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Show Journal of Neuro- Oplitlmlmology 15( 2): 90- 94, 1995. © 1995 Raven Press, Ltd., New York A Controlled Trial of Regional Sympatholysis in the Treatment of Photo- oculodynia Syndrome Perry G. Fine, M. D., and Kathleen B. Digre, M. D. Abstract: Introduction: The mechanism( s) underlying the eye pain syndrome characterized by photo- oculodynia and decreased tears ( herein referred to as PODS) is unknown. Postulating a sympathetically maintained pain mechanism, cervical sympathetic ganglion blocks ( CSB) were performed in an open- label trial in two patients as a pilot test of our hypothesis. Because these patients experienced clinically dramatic reductions in signs and symptoms, a double- masked controlled trial was initiated. Methods: With Institutional Review Board approval and written informed consent, four other subjects with PODS who had experienced temporary reduction (> 50%) of symptoms with a single lidocaine CSB were enrolled. A randomized, double- masked series of three CSBs ( saline, bupivacaine, lidocaine) was scheduled for each subject 2- 7 days apart. Results: CSB with lidocaine and bupivicaine, but not saline, reduced spontaneous pain and light sensitivity and increased production of tears. Symptom reduction lasted for hours to days, extending beyond clinical signs of local anesthetic- induced sympatholysis. It was also observed that sympatholysis extinguished associated blepharospasm in those subjects with this dystonic condition ( one subject in the open- label pilot trial and two of three in the controlled trial). Conclusions: Results of these preliminary data suggest that the sympathetic nervous system is involved in mediating symptoms associated with PODS in certain individuals. Key Words: Eye pain- Sympatholysis- Photophobia- Oculodynia- Blepharospasm. From the Departments of Anesthesiology ( P. G. F.) and Neurology ( K. B. D.), University of Utah Health Sciences Center, Salt Lake City, Utah, U. S. A. Address correspondence and reprint requests to Dr. P. G. Fine, Associate Professor, Department of Anesthesiology, University of Utah Health Sciences Center, 50 North Medical Drive, Salt Lake City, UT 84132, U. S. A. Photophobia is a general and conventionally used term to denote aversive responses or abnormal intolerance to light. Several pathophysiological states affecting eye structures cause light-induced sensitivity. Iritis and iridocyclitis, both inflammatory conditions that affect the iris, produce pain when the eye is exposed to light a n d the pupil constricts. This type of pain is ameliorated with pupillary dilation. Chemical or mechanical irritation of the cornea can cause a pain syndrome that may be made worse by light and that is relieved with topical anesthesia. Another type of light sensitivity, " dazzling," is due to abnormality of light scatter and lack of adaptation ( 1). Photophobia accompanies migraine headaches for unknown reasons. Migraineurs have a decrease in light pain threshold, and even normal amounts of light can be painful. Little progress has been made to elucidate further this or other mechanisms underlying light- activated eye pain. In this article, we address a category of idiopathic chronic eye pain triggered by even minor ocular trauma, when there is no evident ongoing tissue damage or inflammation. This symptom is frequently accompanied by exquisite light ( visual) hypersensitivity, dry eyes, ocular foreign- body sensation, and blepharospasm. No known pathology exists in the iris or the cornea to account for the pain or other symptoms experienced by these patients. Although the term photophobia is also commonly used to denote this particular group of patients' conditions, we suggest that this nomenclature is not clinically useful because it serves only to describe a generalized behavioral response to a normally nonnoxious stimulus. Therefore, we differentiate this group of patients exhibiting the constellation of findings listed b y using the t e rm photo-oculodynia syndrome ( PODS). A paucity of epidemiological ( prevalence) data exist from which to draw to further describe this group of patients. 