The complaints of tiredness, fatigue, sedation, and sleepiness are common among patients with psychiatric disorders. Many factors contribute to the experience of diminished alertness across individuals with such complaints. Potential contributing elements include presumed physiological epiphenomena of primary pathological conditions (e.g., "hypersomnia" in "atypical" depression), medication effects, use or abuse of sedating substances, sleep disruption, advanced or delayed circadian rhythm phase, voluntary or involuntary sleep restriction, and other sleep disorders (e.g., obstructive sleep apnea syndrome). The careful characterization of the complaint is of key importance in the evaluation of suboptimal alertness or fatigue for appropriate diagnosis and symptom management—primary treatment, when possible, or secondary amelioration.

Occasionally, patients will manifest somnolence or frank sleepiness—unrelated to factors such as those noted above or to the primary psychiatric condition they have—as a result of distinct central nervous system (CNS) dysfunction. Sometimes the CNS condition of excessive sleepiness is comorbid with a primary psychiatric disorder. However, not infrequently, the patient receives the diagnosis of a psychiatric illness when none is present. Comorbid disorders of somnolence or excessive daytime sleepiness (EDS) add frustration to the diagnostic workup and complexity to the treatment of individuals with psychiatric disorders. Sleep-related conditions that arise from CNS dysfunction tend to be less familiar to the clinician. Indeed, lack of an understanding of these conditions not only leads to their being misdiagnosed or overlooked, but at times results in gross mismanagement (e.g., the use of antipsychotic medications for narcolepsy-related hypnagogic hallucinations).

Narcolepsy is the most well known and extensively studied of the EDS conditions arising from CNS dysfunction, yet it, too, is often misunderstood and misdiagnosed. Idiopathic hypersomnia, the recurrent hypersomnias, and EDS associated with nervous system disorders also must be understood in order to provide appropriate evaluation and management. In this chapter, we summarize the distinguishing features of these clinical syndromes of primary EDS and provide a brief overview of their pharmacologic management. Additionally, we review the great advances in our understanding of the pathophysiology of narcolepsy that have occurred in the past few years.

The epidemiology of EDS has been explored, using a variety of research methods, in many countries around the world. The largest and most comprehensive representative population survey was performed across four Western European countries (the United Kingdom, Germany, Spain, and Italy). Substantial EDS, defined as meeting three parameters of marked sleepiness during three or more days a week, was reported in 15% of this combined population (Ohayon et al. 2002). Smaller population surveys in the United States have been conducted. Two recent polls suggest that 15%—16% of the U.S. population may experience EDS that interferes with daily activities a few days a week or more (National Sleep Foundation 2002, 2003). These data do not indicate the percentage of sleepy individuals whose sleepiness results from insufficient sleep or environmental factors rather than from pathological causes of EDS.

The prevalence of syndromes of CNS-mediated sleepiness is much more difficult to assess than that of EDS in the general population and, with the exception of narcolepsy, it remains poorly characterized. Data gathered in U.S. and Western European narcolepsy studies demonstrate a fairly consistent prevalence of approximately 0.05%, although rates as low as 0.002% and as high as 0.16% have been reported for Israel and Japan, respectively (Mignot 1998). In general, the published literature on the epidemiology of CNS-mediated EDS syndromes indicates a total prevalence that ranges from as high as 2%—3% to much less than 1% of the population.

Fragmented sleep and insufficient sleep

Essential in the evaluation of patients presenting with EDS is the determination of the presence or absence of the two most common causes of EDS: 1) fragmented sleep due to extrinsic or intrinsic factors and 2) insufficient sleep. Fragmented sleep, predominantly microfragmentation resulting from such conditions as sleep-related breathing disorders (e.g., obstructive sleep apnea syndrome) and periodic limb movement disorder (PLMD), is an important consideration in the evaluation of EDS. These conditions are addressed in Chapter 3, "Sleep Apnea," and Chapter 5, "Restless Legs Syndrome," in this volume. The most common cause of daytime sleepiness is insufficient sleep, which may reflect poor sleep "hygiene" (behaviors negatively affecting sleep) or self-imposed or socially dictated sleep deprivation. Insufficient sleep is expected to lead to frank EDS, yet the more common subjective complaints are those of tiredness, lack of energy, or fatigue. Additionally, decrements in attention, learning capacity, short-term memory, and psychomotor performance, with or without EDS, may be present. Moreover, irritability, poor impulse control, or other forms of mood instability may exist alone or in concert with the above-noted features in individuals with insufficient sleep.

