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Show Journal of Ncuro- Ophthalmology 14( 1): 6- 8, 1994. © 1994 Raven Press, Ltd., New York Temporary Blindness in the TUR Syndrome John P. Barletta, M. D., Maher M. Fanous, M. D., and Latif M. Hamed, M. D. The TUR syndrome is a clinical disorder consisting of circulatory, gastrointestinal, and neurologic signs that are infrequently seen in some patients undergoing endoscopic surgery of the prostate gland with the use of nonconductive irrigating fluids. Several theories of its pathogenesis have been proposed. The condition may occasionally be associated with bilateral profound loss of vision. We report a patient with the TUR syndrome who suffered bilateral temporary blindness and speculate on the etiology of the visual loss and localization of the dysfunction along the visual pathway. Key Words: Transurethral resection of prostate- Endoscopic fluid absorption- Hyperammonemia- glycine toxicity. The TUR syndrome refers to a constellation of symptoms and signs that can develop during transurethral resection of the prostate. It is characterized by irritability, confusion, bradycardia, nausea, hypertension, dyspnea, convulsions, and blindness ( 1- 4). It is speculated to be due to excessive absorption of the nonelectrolyte irrigating fluid through the prostatic venous sinuses into the general circulation ( 2- 4). The resulting metabolic disturbance includes a dilutional hyponatremia, hyperglycinemia, and subsequent hyperammonemia ( 2,5- 8). Visual disturbances such as blurred vision or temporary blindness have occasionally been reported as a consequence of the TUR reaction ( 1, 9- 12). We describe a patient undergoing transurethral resection of the prostate who experienced blindness as the first presenting manifestation of the TUR syndrome. From the Department of Ophthalmology, University of Florida College of Medicine, Gainesville, Florida, U. S. A. This work was supported in part by an unrestricted departmental grant from Research to Prevent Blindness, Inc., New York, New York. Address correspondence and reprint requests to Dr. Latif M. Hamed, Department of Ophthalmology, University of Florida College of Medicine, P. O. Box 100284, JHMHC, Gainesville, FL 32610- 0284, U. S. A. CASE PRESENTATION A 61- year- old man underwent transurethral resection of the prostate under spinal anesthesia. Irrigating fluid was 1.5% glycine. At 45 minutes into the operation the patient experienced sudden blindness, acute nausea and vomiting, altered mental status, and, shortly thereafter, seizure activity. Stat laboratory studies revealed the serum sodium concentration to have dropped precipitously from 138 mEq/ L to 120 mEq/ L ( normal: 135- 145 mEq/ L) and the serum ammonia was 708 | xmol/ L ( normal: 11- 35 ixmol/ L). The patient was started on 3% normal saline and furosemide, and the procedure was terminated. An electrocardiogram showed normal sinus rhythm. The patient responded favorably, becoming oriented but lethargic within 1 hour. Ophthalmologic examination displayed no light perception vision OU, with sluggish but reactive pupils and no relative afferent pupillary defects. The fundus TEMPORARY BLINDNESS IN TUR SYNDROME 7 examination was normal as was the neurologic examination. Computed tomography of the brain was normal. Therapy with intravenous pyridoxine and L- argi-nine HC1 was begun for treatment of the hyperammonemia. Four hours later, the ammonia level dropped to 456 u- mol/ L and the visual acuity gradually improved to 20/ 800 in each eye over the same time period. The ocular examination was otherwise unchanged. The patient's vision continued to improve over the next 12 hours, returning to normal in 24 hours. DISCUSSION The TUR reaction was first described in 1947 ( 3) as a complication of transurethral resection of the prostate characterized by severe neurologic, circulatory, and gastrointestinal disturbances. Death may occasionally result. Visual loss has been described as one of the earliest, and, rarely, the sole symptom of the TUR reaction ( 1,9,11). The exact etiology of the visual loss remains unclear, but has been generally attributed to the rapid absorption of large amounts of irrigating fluid into the systemic circulation, inducing metabolic disturbances. The choice of irrigating fluid