90 EFFECT OF SYMPATHOEYSIS ON PHOTO- OCUEODYNIA 91 Hypothesis Reflex sympathetic dystrophy ( RSD), causalgia, and sympathetically maintained pain ( SMP) are names currently given to pain syndromes that seem to be driven by sympathetic activity. The pathophysiology of this subset of neuropathic pain- producing disorders is poorly understood. Most current evidence suggests that there is sensitization of central ( spinal) receiving neurons, up-regulation of a- adrenoreceptors at peripheral primary nociceptive afferents, or both, which lead to the sensory abnormalities experienced by affected patients ( 2- 4). Remarkable similarities exist in patients exhibiting these sympathetically mediated pain syndromes and those with PODS. These are listed in Table 1. Based on this observation, we postulate that if PODS is a sympathetically maintained pathophysiological state, signs and symptoms should abate, at least temporarily, with regional sympatholysis. To test this hypothesis, a two- stage clinical study was initiated. METHODS All subjects involved in every phase of this study voluntarily enrolled after giving written and verbal consent according to the guidelines and with the approval of the University of Utah Institutional Review Board for Human Studies. All procedures were performed in the Pain Management Clinic, University of Utah Health Sciences Center, by the same anesthesiologist ( P. G. F.). A consistent technique of requiring nothing by mouth ( NPO) status for at least 6 h, procuring intravenous access, continuous monitoring of vital signs ( automated blood pressure ( BP), electrocardiogram ( ECG), pulse oximetry), and performing cervical sympathetic ganglion block ( CSB), was employed. The anterior C- 6 paratracheal approach with a 22- G " B" bevel needle under aseptic conditions TABLE 1. Similarities between PODS and other sympathetically maintained pains 1. Onset triggered by even minor trauma or undeterminable cause. 2. " Burning" quality to spontaneous pain. 3. Symptoms out of proportion to any evident ongoing tissue damage or inflammation ( typical of other neuropathic pains). 4. Pain to a usually nonnoxious sensory stimulus. 5. Dystonia. 6. Emotionality a common hallmark; symptoms often attributed to primary psychological disturbance rather than physically based disorder. PODS, photo- oculodynia syndrome. was used. Digital pressure was applied caudal to the puncture site during injection to promote cephalic spread of injectate. Pilot Subjects This stage involved an unmasked local anesthetic ( 1% lidocaine, 10 ml) unilateral sympathetic block of the cervical sympathetic chain in two subjects experiencing PODS ( Table 2). Based on the positive response to sympatholysis in these two individuals, manifest by elimination of spontaneous pain, light- induced pain, and foreign- body sensation, a placebo- controlled double- masked trial in four additional subjects was initiated. Control Study Subjects experiencing PODS were enrolled and scheduled to undergo screening with an unmasked CSB with 10 ml 1% lidocaine. Those experiencing at least 50% reduction in pain would proceed to receive three additional blocks in random order under double- masked conditions, with subjects thereby serving as their own controls. Each block would involve 10 ml preservative- free solutions consisting of either 1% lidocaine, 0.5% bu-pivacaine, or placebo ( isotonic saline), scheduled 3- 7 days apart. Measures of pain and pain- relief scores ( verbal and visual analog), subjective reports, and objective observations of blepharospasm, presence of Horner's signs, and vital signs would be recorded before the block and at 5, 10, 15, 30, 45, 60, and 90 min after the block. RESULTS All four subjects enrolled in the control study responded to the screening CSB and completed all three subsequent double- masked blocks ( Table 2). Subjective reports of significant reductions in most troublesome symptoms resulted with local anesthetic injection but not with saline placebo ( Table 3). All local anesthetic blocks were attended by Horner's signs, objectively substantiating sympatholysis. The most consistent finding was dramatic decrease in light- induced pain and sensitivity with onset of sympathetic blockade ( Fig. 1). There were no morbid events, and no clinically significant alterations in vital signs occurred. One subject ( S. T.) underwent pre- and post-block intraocular pressure ( IOP) measurements ( Goldman Tonometer). A 33% reduction from / Neuro- Ophthalmol, Vol. 15, No. 2, 1995 92 P. G. FINE AND K. B. DIGRE TABLE 