Primary disorders of excessive daytime sleepiness

Two diagnostic classification manuals are commonly used to specify diagnostic criteria for disorders of primary EDS. DSM-IV-TR (American Psychiatric Association 2000) subcategorizes these disorders into narcolepsy and primary hypersomnia; the latter includes all non-narcolepsy forms of primary EDS. The International Classification of Sleep Disorders (ICSD; American Sleep Disorders Association 1997) subcategorizes primary EDS into narcolepsy, idiopathic hypersomnia, recurrent hypersomnia, and posttraumatic hypersomnia. We have selected the ICSD format to organize this review, but we suggest the expansion of the posttraumatic category to include CNS pathology in addition to trauma.

As suggested by both DSM-IV-TR and ICSD, several entities may be regarded as primary disorders of EDS. Narcolepsy, the best known and the most completely understood disorder of this group, will be considered at greater length; other clinical syndromes will be reviewed more briefly. Patients with these CNS-mediated EDS syndromes commonly receive a misdiagnosis of a mood disorder and are treated with antidepressant therapy.

Narcolepsy

Narcolepsy is a syndrome of unknown etiology characterized by a profound degree of EDS. Narcolepsy usually occurs in association with cataplexy and other symptoms and signs, including hypnagogic or hypnopompic hallucinations, sleep paralysis, automatic behavior, and disrupted nocturnal sleep (American Sleep Disorders Association 1997). Symptoms most often begin during adolescence or young adulthood. However, narcolepsy may also occur earlier in childhood or not until the third or fourth decade of life. The impact of narcolepsy on quality of life is equal to that of other chronic neurologic disorders, such as Parkinson’s disease (Beusterien et al. 1999). No symptom or sign of narcolepsy is specific to narcolepsy; even cataplexy unrelated to narcolepsy occurs, rarely, either as an isolated symptom or in conjunction with other conditions. Unfortunately, the average duration from symptom onset to the conferring of an accurate diagnosis is greater than 10 years. This substantial delay in diagnosis is largely due to clinicians’ lack of education about and experience with this disorder.

Symptoms of narcolepsy include the following:

Hypnagogic hallucinations, sleep paralysis, and automatic behavior are not specific to narcolepsy and may occur in other sleep disorders, as well as in healthy individuals. These symptoms are, however, far more common and occur with much greater frequency in narcolepsy.

The following tools are available for the evaluation of narcolepsy:

Idiopathic hypersomnia

Idiopathic hypersomnia (previously labeled idiopathic CNS hypersomnia) is an incompletely defined disorder characterized by EDS. This diagnosis has been used as a nosologic haven for classifying individuals with excessive somnolence but without the classic features of narcolepsy or another disorder known to cause EDS, such as sleep apnea. Without doubt, many patients have received diagnoses of idiopathic hypersomnia who actually had other disorders, such as narcolepsy without cataplexy, delayed sleep phase syndrome, or upper airway resistance syndrome, a subtle variant of the obstructive sleep apnea syndrome (Guilleminault et al. 1993). Roth (1976) described monosymptomatic and polysymptomatic forms of idiopathic hypersomnia, the former characterized by EDS alone and the latter characterized by EDS, prolonged nocturnal sleep time, and marked difficulty with awakening. Others have suggested that the category of idiopathic hypersomnia is heterogeneous, including individuals with EDS with or without one or more of the other features of Roth’s polysymptomatic form (Aldrich 1996).

