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Volume 16, Number 22, Issue of November 15, 1996 pp. 7318-7330
Copyright ©1996 Society for NeuroscienceAn Explanation for Reflex Blink Hyperexcitability in Parkinson's Disease. II. Nucleus Raphe Magnus
Michele A. Basso1 and Craig Evinger2 1 Department of Psychology, and 2 Departments of Neurobiology and Behavior and Ophthalmology, SUNY Stony Brook, Stony Brook, New York 11794-5230
ABSTRACT
Hyperexcitable reflex blinks are a cardinal sign of Parkinson's disease. The first step in the circuit linking the basal ganglia and brainstem reflex blink circuits is the inhibitory nigrostriatal pathway (Basso et al., 1996
Key words: Parkinson's disease; blink reflex; superior colliculus; trigeminal complex; rats). The current study reports the circuits linking the superior colliculus (SC) to trigeminal reflex blink circuits. Microstimulation of the deep layers of the SC suppresses subsequent reflex blinks at a latency of 5.4 msec. This microstimulation does not activate periaqueductal gray antinociceptive circuits. The brainstem structure linking SC to reflex blink circuits must suppress reflex blinks at a shorter latency than the SC and produce the same effect on reflex blink circuits as SC stimulation, and removal of the structure must block SC modulation of reflex blinks. Only the nucleus raphe magnus (NRM) meets these requirements. NRM microstimulation suppresses reflex blinks with a latency of 4.4 msec. Like SC stimulation, NRM microstimulation reduces the responsiveness of the spinal trigeminal nucleus. Finally, blocking the receptors for the NRM transmitter serotonin eliminates SC modulation of reflex blinks, and muscimol inactivation of the NRM transiently prevents SC modulation of reflex blinks. Thus, the circuit through which the basal ganglia modulates reflex blinking is (1) the substantia nigra pars reticulata inhibits SC neurons, (2) the SC excites tonically active NRM neurons, and (3) NRM neurons inhibit spinal trigeminal neurons involved in reflex blink circuits.
INTRODUCTION
Reduced dopaminergic tone in the basal ganglia (BG) produces marked reflex blink hyperexcitability in animals (Shallert et al., 1989
The rodent SC has two major descending projections. First, the ipsilateral descending pathway originates from the entire rostral caudal extent of the medial SC. The axons forming this pathway terminate primarily in the parabigeminal nucleus, cuneiform nucleus, ventrolateral midbrain pontine reticular formation, pontine nuclei, and the pontomedullary reticular formation (Redgrave et al., 1987
Many of the brainstem areas that receive lateral SC afferents could mediate SC modulation of reflex blinks. Because SC inactivation increases reflex blink excitability and SC activation decreases reflex blink excitability, the SC must excite a tonically active neuron that inhibits the reflex blink circuit. The inhibitory, midline omnipause neurons (OPNs) might fill this role. Tonically active OPNs receive an excitatory input from the rostral SC (Raybourn and Keller, 1977
MATERIALS AND METHODS
Subjects. Male Sprague Dawley rats weighing between 150 and 400 gm served as subjects. Animals were maintained on a 12 hour light/dark cycle and fed ad libitum. All procedures strictly adhered to federal, state, and university guidelines concerning the use of animals in research.
Acute preparation. Animals were prepared as described in the companion paper [Basso et al., 1996
Microstimulation. Glass microelectrodes filled with 2 M sodium acetate saturated with fast green were used for stimulation. To activate neural structures, a 70 msec train of 200 Hz, 80 µsec duration stimuli was delivered 75 msec before corneal stimulation. The stimulus intensities ranged from 10 to 50 µA. To establish the latency of stimulation effects, a single 80 µsec stimulus was presented 0, 10, 20, or 30 msec after the corneal stimulus. The stimulus intensities for the single stimuli ranged from 50 to 120 µA. In all experiments, stimulation and nonstimulation trials were alternated with an intertrial interval of 50 ± 5 sec.
Drug protocols. We examined the effects of muscimol, a GABA agonist, metergoline, a serotonin blocker, and naloxone, an opioid antagonist, on SC modulation of reflex blinks. Muscimol (1%) dissolved in saline was injected into brain structures to decrease neural activity. In one animal, 0.5 µl of muscimol was injected through a 30-gauge syringe into the SC while recording spinal trigeminal field potentials and OOemg activity evoked by corneal stimulation. In the other experiments, 50-100 nl of muscimol was pressure-injected with a Picospritzer (General Valve, Fairfield, NJ) through one barrel of a double-barrel recording electrode. The other barrel of the microelectrode contained 2 M sodium acetate saturated with fast green and was used to establish the level of reflex blink suppression produced by microstimulation. The electrode pair was placed stereotaxically into the NRM. The electrode position was marked by passing current through the fast green barrel (Thomas and Wilson, 1965
Data acquisition and analysis. OOemg signals were acquired and stored on a computer (4000 Hz, 12-bit A/D resolution) and analyzed off-line using an interactive computer program that integrated OOemg records and determined latencies. When acquiring trigeminal field data and OOemg data simultaneously, both records were acquired and stored on a computer at 15 kHz per channel (12-bit A/D resolution).