2. Photo- oculodynia patient profiles Subject Unmasked J. M. F. Q. Age Gender initial trial 65 F 46 M Symptoms Pod, b, d, p, fbs Pod, ha, d, P Double- masked placebo- controlled trial S. M. ST. K. O. K. W. 39 F 57 F 66 M 58 F Pod, d, p, fbs Pod, ha, d, P, b Pod, ha, d, P, b Pod, ha, d, p, b, fbs Duration 8- 10 years 8 months 4 years 4 years 7 years 9 years Trigger Corneal transplant ( Fuch's dystrophy) Corneal transplant ( keratoconus) Chemical keratitis Unknown Unknown Head trauma Pod, photo- oculodynia; d, dry eyes; p, spontaneous burning pain; fbs, foreign body sensation; b, blepharospasm; ha, headache. baseline normal values of IOP occurred after local anesthetic but not after saline injection. The two pilot patients and two of the control study patients decided to continue with two to six additional lidocaine blocks after completing the formal study. One subject ( F. Q.) experienced complete resolution of all symptoms, and the other three have experienced > 50% improvement in signs and symptoms at 6- 12 months' follow- up. One subject ( K. O.) did not elect to proceed with any further therapy after the control study ( 3 months' follow- up) because he felt " good enough." The remaining subject, K. W., who had only two local anesthetic blocks during the control trial, at 1 year follow- up reports only the continuing problem of dry eyes. DISCUSSION Although the small cohort of subjects under investigation obviates formal statistical analysis, the clinical results demonstrated using this rigorous study design strongly suggest that PODS is in some way driven by sympathetic nervous system activity. This is not surprising because the eye is TABLE 3. Photo- oculodynia patient results: double- masked, placebo- controlled trial of cervical sympathetic ganglion block Result Spontaneous pain Light- triggered pain Blepharospasm Dry eyes Foreign- body sensation S. M. 4a 1 NA 44 4 4 s S. T. 4 44 4 4 4 NA jbject K. O. 4 4 4 4 4 4 NA K. W. 4 4 4 4 4 4 4 4 4 , most remarkable changes perceived by the subjects; NA, not applicable to this subject. " Arrows depict direction and magnitude of change after local anesthetic block compared to placebo block. richly innervated by sympathetics, and most eye structures are dependent on balanced autonomic activity for normal function. The sympathetics arise in the hypothalamus and travel down the spinal cord to C8- T1 where they leave the cord and synapse in three to four cervical sympathetic ganglia. Fibers from the most cephalic ganglion, the superior cervical ganglion, form the internal carotid plexus. These sympathetic effer-ents enter the orbit at the superior orbital fissure and join the ophthalmic and nasociliary branches of the trigeminal nerve. The sympathetic fibers in the short ciliary nerves supply blood vessels in the eye, whereas the long ciliary nerves supply the dilator of the pupil. placebo local anesthetic time after block FIG. 1. Changes in ocular pain induced by ambient room lighting after cervical sympathetic ganglion block. Values reported are means of the four subjects tested, comparing injection of saline and local anesthetic. / Neuro- Ophthalmol, Vol. 15, No. 2, 1995 EFFECT OF SYMPATHOEYSIS ON PHOTO- OCUEODYNIA 93 Pharmacologically, sympathetic effector sites consist of several subtypes of receptors. Postsynaptic a- 1 receptors are activated by norepinephrine, whereas presynaptic ct- 2 receptor activation inhibits norepinephrine release from sympathetic efferent terminals. It is well documented that adrenergic neurotransmitter release can mediate nociception, presumably via a- 1 receptor activation of primary nociceptive afferents ( 5,6). p receptors have not been implicated in nociception. Historically, there have been repeated efforts to understand the neural basis of photophobia and eye pain. The sympathetic nervous system or dys-regulation of sympathetic receptors have only in-ferentially been tied to eye pain syndromes. In 1896, Kraus ( 7) performed a seminal experiment on a patient with photophobia whereby he extirpated the gasserian ganglion and sectioned the sensory root of the trigeminal nerve. He reported that symptoms were abolished on the operative side. This led to the belief that photophobia is primarily due to an abnormality in the pain pathways coursing with the trigeminal nerve. Later, Lebensohn ( 8) concluded that photophobia must