during endoscopic surgery has evolved since the late 1920s. Many of the severe complications derived from the earlier use of hypotonic irrigants were eliminated with the introduction of isotonic glycine solution. However, with excessive absorption of the glycine solution, acute hyponatremia still occasionally occurs. Blindness was first described when glycine was used as an irrigating solution ( 4). Historically, the most widely accepted hypothesis regarding the development of vision loss incriminated the dilutional hypervolemia with hyponatremia that develops as a consequence of a rapid fluid absorption through open venous sinuses during prostatectomy. It has been postulated that changes in serum sodium levels may produce alterations in the central nervous system function as a result of cerebral edema. Involvement of the occipital cortex would cause vision loss ( 2). Although hyponatremia develops, serum osmolality remains near normal ( 6,13,14). In a study of 72 patients, 19% of whom had marked diminution in serum sodium, only two had reduced serum osmolality ( 5). Thus hyponatremia has been thought to be an unlikely etiology of the transient visual loss. Another possible cause of vision loss may be ammonia, which becomes elevated by oxidative deamination of glycine in the liver. Hyperammonemia in hepatic encephalopathy is well-known, but the mechanism for central nervous system ( CNS) depression is unknown. A partial deficiency of the urea cycle enzyme, arginosucci-nate synthetase, has been postulated in patients with hyperammonemia ( 8). Infusion of L- arginine prevents the rise in blood ammonia in patients receiving intravenous glycine ( 17). Serum ammonia levels have been described as the most accurate marker for delayed awakening from general anesthesia ( 7). Ryder reported two patients whose recovery from coma after TUR more closely followed a drop in ammonia level than a rise in serum sodium ( 8). In four patients with TUR syndrome who showed elevated glycine and abnormal elec-troretinograms, two had normal ammonia levels, rendering it unlikely that hyperammonemia plays a significant role in the vision loss ( 15). Another putative etiology for the transient blindness is hyperglycinemia and direct glycine toxicity. Glycine, a nonessential amino acid, is a known inhibitory neurotransmitter that readily crosses the blood- brain barrier. It causes membrane hyperpolarization with a concomitant fall in membrane resistance and increase in chloride permeability. Light has been shown to evoke the release of glycine from cat and rabbit retinas, which in turn has an inhibitory effect on the electroretin-ogram and visual evoked potential in rabbits ( 19). Because high serum levels of glycine and vision loss have been shown to coexist in affected patients, glycine may be the cause due to its inhibitory action in the retina and/ or the CNS. Furthermore, an association between the normalization of serum glycine levels and visual recovery have been demonstrated in some patients with the TUR syndrome who suffered visual loss ( 12). In support of the theory of glycine toxicity to the retina ( as opposed to a generalized toxic effect on the CNS), Burkhart and colleagues ( 16) described a case of transient visual blindness during arthroscopy, using 1.5% glycine as the irrigating solution. The patient had no other symptoms and a normal sen-sorium. In a study of 17 patients who underwent transurethral resection of the prostate, four patients described visual disturbances coincident with elevated serum glycine and decreased serum sodium levels. Electroretinograms consistently demonstrated complete loss of the oscillatory potentials on the ascending limb of the b- wave and abolition of the 30- Hz flicker response ( 15). Hyponatremia does not appear to be a confounding factor in the etiology as sodium has little effect on retinal physiologic functions in contrast to glycine ( 18). / Neuro- Ophthalmol, Vol. 14, No. 1, 1994 /. P. BARLETTA ET AL. Year 1956 1975 1979 1982 1984 1985 1990 Present TABLE" Reference Harrison et al. ( 4) Defalque et al. ( 11) Appelt et al. ( 9) Ovassapian et al. ( 12) Kaiser et al. ( 10) Gillett et al. ( 1) Burkhart et al. ( 16) case I. Visual examination and Va NLP LP NLP LP LP LP LP LP LP NLP NLP NLP NLP NLP [ Sod [ Nm ium m Eq/ L] 11 