Statistical procedures. OOemg and field data were analyzed separately for each experimental manipulation. OOemg data were normalized to the mean blink amplitude for all animals, and nonparametric statistics were used to compare reflex blink amplitude with and without stimulation trains. Analyses assessing drug effects compared the amount of reflex blink suppression with and without SC stimulation before and after the drug using parametric statistics. To determine the latency of reflex blink suppression after a single stimulus, five consecutive OOemg responses of either stimulated or unstimulated trials were collected at 15 kHz and averaged. We compared the two averaged wave forms by subtracting the OOemg waveform with a stimulus from the OOemg wave form without a stimulus. We took the mean and SD of the differences of 3 msec of baseline data. We defined the suppression evoked by microstimulation as significant when the difference between the waveforms was 2 SD below the mean of the differences in the baseline for >30 consecutive points (2 msec). We calculated latency as the time after the stimulus when the stimulated wave form first showed the 2 SD decrease in magnitude that lasted at least 30 consecutive points. The 2 msec period ensured that short random differences between the two wave forms were ignored. After analysis, the wave forms were smoothed with a 250 Hz low pass filter to facilitate visual comparison of the records.
Histology. At the end of the experiments, deeply anesthetized animals were perfused intracardially with a warm solution of 6.0% dextran in 0.1 M phosphate buffer (PB; pH 7.4) and then with cold 10% formalin in 0.1 M PB. The brains were then immersed in a 30% sucrose solution in PB. The brains were cut into 100 µm frozen sections and stained with cresyl violet to reconstruct electrode placement sites as marked by fast green dye injections.
RESULTS
Because suppression of reflex blinks was most effective at deep SC stimulation sites, in the initial experiments we investigated whether SC stimulation suppressed reflex blinks by directly activating periaqueductal grey (PAG) antinociceptive circuits. If blink suppression involved PAG mechanisms, then the effects of SC stimulation should be opioid-sensitive and last for periods of minutes (Levine et al., 1991130 msec). Also consistent with the lack of PAG involvement in SC suppression of reflex blinks, a systemic injection of naloxone at concentrations sufficient to block PAG anti-nociceptive activity (Cazala and David, 1991
Fig. 1. Effect of the delay between the onset of the SC stimulation and the occurrence of the corneal stimulus on reflex blink magnitude. A, OOemg response to a corneal stimulus (Corn) with (bottom trace) and without (top trace) a preceding 40 µA, 70 msec, 200 Hz train of SC stimulation (black bar) that terminated 5 msec before the corneal stimulus. Each trace is the average of five rectified blinks. B, The diagram illustrates stimulus conditions. The corneal stimulus (Corn) occurred 100 msec () compared to trials without superior colliculus stimulation (
). All data are normalized to the mean magnitude of all blinks at all delays without SC stimulation. Each point is the mean of 25 blinks (5 blinks from 5 animals), and the error bars are SEM.
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Microstimulation of almost all brainstem areas receiving SC afferents suppressed trigeminal reflex blinks. For example, stimulation of the NRM with current intensities as low as 15 µA readily suppressed reflex blinks (Fig. 2A). Seventy millisecond trains of stimuli significantly suppressed OOemg activity in all four rats tested (Fig. 2B; Kruskal-Wallis = 6.05, p < 0.01). The trigeminal reflex blink suppression produced by brainstem microstimulation could have occurred because the electrical stimulus activated fibers of passage from the SC or because several independent pools of neurons linked the SC to trigeminal reflex blink circuits. As an initial step to establish a causal linkage, we determined the latency of OOemg suppression after a single stimulus to the SC and repeated this procedure in candidate brainstem structures. 
Fig. 2. Suppression of reflex blinks by NRM microstimulation. A, Orbicularis oculi response to a corneal stimulus (Corn) with (solid line) and without (dotted line) a preceding 70 msec, 200 Hz, 15 µA stimulus train to the nucleus raphe magnus (Raphe Stim) that ended 5 msec before the corneal stimulus. Each trace is the average of five rectified responses. B, Group data from four animals (at least 5 blinks per condition per animal) illustrating OOemg magnitude with preceding NRM microstimulation (solid bar, Stim) relative to OOemg blink magnitude without NRM stimulation (hatched bar, Con). Error bars are SEM.