Idiopathic hypersomnia is believed to be less common than narcolepsy; estimation of prevalence, however, is elusive because strict diagnostic criteria are lacking and no specific biological marker has been identified. Typically, onset of symptoms occurs in adolescence or early adulthood. Symptoms generally persist for life, although a few patients with idiopathic hypersomnia have improved over time or attained complete remission of symptoms (Bassetti and Aldrich 1997; Billiard and Dauvilliers 2001; Bruck and Parkes 1996). The etiology of the disorder is not known, but viral illnesses, including Guillain-Barré syndrome, hepatitis, mononucleosis, and atypical viral pneumonia, may herald the onset of sleepiness in a subset of patients. EDS may occur as part of the acute illness, but it persists after the other symptoms subside. Familial cases are known to occur, with increased frequency of HLA-Cw2 and HLA-DR11 (Montplaisir and Poirier 1988). Some of these patients have associated symptoms suggesting autonomic nervous system dysfunction, including orthostatic hypotension, syncope, vascular headaches, and peripheral vascular complaints. Most patients with idiopathic hypersomnia have neither a family history nor an obvious associated viral illness. Little is known about the pathophysiology of idiopathic hypersomnia. No animal model is available for study. Neurochemical studies examining CSF have suggested that patients with idiopathic hypersomnia may have altered noradrenergic system function (Faull et al. 1983, 1986; Montplaisir et al. 1982).

The clinical picture of idiopathic hypersomnia varies among individual patients. The disorder may be mistaken for narcolepsy if a careful history is not taken. The two disorders share several common features, including similar age of onset, lifelong persistence after onset, EDS as the primary symptom, and familial clustering of some cases. However, essential differences between the disorders become apparent in the history and in diagnostic studies (see Table 1T1). Patients with idiopathic CNS hypersomnia present with EDS, but with neither cataplexy (although some patients have episodes of sleep paralysis or hypnagogic hallucinations) nor significant nocturnal sleep disruption (Billiard and Dauvilliers 2001). They complain of daytime sleepiness that interferes with normal activities. Occupational and social functioning may be severely affected by sleepiness. Nocturnal sleep time tends to be long, and patients are usually difficult to awaken in the morning, becoming irritable or even abusive in response to the efforts of others to rouse them. In some patients, this difficulty may be substantial and may include confusion, disorientation, and poor motor coordination, a condition sometimes termed "sleep drunkenness" (Roth et al. 1972). These patients often take naps, which may be prolonged but, in contrast to naps in narcolepsy, are usually nonrefreshing. No amount of sleep ameliorates the EDS. "Microsleeps," with or without automatic behavior, may occur throughout the day.

Polysomnographic studies of patients with idiopathic CNS hypersomnia usually reveal shortened initial sleep latency, increased total sleep time, and normal sleep architecture, in contrast to narcoleptic patients, who exhibit significant sleep fragmentation. Using quantitative electroencephalography, Sforza et al. (2000) found reduced sleep pressure, as evidenced by decreased slow-wave activity during the first two NREM episodes of nocturnal sleep, in patients with idiopathic hypersomnia. Mean sleep latency on MSLT is usually reduced, often in the 8—10-minute range but sometimes dramatically shorter. Also in contrast to narcolepsy, SOREMPs are not typically seen.

As with narcolepsy, other disorders producing EDS (such as insufficient sleep, sleep-related breathing disorders, PLMD, other sleep-fragmenting disorders, psychiatric diseases, and circadian rhythm disorders) must be ruled out before the diagnosis of idiopathic hypersomnia is made.

Recurrent hypersomnias

Kleine-Levin syndrome.

This uncommon disorder is a form of recurrent hypersomnia that occurs primarily in adolescents (Critchley 1967), with a male preponderance. It is characterized by the occurrence of episodes of EDS and is usually, but not invariably, accompanied by hyperphagia, aggressiveness, and hypersexuality. These episodes last for days to weeks and are separated by asymptomatic periods of weeks or months. During symptomatic periods, individuals sleep up to 18 hours per day and are usually drowsy (often to the degree of stupor), confused, and irritable the remainder of the time. During symptomatic episodes, polysomnographic studies show long total sleep time with high sleep efficiency and decreased slow-wave sleep. MSLT studies demonstrate short sleep latencies and SOREMPs (Rosenow et al. 2000).

