeries. Am J Opthalmol 2008;145:4:604-610. Nuttall GA, Garrity JA, Dearani JA, et al. Risk factors for ischemic optic neuropathy after cardiopulmonary bypass: a matched case/control study. Anesth Analg 2001;93:1410–1416. References

  37. Roth S, Barach P. Postoperative visual loss: still no answers– yet. Anesthesiology 2001;95:575–577. Roth S, Thisted RA, Erickson JP, Black S, Schreider BD. Eye injuries after nonocular surgery: a study of 60,965 anesthetics from 1988 to 1992. Anesthesiology 1996;85:1020 –1027. Stevens WR, Glazer PA, Kelley SD, Lietman TM, Bradford DS. Ophthalmic complications after spinal surgery. Spine1997;22:1319 –1324. Warner ME, Warner MA, Garrity JA, et al. The frequency of perioperative vision loss. Anesth Analg 2001;93:1417–1421. References

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