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At SC sites where trains of low-intensity, SC stimulation induced reflex blink suppression, a single pulse presented to the SC of five animals during a corneal-evoked reflex blink transiently suppressed OOemg activity (Fig. 3A). As suggested by the time course experiment (Fig. 1), the SC stimulation was more effective and reliable when it occurred during the OOemg response. Because the latency of the OOemg response to corneal stimulation varied between animals, the data from only two of these animals could be used to determine a reliable latency measure. When there was sufficient OOemg activity before the onset of the single SC pulse (i.e., at least 10 msec), the mean latency to the transient OOemg suppression was 5.4 msec (Fig. 3, Table 1). 
Fig. 3. A single stimulus to the superior colliculus or the nucleus raphe magnus transiently decreases reflex blink amplitude. A, Unfiltered OOemg response to corneal stimulation with (solid line, SC Stim) and without (dotted line, Unstim) a single 80 µsec pulse to the superior colliculus (SC Stim, dashed vertical line). Traces are unfiltered (top traces) or filtered (bottom traces) at 250 Hz to facilitate comparison of the stimulated and unstimulated records. Each trace is the average of five rectified OOemg responses. B, A single stimulus of the nucleus raphe magnus transiently decreases blink amplitude at a shorter latency than SC stimulation. OOemg response to corneal stimulation with (solid line, NRM Stim) and without (dotted line, Unstim) a single 80 µsec pulse to the nucleus raphe magnus (NRM Stim, dashed vertical line). Traces are unfiltered (top traces) or filtered (bottom traces) at 250 Hz to facilitate comparison of the stimulated and unstimulated records. Each trace is the average of five rectified OOemg responses.
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Table 1. Latency of decrease in OOemg
Latency from OOemg onset (msec) Superior colliculus stim Nucleus raphe magnus stim 13 4.1 18 5.9 12.7 3.5 26.2 4 16.8 5.75 15.8 5 Latency of the decrease in OOemg magnitude after a single stimulus to the superior colliculus (Superior colliculus stim) or the nucleus raphe magnus (Nucleus raphe magnus stim) as a function of the time after the onset of corneally evoked OOemg activity that the stimulus occurs (Latency from OOemg onset) in msec.
If a brainstem area links the SC to the trigeminal reflex blink circuits, stimulating that brainstem nucleus should produce suppression at a shorter latency than SC stimulation at all delays. We tested the nucleus pontis caudalis (NPc), the nucleus paragigantocellularis (PGi), the NRM, and the nucleus supragenualis rostral to the prepositus hypoglossi nucleus (S.Genu/PH). Trains of low-intensity stimuli presented to all of these brainstem areas suppressed reflex blinking. The NRM, however, was the only structure in which stimulation transiently suppressed OOemg with a latency shorter than SC stimulation in all four animals tested (Fig. 3B, Table 1). Other neural structures that also transiently suppressed OOemg activity with single-pulse stimulation did so at latencies that were much longer and more variable than those obtained with NRM stimulation. Single-pulse stimuli delivered to NRM also produced deeper suppression than the other structures. The mean 4.4 msec latency suppression of OOemg activity with NRM stimulation in four animals is consistent with a single synapse intervening between the SC and the NRM.
Reflex blink suppression caused by SC stimulation could occur at any one of the three neurons of the corneal reflex blink circuit: (1) A primary afferents; (2) spinal trigeminal second-order neurons; or (3) OO motoneurons. Previous work showed that stimulation of the NRM exerted its suppressive effects on trigeminal neuron responsiveness (Dostrovsky, 1980
Fig. 4. Effect of trains of SC microstimulation on facial nucleus antidromic field potentials. A, OOemg response to corneal stimulation at the intensity used to assess OO motoneuron excitability with (solid line) and without (dashed line) preceding, 70 msec train of SC stimulation. B, Antidromic field potential from the OO subdivision of the facial nucleus evoked by stimulation of the zygomatic branch of the facial nerve with (solid line) and without (dashed line) preceding SC stimulation. Each trace is the average of 10 responses.