The etiology of this syndrome remains obscure. Symptomatic cases of Kleine-Levin syndrome associated with structural brain lesions have been reported, but most cases are idiopathic. Single-photon emission computed tomography studies have demonstrated hypoperfusion in the thalamus in one patient and in the nondominant frontal lobe in another (Arias et al. 2002).

Menstrual-related hypersomnia.

In this form of recurrent hypersomnia, EDS occurs during the several days prior to menstruation (Billiard et al. 1975; Sachs et al. 1982). The prevalence of this syndrome has not been well characterized. Likewise, the etiology is not known, but presumably the symptoms are related to hormonal changes. Some cases of menstrual-related hypersomnia have responded to the blocking of ovulation with estrogen and progesterone (birth control pills) (Bamford 1993).

Idiopathic recurring stupor.

Numerous cases have been reported in which individuals (predominantly middle-aged males) are subject to stuporous episodes lasting from hours to days, in the absence of obvious toxic, metabolic, or structural cause. Episodes occur unpredictably, and the individuals are normal between episodes. Electroencephalographic data collected during symptomatic episodes have shown fast background activity in the 13—16 Hz range. Several of these patients have been shown to have elevated plasma and CSF levels of endozepine-4, an endogenous ligand with affinity for the benzodiazepine recognition site at the γ-aminobutyric acid type A receptor (Rothstein et al. 1992). Administration of flumazenil, a benzodiazepine antagonist, has produced transient awakening with normalization of the EEG profile (Lugaresi et al. 1998). In some cases, the episodes resolved spontaneously after several years. Similar cases have been reported in children (Soriani et al. 1997).

Nervous system disorders and excessive daytime sleepiness

EDS is often associated with disorders of the central or peripheral nervous system. It is a clinical feature of many toxic or metabolic encephalopathic processes. These disorders often present with other symptoms and signs, but EDS may dominate the picture, particularly in chronic cases. Structural brain lesions, including strokes, tumors, cysts, abscesses, hematomas, vascular malformations, hydrocephalus, and multiple sclerosis plaques, are known to produce EDS. Somnolence may result either from direct involvement of discrete brain regions (especially the brainstem reticular formation or midline dien-cephalic structures) or from effects on sleep continuity (for example, nocturnal seizure activity or sleep-related breathing disorders such as sleep apnea).

EDS is a frequent sequela of encephalitis or head trauma. Victims of "encephalitis lethargica," described by Von Economo in the early twentieth century, were found to have lesions in the midbrain, subthalamus, and hypothalamus. Additionally, post-traumatic narcolepsy with cataplexy is well documented (Francisco and Ivanhoe 1996). Epileptic patients may experience EDS as a consequence of medication effects or, less obviously, nocturnal seizure activity (Manni and Tartara 2000). EDS may be associated with numerous infectious agents affecting the CNS, including bacteria, viruses, fungi, and parasites. Perhaps the best known is trypanosomiasis, which is called "sleeping sickness" because of the prominent hypersomnia. Sleepiness may occur with acute infectious illness, even without direct invasion of the nervous system, and may be mediated by cytokines, including interferon, interleukins, and tumor necrosis factor (Toth and Opp 2002). EDS may also persist chronically after certain viral infections (Guilleminault and Mondini 1986).

Sleep disruption and EDS are also common in neurodegenerative disorders, including Parkinson’s disease, Alzheimer’s disease, and other dementias, as well as multiple system atrophy (Askenasy 1993; Chokroverty 1996; Trenkwalder 1998). Patients with neuromuscular disorders or peripheral neuropathies may also develop EDS due to associated central or obstructive sleep apnea, pain, or PLMD (George 2000). Patients with myotonic dystrophy often suffer from EDS, even in the absence of sleep-disordered breathing (Gibbs et al. 2002).

