Hypnotics and driving: FDA action, clinical trials show need for precautions

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Hypnotics and driving: FDA action, clinical trials show need for precautions

“Sleep driving” blamed on the hypnotic zolpidem was used as a defense last year in Virginia in a criminal case involving impaired driving. The defendant’s attorney argued that the defendant should not be held criminally liable because he was “essentially unconscious” and the accident therefore was involuntary.

The “sleep driving” defense failed when testimony revealed the defendant had taken 5 times the recommended zolpidem dose before the accident. The judge found him guilty of a felony charge of driving under the influence of a sleep medication.1

Sedative-hypnotics are increasingly being used to treat insomnia2-4 and as a result some patients try to drive while under the drugs’ sedating effects. Also, new FDA-ordered labeling for all 13 available prescription sleep aids warns of potential risks of “complex sleep-related behaviors,” including driving, phoning, and eating while asleep (Box 1).

Hypnotics can improve quality of life and well-being by addressing insomnia’s complications—hypertension, diabetes, coronary artery disease, depression, and anxiety5-7—but they also have been associated with impaired motor coordination and somnambulism. To help you and your patients weigh sleep medications’ relative risks and benefits, we report on clinical studies and court cases in the literature. Most of the data focus on zolpidem, by far the most prescribed hypnotic (Box 2).8,9

Box 1

New labeling for hypnotics: Sleep-related behaviors

Labeling of all sedative-hypnotic drugs now carries FDA-ordered precautions about “sleep-driving and other complex behaviors” that may occur without the patient being fully awake. FDA cited reports of patients preparing and eating food, making phone calls, and having sex after taking a sedative-hypnotic, usually without memory of the event. A warning also was added about rare, potentially fatal anaphylactic reactions in patients taking first or later doses of sleep medications.

Steven Galson, MD, MPH, director of FDA’s Center for Drug Evaluation and Research, said the labeling changes were needed to inform patients and prescribers about the risks of sleep aids that “are well-tolerated and effective for many people.”

Source: Walsh S, Rawlings K. FDA requests label change for all sleep disorder drug products. Available at www.fda.gov/bbs/topics/NEWS/2007/NEW01587.html.

Zolpidem incidents and cases

In 2005, Americans filled 43 million prescriptions for sedative-hypnotics—26.5 million for zolpidem alone—compared with 29 million prescriptions in 2001.4 In addition to the new the FDA-requested warnings about sleep-related behaviors, zolpidem’s labeling cautions patients about operating heavy machinery, driving, or engaging in hazardous occupations after taking the drug. The manufacturer tells patients:

  • to ingest zolpidem only before going to bed
  • that they may experience residual sedation the following day.
Not all patients heed the precautions or follow dosing recommendations, however.

Impaired driving. Besides the “sleep driving” case in Virginia, a highly publicized zolpidem-related driving incident occurred May 4, 2006, when U.S. Representative Patrick Kennedy was involved in an accident after having taken zolpidem in combination with an antinausea medication. Another driving-related case has used zolpidem as a defense for impairment, but the court decided that the medication was not at fault because the defendant also had ingested alcohol.10

Other litigation. Although zolpidem-related impairment apparently has not been used successfully as a defense for a driving incident, class action suits alleging failure to disclose potentially harmful side effects have been filed against the manufacturer.

In Janet Makinen and others v. sanofi-aventis,11 at least 500 plaintiffs claim zolpidem is related to sleep-driving, sleep-eating, and other somnambulistic behaviors. Plaintiffs allege negligence, breach of implied warranties, fraud, unfair trade practices, express warranty violations, strict liability, and consumer fraud violations. Other suits claim dangerous sleep-related side effects with zolpidem use.12

What clinical evidence shows

Driving impairment. Clinical studies have shown conflicting results about driving impairment associated with zolpidem. The literature falls into 2 categories, based on treatment duration:

  • Zolpidem affects performance and memory within the first 4 to 5 hours of administration (Table 1).
  • Beyond 5 hours, no residual effects on performance have been identified (Table 2), and repeat nightly dosing has not caused impairment or tolerance.
Verster et al13 examined residual effects of benzodiazepines and the nonbenzodiazepines zolpidem, zopiclone (available in the United States as eszopiclone), and zaleplon on driving ability, as reported in studies of on-the-road driving, driving simulators, epidemiologic data, and closed-road driving. This review found that:

  • All sedative hypnotic benzodiazepines had statistically significant residual effects 10 to 11 hours after ingestion, with longer periods of impairment corresponding to medications with longer half-lives.
  • Zopiclone was associated with significant residual impairment for up to 10 hours after ingestion.
  • Zolpidem and zaleplon showed no significant impairment in driving 10 to 11 hours after ingestion. Impairment was found, however, when zolpidem was taken within 5 hours of driving.14-18
 

 