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Unlike the case with OO motoneurons, SC stimulation decreased the activity of the trigeminal nucleus as well as OOemg magnitude (Fig. 5). Primary afferent fibers innervating the rat cornea arise from the ophthalmic division of the trigeminal nerve and terminate within the trigeminal nucleus at the border between the rostral caudalis subdivision and the caudal interpolaris subdivision (Marfurt and Del Toro, 1987 
Fig. 5. Effect of a train of SC stimulation on simultaneously recorded OOemg activity and trigeminal field potentials evoked by a corneal stimulus (Corn). Top traces are superimposed orbicularis oculi emg (OOemg) responses, and bottom traces are superimposed trigeminal field potentials (V Field). Solid lines show trials with a preceding, 70 msec train of SC stimulation (SC Stim) that terminated 5 msec before the corneal stimulus. Dotted lines show records from unstimulated trails (Control). Each trace is an average of 10 responses.
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Fig. 6. Effect of a microinjection of muscimol into the SC stimulation on simultaneously recorded OOemg activity and trigeminal field potentials evoked by a corneal stimulus (Corn). Top traces are superimposed orbicularis oculi emg (OOemg) responses, and bottom traces are superimposed trigeminal field potentials (V Field). Solid lines show trials after a 0.5 µl injection of 1.0% muscimol into the contralateral SC (Post Muscimol). Dotted lines show records collected before the muscimol injection (Pre Muscimol). Each trace is an average of 12 responses.
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Stimulation of the NRM causes the release of serotonin in the trigeminal nucleus (Shibutani, 1990 
Fig. 7. Systemic metergoline injections block SC suppression of orbicularis oculi (OOemg) and trigeminal field potentials (V Field) evoked by corneal stimulation (Stim). Simultaneously recorded OOemg (top traces) and trigeminal field responses (bottom traces) to a corneal stimulus with (solid line, SC Stim) and without (dotted line, Control) a preceding, 70 msec SC stimulation that terminated 5 msec before the corneal stimulus before (left records) and after (right records) a 6 mg/kg injection of metergoline. Each trace is an average of 10 rectified responses.
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Fig. 8. Schematic coronal hemisections through the trigeminal nucleus of the rat brain (Swanson, 1992
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The ability of SC stimulation to suppress reflex blinking was examined before and after reversible inactivation of the NRM with microinjections of muscimol in eight animals (Fig. 9; 1 animal 0.5 µl; 7 animals 50-100 nl; 1.0%). At sites where trains of NRM stimulation suppressed reflex blinking (6 rats), a microinjection of muscimol significantly reduced the ability of SC stimulation to suppress blinking (Fig. 9B; t(5) = 
Fig. 9. Effect of microinjections of muscimol into the nucleus raphe magnus on suppression of corneal evoked blinks by SC stimulation. A, OOemg responses to corneal stimulation with (dashed lines) and without (solid lines) a preceding, 70 msec train of SC stimulation that terminated 5 msec before a corneal stimulus (
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Fig. 10. Location of muscimol injections in the nucleus raphe magnus experiments. Black squares show injection sites that reduced SC suppression of trigeminal reflex blinks within 10 min. Filled circles show injection sites where reduction of SC blink suppression occurred between 30 and 45 min after the injection. The open circles identify ineffective injection sites. gVII, Genu of the facial nerve; NPc, nucleus pontis caudalis; NRM, nucleus raphe magnus.
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DISCUSSION
Changes in the level of SC activity dramatically modify reflex blink magnitude. Inhibition of the SC produced marked reflex blink hyperexcitability, whereas activating the SC reduced trigeminal reflex blink amplitude (Basso et al., 1996
The SC could suppress the corneal blink reflex by inhibiting the primary afferents, the trigeminal or reticular interneurons, or the OO motoneurons that form the minimal corneal reflex blink circuit. Two lines of evidence argue against the SC acting to inhibit OO motoneuron activity. First, SC stimulation did not reliably alter the excitability of OO motoneurons (Fig. 4). Second, the facial motoneurons that receive disynaptic inhibition from SC stimulation tend to innervate auricular muscles (Vidal et al., 1988
The current experiments provide strong evidence that the NRM links the SC to the blink circuit. Stimulation of the SC suppresses OOemg activity in 5.4 msec, whereas microstimulation of the NRM suppresses OOemg activity in 4.4 msec. The 1 msec latency difference is consistent with a monosynaptic projection from the SC to the NRM. Because the contralateral descending collicular efferent system originating in the rostral and lateral SC projects to the pontine and medullary raphe nuclei (rat: Redgrave et al., 1987
The present results suggest that reflex blink amplitude correlates inversely with NRM activity and serotonin release in the trigeminal nucleus. The modulation of reflex blink excitability during REM sleep supports this idea. For example, NRM neurons exhibit a decrease to a near cessation of their spontaneous tonic activity during REM sleep (Auerbach et al., 1985 An explanation of reflex blink hyperexcitability in Parkinson's disease
The present experiments combined with those of the previous study (Basso et al., 1996
Fig. 11. Circuit linking the basal ganglia and the trigeminal reflex blink circuit. NRM, Nucleus raphe magnus; SC, superior colliculus; SNr, substantia nigra pars reticulata; SpV, spinal trigeminal nucleus; V, trigeminal ganglion; VII, facial motoneurons.