Finally, psychiatric illness, especially depression, is often accompanied by complaints of EDS. Indeed, tiredness, fatigue, or lack of energy are reported by an overwhelming majority of patients with major depression (Tylee et al. 1999). However, evaluation of true EDS with subjective rating scales and objective measures suggests that frank sleepiness or a high sleep propensity may be much less common than the complaint of fatigue or lack of energy. The few published studies evaluating objective measures of sleepiness (such as the MSLT) in depression suggest that only a minority of depressed patients have clinically important EDS and that the majority are in the normal range (Reynolds et al. 1982).

Behavioral treatment

In addition to the use of medications, the effective treatment of primary EDS conditions requires instituting structured and regular nocturnal sleep as well as structured daytime naps. A period of 8 hours or longer should be established for nocturnal sleep, with a consistent bedtime and time of morning awakening. Inadequate sleep duration, poor sleep environment, and fluctuating sleep-wake schedules can contribute substantially to daytime sleepiness, even in patients with primary sleep disorders. Moreover, shift work in any form is usually problematic. Additionally, in many EDS disorders, such as narcolepsy, scheduling two or more brief naps at regular times during the day is almost always necessary to further enhance daytime function. The importance of regular and adequate nocturnal and daytime sleep must always be emphasized with the patient.

Pharmacologic treatment

Stimulants and other alerting medications

Alerting agents provide a critical component of treatment for most patients with primary disorders of EDS (Mitler et al. 1994) (Table 2T2). Occasionally, patients may wish to avoid medications and instead may attempt to take extra naps during the day. This approach can be successful but usually fails to provide enough daytime alertness to function adequately. For most patients with narcolepsy, alerting agents do not yield a normal degree of daytime alertness but will nonetheless produce substantial improvement (Mitler et al. 1994). Clinically, the practice of combining two alerting agents of different chemical classes has been employed when a single agent is insufficient. This technique can be useful and is undergoing controlled evaluation in a large international trial with modafinil and sodium oxybate in narcolepsy.

Modafinil.

Modafinil is a wake-promoting therapeutic somewhat comparable to traditional stimulants in promoting alertness, but with a different mechanism of action. This mechanism is unknown, but modafinil appears to act more locally at hypo-thalamic regions and less globally on the CNS than the traditional stimulants (US Modafinil in Narcolepsy Multicenter Study Group 2000). The clinical duration of effect of modafinil may be longer because its serum half-life (12—15 hours) is longer than that of traditional stimulants. Modafinil has been evaluated extensively in the treatment of the EDS of narcolepsy, and in other sleep disorders manifesting EDS, and has been found to be useful in ameliorating EDS in these conditions (US Modafinil in Narcolepsy Multicenter Study Group 1998).

Sodium oxybate (GHB).

Another agent that has been found to enhance alertness in narcolepsy is sodium oxybate, also known as γ-hydroxybutyrate (GHB). This agent has been explored extensively and found to be highly effective for the treatment of EDS in narcolepsy (Mamelak et al. 2004). The mechanism of action of the agent has been explored over many years, but how it effects improved alertness is unknown (Tunnicliff and Cash 2002). Data from multiple studies demonstrate that sodium oxy-bate imparts a degree of alertness similar to that of other agents and that its effect may be additive when used in combination with other stimulants (US Xyrem in Narcolepsy Multi-center Study Group 2002). Whether sodium oxybate will prove useful in other conditions of primary EDS is unknown.

Traditional stimulants.

Commonly used traditional stimulants include methylphenidate, dextroamphetamine, and methamphetamine (Mitler et al. 1994). Other sympathomimetic amines and sustained-release preparations are available. Patients may experience negative effects with any alerting agent. Some patients report rebound hypersomnia (exacerbation of sleepiness) as the dose wears off. Tolerance (tachyphylaxis) to the alerting effect may occur with time in some patients. In cases of tolerance, switching to a different class of medication or providing a "drug holiday" can be useful.

Medications for cataplexy (anticataplectics)

Medications useful in the treatment of cataplexy usually also improve hypnagogic/hypnopompic hallucinations and sleep paralysis.