Table 1

Studies of zolpidem-associated driving skills impairment
(

Author/designDoses and timingDriving skills assessmentsConclusions
Wilkinson, 199514 Blinded; 29 subjectsZolpidem, 10 mg, 15 mg, and placebo in combination with an alcoholic drink (to reach a BAC of 0.08%) or placebo drink; testing 45 min, 130 min, and 230 min after administrationVisual backward masking test (approximates driving performance) and attention testsZolpidem produced significant impairment in combination with alcohol and when administered alone during peak effect assessment; alcohol did not potentiate zolpidem’s effects; additive effects of alcohol seen with 10-mg dose but not 15-mg dose of zolpidem
Rush et al, 199815 Double-blind, crossover; 9 subjectsZolpidem, 7.5, 15, and 22.5 mg; quazepam, 15, 30, and 45 mg; triazolam, 0.1875, 0.375, and 0.5625 mg; testing ½, 1, 1½, 2, 2½, 3, 4, 5, and 6 hours after administrationSubject- and observer-rated questionnaires; tests of recall and delayed recognitionPerformance-impairing effects of zolpidem were virtually indistinguishable from those of classic benzodiazepines, such as triazolam
Mattila et al, 199816 Randomized, placebo-controlled, double-blind, crossover; 12 subjectsZolpidem, 15 mg; diazepam, 15 mg; oxazepam, 30 mg; zopiclone, 7.5 mg; alcohol testing before and 1, 3½, and 5 hours after administrationSimulated driving and other measuresZolpidem impaired coordination, reaction, and cognition at 1 and 3½ hours; tracking remained impaired at 5 hours; all agents (especially zolpidem) impaired learning and memory
Mintzer et al, 199917 Double-blind, placebo-controlled; 16 subjectsZolpidem, 15 mg/70 kg (dosed by subject weight); testing ½, 1, 2, and 3 hours after administrationMemory tasks (recall, fragment completion, recognition)Zolpidem interfered with explicit but not implicit memory after administration; zolpidem produced a specific deficit in acquisition of contextual information
Verster et al, 200418 2-step randomized, placebo-controlled, double-blind, crossover; 30 subjectsZolpidem, 10 mg and 20 mg; zaleplon, 10 mg and 20 mg; middle-of-the-night dosing; testing 4 hours after dosingOn-the-road driving and other tests of attention, learning, and thinkingZolpidem, 10 mg and 20 mg, significantly impaired driving function; zolpidem, 20 mg, produced significant impairment on all psychomotor and memory tests; zaleplon, 10 mg and 20 mg, did not differ significantly from placebo
BAC: Blood alcohol concentration
Table 2

Studies of zolpidem-associated driving skills impairment
(>5 hours after dosing)

Author/designDoses and timingDriving skills assessmentsConclusions
Fairweather et al, 199223 Randomized, placebo-controlled; 24 older volunteers taking no other medicationsZolpidem, 5 mg or 10 mg, or placebo taken before bedtime; testing 8.5 hours after administrationNumerous, including reactive time, memory, word recognitionZolpidem consistently helped with sleep latency, with no residual performance deficits; no tolerance seen with repeated dosing
Bocca et al, 199924 Double-blind, crossover; 16 volunteersZolpidem, 10 mg; zopiclone, 7.5 mg; flunitrazepam,* 1 mg; and placebo given at 11 PM, with testing at 9 AMDriving simulation and real time test drive; eye movements measured after driving testsNo residual effects with zolpidem; zopiclone impaired driving ability and increased saccadic latency; flunitrazepam impaired early morning driving and saccadic eye movements longer than zopiclone
Partinen et al, 200320 Randomized, placebo-controlled, double-blind, 3-period crossover; 18 women with insomniaZolpidem, 10 mg; temazepam, 20 mg; dosing at 2 AM, testing 5.5 hours after dosingDriving simulation; delayed word recall and memory testing (FePsy test)No statistically significant effects on driving ability with either drug; no significant differences in FePsy results compared with baseline or placebo
Staner et al, 200525 Randomized, placebo-controlled, double-blind, four-way crossover; 23 subjects with DSM-IV-TR diagnosis of insomniaZolpidem, 10 mg; zopiclone, 7.5 mg; lormetazepam,* 1 mg; 7 days of dosing; tests given 9 to 11 hours post-dosingDriving simulation; EEG at rest and while drivingZolpidem showed no impairment of driving ability and no EEG changes compared with placebo; driving impairment and EEG alterations were found with zopiclone and lormetazepam
* Hypnotics not approved in the United States but available elsewhere.

Acute effects (

Combined with alcohol. Wilkinson14 conducted a randomized, 6-way crossover study in which subjects received 10- or 15-mg doses of zolpidem or placebo plus an alcoholic beverage (enough to obtain a blood alcohol concentration [BAC] of ~0.08%) or placebo beverage. Tests given shortly after patients took the study medications showed that zolpidem caused statistically significant impairment both in combination with alcohol and alone during peak drug effect—identified as 45 minutes after ingestion. Alcohol did not potentiate the impairment associated with zolpidem.