be associated with the trigeminal nerve and its interaction with the pupillary light reflex. This investigator subcategorized painful responses to light as " true photophobia" in contradistinction to non- pain- producing sensations such as " dazzling." He went on to state that for photophobia to occur, the trigeminal nerve must be intact and " antidromic vasodilatation" takes place, referred to as a " trigeminal pupillary reflex." He believed that vasodilatation played a fundamental role in the painful response. For photophobia to occur, an abnormality had to take place in the anterior segment. He suggested that vasodilatation occurred reflexively, causing the subject to perceive an increased brightness to the light with consequent pain. Lowenfeld ( 1) has shown that this antidromic vasodilatation actually results from neurotransmitter release at terminal effector sites within the eye ( e. g., substance P; prostaglandins), leading to congestion of the iris and pupillary miosis. Other possibilities must be taken into account to explain the fact that all PODS patients tested in our study experienced relief with CSB. A placebo response must always be considered, and this is especially the case when a dramatic intervention such as an injection therapy is performed ( 9). Ver-dugo and Ochoa have repeatedly and appropriately emphasized the importance of placebo-controlled methodology in drawing mechanistic conclusions ( 10,11). We believe that a placebo-generated response is an unlikely possibility because the results from placebo ( saline) and active drug ( local anesthetic) injections were so different ( Fig. 1; Table 3). An alternative but related explanation is that these patients suffer from a primary psychiatric disorder that leads to somatization involving this particular area of the body. There are strong arguments in the literature linking such attributions to patients with RSD- like syndromes ( 12). In spite of the fact that these patients often respond strongly to suggestion, this primary " causality" argument is countered by other data concluding that the emotionality and affective disorders so frequently observed in this patient population represent comorbidity ( 13). It has been suggested that this dilemma is best resolved in individual cases by employing a rigorous placebo- controlled testing paradigm ( 14). We believe we have fulfilled this criterion for distinguishing pathophysiological causation in this study. We acknowledge that specific psychological testing may be useful in further defining comorbidity and directing concurrent psychological therapies. Another important consideration is the possibility that systemic absorption of local anesthetic alone caused resolution of symptoms. Intravenous local anesthetic administration has been shown to abate certain neuropathic pains ( 15). To test this possibility, one control study subject ( S. M.) was given the same dose of intravenous lidocaine ( 100 mg) as was injected during the block protocol. This was administered as one of six sequential 15- min intravenous infusions ( five saline, one lidocaine) in a double- masked random order. This followed a previously described methodology specifically designed to bring out placebo effects ( 9). Resolution of spontaneous and light- evoked eye pain coincided exactly with lidocaine infusion. However, this patient's other symptoms, most notably dry eyes, did not improve as with CSB. This overlapping but separation of systemic versus regional sympatholytic effects requires further investigation and confirmation. CONCLUSION A link between the sympathetic nervous system and PODS, an idiopathic pain- producing condition, seems to have been confirmed, but there are considerable barriers to studying patients with PODS to exact a pathophysiological mechanism. Other than serious ethical concerns, which limit human experimentation, the heterogeneous na- / Neuro- Ophtlmimol, Vol. 15, No. 2, 1995 94 P. G. FINE AND K. B. DIGRE ture of these patients in regard to their functional and psychological states makes fixed variable experiments and conclusions extremely difficult. This is especially true with an end point as subjective as is pain. Other forms of clinical studies can help to reinforce or discount our conclusion and further define subsets of patients. 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