Sodium oxybate (GHB).

In addition to its effect on EDS in narcolepsy, sodium oxybate is remarkably effective as an anticataplectic. It has been extensively evaluated as an anticataplectic agent over many years (US Xyrem in Narcolepsy Multi-center Study Group 2002). Additionally, GHB is effective in reducing nocturnal sleep disruptions and consolidating nocturnal sleep. Again, the mechanism of action of GHB in treating these symptoms is unknown (Tunnicliff and Cash 2002).

Antidepressants.

Very low doses of tricyclic anti-depressants (TCA) and typical antidepressant doses of selective serotonin reuptake inhibitors (SSRI), especially those with CNS noradrenergic activity, are also useful in treating cataplexy (Nishino and Mignot 1997). Tolerance to these traditional cataplexy medications can occur, requiring medication switch or drug holiday. Atomoxetine, venlafaxine, and other newer non-SSRI/non-tricyclic antide-pressants have been reported in individual cases to provide effective treatment for cataplexy, although they have not yet been rigorously studied.

Narcolepsy symptoms

The similarity between cataplexy and REM sleep atonia, the presence of frequent episodes of hypnagogic hallucinations and of sleep paralysis, and the propensity for narcolepsy patients to go directly from wakefulness into REM sleep suggest that narcolepsy is primarily a "disease of REM sleep" (Dement et al. 1966). This hypothesis may, however, be too simplistic, and it does not explain the presence of sleepiness during the day and the short latency to both NREM and REM sleep during nocturnal and nap recordings. A complementary hypothesis is that narcolepsy results from the disruption of the control mechanisms of both sleep and wakefulness or, in other words, from vigilance-state boundary problems (Broughton et al. 1986). According to this hypothesis, a cataplectic attack represents an intrusion of REM sleep atonia during wakefulness, and the hypnagogic hallucinations appear as dreamlike imagery taking place in the waking state, especially at sleep onset in patients who frequently have SOREMPs.

Cataplexy is associated with an inhibition of the monosynaptic H-reflex and the polysynaptic deep tendon reflexes (Guilleminault et al. 1974). In healthy subjects, it is only during REM sleep that the H-reflex is totally suppressed. This finding highlights the relationship between the inhibition of motor processes during REM sleep and the sudden atonia and areflexia seen during cataplexy. Studies in canine narcolepsy, however, suggest that the mechanisms for induction of cataplexy are different from those for REM sleep (Nishino et al. 2000a). Furthermore, an extended human study confirmed that cataplexy correlates much more highly with hypocretin deficiency (discussed below) than do other REM sleep—related phenomena (Mignot et al. 2002). Cataplexy may thus be viewed as a hypocretin-deficiency pathological phenomenon somewhat distinct from other REM-related symptoms. Patients with other sleep disorders such as sleep apnea, and even healthy individuals, can manifest SOREMPs, hypnagogic hallucinations, and sleep paralysis when their sleep-wake patterns are sufficiently disturbed. However, these subjects never develop cataplexy, further supporting the proposal that cataplexy is unrelated to other REM-associated symptoms (Aldrich et al. 1997; Bishop et al. 1996; Fukuda et al. 1987; Ohayon et al. 1996). Although cataplexy and REM sleep atonia have great similarity and possibly share a common executive system, the regulatory mechanisms of the two states are not necessarily identical. The mechanism of emotional triggering of cataplexy remains undetermined.

Narcolepsy, human leukocyte antigen, and the immune system

A remarkably high association of HLA with narcolepsy was discovered in the early 1980s (Juji et al. 1984). Since the time of this initial finding, a variety of research across multiple ethnic groups has corroborated the existence of this strong HLA association. The most specific marker of narcolepsy in a number of different ethnic groups studied to date is DQB1*0602 (Mignot 1998). This association is seen in an average of approximately 90% of those with unequivocal cataplexy (Mignot et al. 1997). Importantly, this association is substantially lower (only approximately 40%) in individuals who have received the diagnosis of narcolepsy but do not have cataplexy.