135- 145] 111 110 107 106 114 115 121 107 111 125 116 118 N. A. 120 ' laboratory values in [ Glycine [ Nml 13 N. A. N. A. N. A. N. A. N. A. N. A. N. A. N. A. 1,029 1,374 N. A. N. A. N. A. N. A. [ NH3 = Nml 11- 708 - 35 ( mg/ L] - 17] Ixmol/ L] xrnol/ L the TUR syndrome Pupils N. A. Normal N. A. Normal Nonreact N. A. N. A. N. A. N. A. Nonreact N. A. N. A. Sluggish Sluggish Systemic Yes None Yes None None None Yes None Yes None None None None Yes Recovery time N. A. 4 h Several hours Several hours 48 h 24 h 8 h 12 h 24 h 24 h 12 h 12 h 30 min 12 h N. A., not available; Nml, normal. The site of dysfunction along the visual pathways that is responsible for the visual loss remains elusive. The loss of vision has been commonly attributed to cortical edema, but the clinical cases reported to date do not support a cortical localization of the vision loss in all cases. While the presence of normal pupillary light reflexes in some patients with severe vision loss would support a cortical localization, other cases with sluggish or nonreactive pupils would suggest an anterior pathway disturbance ( Table 1). Documentation of the pupillary response and the presence or absence of associated neurologic disease in future cases may help delineate the exact localization of the dysfunction along the visual pathway. On the basis of available evidence, glycine toxicity appears to correlate best with the clinical picture. REFERENCES 1. Gillett W, Grossman HB, Lee R. Visual disturbances in TUR reaction. Urology 1985; 25: 573- 1. 2. Henderson DJ, Middleton RG. Coma from hyponatremia following transurethral resection of prostate. Urology 1980; 25: 267- 71. 3. Creevy CD, Webb EA. Fatal hemolytic reaction following transurethral resection: a discussion of its prevention and treatment. Surgery 1947; 21: 56. 4. Harrison RH, Boren JS, Robinson JR. Dilutional hypona-tremic shock: another concept of the transurethral prostatic resection reaction. / Urol 1956; 75: 85- 107. 5. Desmond J. Serum osmolality and plasma electrolytes in patients who develop dilutional hyponatremia during transurethral resection. Can ) Surg 1970; 13: 116- 21. Zucker JR, Bull AP. Independent plasma levels of sodium and glycine during transurethral resection of the prostate. Can Anacsth Soc J 1984; 31: 307- 13. Roesch RP, Stoelting RK, Langeman JE, Kahnoski RJ, Backes DJ, Gephardt SA. Ammonia toxicity resulting from glycine absorption during a transurethral resection of the prostate. Anesthesiology 1983; 58: 577- 9. Ryder KW, Olson JF, Kahnoski RJ, Karn RC, Oei TO. Hyperammonemia after transurethral resection of the prostate: a report of two cases. / Urol 1984; 132: 995- 7. Appelt GL, Benson GS, Corriere JN. Transient blindness: unusual initial symptoms of transurethral prostatic resection reaction. Urology 1979; 13: 402- 4. Kaiser R, Adragna MG, Weis FR Jr, Williams D. Transient blindness following transurethral resection of the prostate in an achondroplastic dwarf. / Urol 1985; 133: 685- 6. Defalque RJ, Miller DW. Visual disturbances during transurethral resection of the prostate. Can Anaesth Soc } 1975; 22: 620. Ovassapian A, Josh CW, Brunner EA. Visual disturbances: an unusual symptom of transurethral prostatic resection reaction. Anesthesiology 1982; 57: 332. Rothenberg DM, Berns AS, Ivankovich AD. Isotonic hyponatremia following transurethral prostate resection. / Clin Anesthesiol 1990; 2: 48- 53. Kirschenbaum MA. Severe mannitol- induced hyponatremia complicating transurethral prostate resection. / Urol 1979; 121: 687- 8. Wang JM, Creel DJ, Wong KC. Transurethral resection of the prostate, serum glycine levels, and ocular evoked potentials. Anesthesiology 1989; 70: 36- 41. Burkhart SS, Barnett CR. Synder SJ. Case report: transient post- operative blindness as a possible effect of glycine toxicity. Arthroscopy 1990; 6: 112^. Fahey JL. Toxicity and blood ammonia rise resulting from intravenous amino acid administration in man: the protective effect of L- arginine. / Clin Invest 1957; 36: 1647- 55. Massey SC, Redburn DA. Transmitter circuits in vertebrate retina. Prog Neurobiol 1987; 28: 55- 96. 19. Korol S. The effects of glycine on the rabbit retina: average ERG and averaged visual evoked responses. Experientia 1973; 29: 984- 5. 8 10 11 12 13 14 15 16 17 18 I Neuw- Ophthalmol, Vol. 14, No. 1, 1994 |