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It is possible that, in addition to modulating tonic reflex blink magnitude, the BG modifies reflex amplitude phasically. McHaffie et al. (1989)
FOOTNOTES
Received March 18, 1996; revised July 31, 1996; accepted Aug. 27, 1996.
This work was supported by National Eye Institute Grant EY07391 (C.E.) and summer fellowships from the Parkinson's Disease Foundation. We thank Donna Schmidt for her expert technical assistance.
Correspondence should be addressed to Craig Evinger, Department of Neurobiology and Behavior, SUNY Stony Brook, Stony Brook, NY 11794-5230.
Dr. Basso's current address: Laboratory of Sensorimotor Research, National Eye Institute, Building 49, Room 2A50, Bethesda, MD 20892-4435.
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R. Leal-Campanario, A. Fairen, J. M. Delgado-Garcia, and A. Gruart
Electrical stimulation of the rostral medial prefrontal cortex in rabbits inhibits the expression of conditioned eyelid responses but not their acquisition
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M. A. Basso and P. Liu
Context-Dependent Effects of Substantia Nigra Stimulation on Eye Movements
J Neurophysiol, June 1, 2007; 97(6): 4129 - 4142.
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L. Di Clemente, G. Coppola, D. Magis, A. Fumal, V. De Pasqua, V. Di Piero, and J. Schoenen
Interictal habituation deficit of the nociceptive blink reflex: an endophenotypic marker for presymptomatic migraine?
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H. Rambold, A. Sprenger, and C. Helmchen
Effects of Voluntary Blinks on Saccades, Vergence Eye Movements, and Saccade-Vergence Interactions in Humans
J Neurophysiol, September 1, 2002; 88(3): 1220 - 1233.
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R. S. Baker, S. M. Radmanesh, and K. M. Abell
The Effect of Apomorphine on Blink Kinematics in Subhuman Primates with and without Facial Nerve Palsy
Invest. Ophthalmol. Vis. Sci., September 1, 2002; 43(9): 2933 - 2938.
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M. A. Basso and R. H. Wurtz
Neuronal Activity in Substantia Nigra Pars Reticulata during Target Selection
J. Neurosci., March 1, 2002; 22(5): 1883 - 1894.
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E. J. Schicatano, J. Mantzouranis, K. R. Peshori, J. Partin, and C. Evinger
Lid Restraint Evokes Two Types of Motor Adaptation
J. Neurosci., January 15, 2002; 22(2): 569 - 576.
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V. Tozlovanu, R. Forget, A. Iancu, and D. Boghen
Prolonged orbicularis oculi activity: A major factor in apraxia of lid opening
Neurology, September 25, 2001; 57(6): 1013 - 1018.
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H.H.L.M. Goossens and A. J. Van Opstal
Blink-Perturbed Saccades in Monkey. I. Behavioral Analysis
J Neurophysiol, June 1, 2000; 83(6): 3411 - 3429.
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H.H.L.M. Goossens and A. J. Van Opstal
Blink-Perturbed Saccades in Monkey. II. Superior Colliculus Activity
J Neurophysiol, June 1, 2000; 83(6): 3430 - 3452.
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E. J. Schicatano, K. R. Peshori, R. Gopalaswamy, E. Sahay, and C. Evinger
Reflex Excitability Regulates Prepulse Inhibition
J. Neurosci., June 1, 2000; 20(11): 4240 - 4247.
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L. J. Bour, M. Aramideh, and B. W. Ongerboer de Visser
Neurophysiological Aspects of Eye and Eyelid Movements During Blinking in Humans
J Neurophysiol, January 1, 2000; 83(1): 166 - 176.
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J. Verghese, C. Milling, and D. M. Rosenbaum
Ptosis, blepharospasm, and apraxia of eyelid opening secondary to putaminal hemorrhage
Neurology, August 1, 1999; 53(3): 652 - 652.
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E. J. Schicatano, M. A. Basso, and C. Evinger
Animal Model Explains the Origins of the Cranial Dystonia Benign Essential Blepharospasm
J Neurophysiol, May 1, 1997; 77(5): 2842 - 2846.
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M. A. Basso, A. S. Powers, and C. Evinger
An Explanation for Reflex Blink Hyperexcitability in Parkinson's Disease. I. Superior Colliculus
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ABSTRACT