The strong association between HLA type and narcolepsy with cataplexy raises the possibility that narcolepsy is an autoimmune disease (Mignot et al. 1992). There is, however, no evidence of inflammatory processes or immune abnormalities associated with narcolepsy (Mignot et al. 1992). Studies have found no classical autoantibodies and no increase in oligoclonal CSF bands in individuals with narcolepsy (Fredrikson et al. 1990). Results of typical autoimmune pathology measures (erythrocyte sedimentation rates, serum immunoglobulin levels, C-reactive protein levels, complement levels, and lymphocyte subset ratios) are apparently normal in narcoleptic patients (Matsuki et al. 1988). In contrast, a variety of serological tests performed in narcoleptic patients and in age- and sex-matched control subjects yielded higher levels of antistreptolysin 0 and anti-DNase antibodies in patients than in control subjects (Billiard et al. 1989; Montplaisir et al. 1989). In view of these preliminary data, further exploration of possible immune-related dysfunction in narcolepsy is warranted.

Narcolepsy genes in animal models

Narcolepsy has been described in several animal species, including dogs, and most recently in genetically engineered mice models. Canine narcolepsy is a naturally occurring model, with both sporadic forms (17 breeds) and familial forms (Doberman, Labrador, and dachshund). In Doberman pinschers and Labrador retrievers, the disease is transmitted as a recessive autosomal trait with complete penetrance (Mignot et al. 1991).

In 1999, using positional cloning and gene targeting strategies, two groups independently revealed the pathogenesis of narcolepsy in animals. The lack of the hypothalamic neuropeptide hypocretin/orexin ligand (preprohypocretin/orexin gene knockout mice [Chemelli et al. 1999]) or mutations in one of the two hypocretin/orexin receptor genes (hypocretin receptor 2 [hcrtr 2] gene in autosomal recessive canine narcolepsy [Lin et al. 1999]) was observed to result in narcolepsy. Extensive screening in humans, especially in familial and early-onset narcolepsy, demonstrated that mutations in hypocretin-related genes are rare; only a single case with early onset (at age 6 months) was found to be associated with a single-point mutation in the preprohypocretin gene (Peyron et al. 2000).

Hypocretin deficiency in human narcolepsy

Despite the lack of genetic abnormalities in the hypocretin system, the large majority (85%—90%) of patients with narcolepsy-cataplexy have low or undetectable hypocretin-1 ligand in their cerebrospinal fluid (Figure 1F1) (Nishino et al. 2000b, 2001b). This hypocretin deficiency is tightly associated with occurrence of cataplexy and HLA-DQ1*0602 positivity (Kanbayashi et al. 2002; Krahn et al. 2002; Mignot et al. 2002). Postmortem human studies, although using few brains, have confirmed hypocretin ligand deficiency (both hypocretin-1 and -2) in the narcoleptic brain (Figure 1F1) (Peyron et al. 2000; Thannickal et al. 2000). Hypocretin deficiency has also been observed in sporadic cases of canine narcolepsy (7 of 7 animals studied; the results of 4 cases are reported), suggesting that the pathophysiology in these animals mirrors that of most human cases (Ripley et al. 2001a).

The establishment of CSF hypocretin measurement as a new diagnostic tool in human narcolepsy is encouraging. Although positive predictive value is not 100%, low CSF hypocretin-1 levels are very specific for narcolepsy when compared with other sleep or neurologic disorders (Figure 2F2) (Kanbayashi et al. 2002; Mignot et al. 2002; Ripley et al. 2001b). Previously, no specific and sensitive diagnostic test for narcolepsy based on the pathophysiology of the disease was available, and the final diagnosis was often delayed for several years after the onset (typically during adolescence) of the disease (Alaila 1992). Many patients with narcolepsy and related EDS disorders are therefore likely to obtain immediate benefit from this new specific diagnostic test. In addition, hypocretin agonists may be promising in the treatment of narcolepsy.

Hypocretin/orexin and sleep physiology

Hypocretins/orexins were identified by two independent research groups in 1998, one year prior to the cloning of the canine narcolepsy gene. One group called the peptides hypocretin because of their primary hypothalamic localization and similarities with the hormone secretin (De Lecea et al. 1998). The other group called the molecules orexin after observing that central administration of these peptides increased appetite in rats (Sakurai et al. 1998). Hypocretin-1 and -2 are produced exclusively by a well-defined group of neurons localized in the lateral hypothalamus. The neurons project to the olfactory bulb, cerebral cortex, thalamus, hypothalamus, and brainstem, particularly the locus coeruleus (LC), raphe nucleus, and cholinergic nuclei and cholinoceptive sites (such as pontine reticular formation), thought to be important for sleep regulation (Peyron et al. 1998).

The hypocretin system is a major excitatory system that affects the activity of monoaminergic (dopamine, norepinephrine, serotonin, and histamine) and cholinergic systems with major effects on vigilance states (Taheri et al. 2002; Willie et al. 2001). It is therefore likely that a deficiency in hypocretin neurotransmission induces an imbalance between these classical neurotransmitter systems, with primary effects on sleep-state organization and vigilance. Indeed, dopamine and/or nor-epinephrine contents have been reported to be high in several brain structures in narcoleptic Dobermans and in human narcolepsy postmortem brains (Nishino and Mignot 1997). These changes in humans are possibly due to compensatory mechanisms, because drugs that enhance dopaminergic neurotransmission (such as amphetamine-like stimulants and modafinil for EDS) and norepinephrine neurotransmission (such as noradrenaline uptake blockers for cataplexy) are commonly used (Nishino and Mignot 1997).

Histamine is another monoamine implicated in the control of vigilance, and the histaminergic system is also likely to indirectly mediate the wake-promoting effects of hypocretin (Eriksson et al. 2001; Huang et al. 2001; Yamanaka et al. 2002). Interestingly, brain histamine contents both in hcrtr-2 gene—mutated and in ligand-deficient narcoleptic dogs are dramatically reduced (Nishino et al. 2001a). The involvement of the histaminergic system in the pathophysiology of narcolepsy and therapeutic applications of histaminergic compounds (Tedford et al. 1999) should be further studied.

Studies of animal hypocretin system function suggest that basic hypocretin neurotransmission fluctuates across the 24-hour period and slowly builds up during the active period (Fujiki et al. 2001; Yoshida et al. 2001; Zeitzer et al. 2003). Adrenergic LC neurons are typical wake-active neurons involved in vigilance control, and it has been recently demonstrated that basic firing activity of wake-active LC neurons also significantly fluctuates across various circadian times (Aston-Jones et al. 2001). Several acute manipulations, such as exercise, low glucose utilization in the brain, and forced wakefulness, increase hypocretin levels (Willie et al. 2001; Wu et al. 2002; Yoshida et al. 2001). It is therefore hypothesized that a buildup or acute increase of hypocretin levels may counteract the homeostatic sleep propensity that typically increases during the daytime and during forced wakefulness (Yoshida et al. 2001; Zeitzer et al. 2003). Because of the lack of increase in hypocretin tone, narcoleptic subjects may not be able to stay awake for a prolonged period and do not respond to various alerting stimuli. Conversely, the reduction of the hypocretin tone at sleep onset may contribute to the profound deep sleep that normally inhibits REM sleep at sleep onset, and the lack of this system in narcolepsy may allow the occurrence of REM sleep at sleep onset.

Excessive daytime sleepiness is a prevalent problem in medical practice and in society in general. It exacts a great cost in terms of quality of life, personal and public safety, and productivity. The causes of EDS are myriad, and a careful evaluation is needed to determine the cause in an individual case. Although much progress has been made in discovering the pathophysiology of narcolepsy, much more remains to be understood, and far less is known about other primary conditions of EDS. Several methods have been developed to assess EDS, although each of them has limitations. Treatment is available for the great majority of individuals with excessive daytime sleepiness.