Using a similar design, Mattila et al16 compared acute performance impairment associated with zolpidem, diazepam, oxazepam, and zopiclone. In this randomized, double-blinded, crossover study, all comparison medications impaired antecedent learning and memory, but zolpidem given at 15 mg had the greatest effect. Zolpidem impaired coordination, reactive functioning, and cognitive skills at 1 and 3.5 hours after administration, and simulated driving test performance remained impaired at 5 hours (approximately two half-lives of the medication). Of note is that the 15-mg zolpidem dose used in this study was shown by Wilkinson et al14 to be more impairing than the recommended maximum 10-mg dose.

 

 

A study from the University of Toronto19 that did not include zolpidem examined potential psychomotor performance deficits and sleepiness in a comparison of time-released melatonin, 6 mg; zaleplon, 10 mg; zopiclone, 7.5 mg; temazepam, 15 mg, and placebo. Tests were given to 9 men and 14 women, ages 21 to 53, just before drug administration and 7 hours later.

Zaleplon had the greatest effect on psychomotor performance, followed by temazepam and zopiclone. Aside from prolonged perceived sleepiness, melatonin and placebo did not interfere with performance testing.

Box 2

Zolpidem: Approved for ‘short-term’ insomnia

Zolpidem, a benzodiazepine receptor agonist, was the 7th most prescribed drug in the United States in 2005 (2006 data not available).8 It is FDA-approved for short-term treatment of insomnia, although “short-term” is not defined. Package labeling states:

This nonbenzodiazepine hypnotic has been shown to decrease sleep latency and increase sleep duration for up to 35 days in controlled clinical trials. Patients should be evaluated for a primary psychiatric or medical illness if insomnia does not remit after 7 to 10 days of treatment.

An imidazopyridine that acts as an agonist of GABA A1, zolpidem produces sedation while avoiding anticonvulsant, anxiolytic, and muscle relaxation effects. Available in 5- and 10-mg tablets, the drug is rapidly absorbed in the GI tract and excreted primarily through the kidneys. Its half-life is approximately 2.5 hours (approximately 3 hours in elderly patients). The most common side effects are daytime drowsiness, dizziness, and diarrhea; others include asthenia, hiccup, and diplopia.9

Middle-of-the-night dosing. Effects of zolpidem and zaleplon on driving ability, memory, and psychomotor performance were compared by Verster et al18 in a randomized, controlled trial. The double-blind, 5-period crossover design measured the effects of middle-of-the-night use of zaleplon, 10 or 20 mg; zolpidem, 10 or 20 mg; or placebo on:

  • driving ability 4 hours after administration
  • memory and psychomotor performance 6 hours after administration.
As expected, subjects taking zolpidem showed impairment on all measures. The 10- and 20-mg doses significantly impaired driving 4 hours after ingestion, with the 20-mg dose—twice the recommended maximum dose—producing greater impairment. The 20-mg dose—but not the 10-mg dose—also significantly impaired memory and psychomotor function. Zaleplon did not impair driving ability, memory, or psychomotor testing.

Partinen et al20 used the recommended zolpidem dose in a similar study of after-midnight use by women with insomnia. The double-blind, randomized, controlled trial evaluated performance with a driving simulator and neuropsychological testing 5.5 hours after medication dosing. Patients taking zolpidem, 10 mg, showed no significant impairment when compared with those taking placebo. Some patients scored poorly on the driving tests alone, and the authors concluded that this group was more susceptible to zolpidem’s effect.

Memory. In a double-blind, placebo-controlled trial by Mintzner et al,17 zolpidem dosed by patient weight at 15 mg/70 kg:

  • significantly impaired explicit memory (requires conscious recollection for recall)
  • did not affect implicit memory (lack of conscious awareness in the act of recollection).
Explicit memory for material presented before drug administration and previously acquired knowledge was not affected. Zolpidem spared explicit and implicit memory for material presented before administration, but subjects had difficulty acquiring contextual information after the dose was given.

These findings support complaints of zolpidem-related anterograde amnestic episodes, which also occur with some benzodiazepines (such as midazolam).

Similar to benzodiazepines? Rush et al’s results21 support Mintzer’s assertion17 that zolpidem shares many side effects with benzodiazepines. Performance impairment associated with zolpidem—as rated by subjects and observers—is virtually indistinguishable from a benzodiazepine effect, except that the duration is shorter with zolpidem (5 hours), compared with up to 10 hours for benzodiazepines.

Logan and Couper22 reviewed police reports and toxicology profiles of individuals suspected of driving while impaired. Zolpidem was found in 29 subjects, 5 of whom showed no other substances. In those 5, zolpidem blood levels ranged from 0.08 to 1.40 mg/L and did not appear to correlate with the degree of impairment.

Residual effects (>5 hours)

Older patients. In a randomized, placebo-controlled trial by Fairweather et al,23 zolpidem improved sleep latency in 24 subjects ages 63 to 80. No evidence of impairment in reactive time, memory, or word recognition was found 8.5 hours after nighttime dosing, and tolerance was not seen after 1 week of repeated dosing.

 

 

Driving impairment. Bocca et al24 compared degree of driving impairment by zolpidem, zopiclone, flunitrazepam (not approved in the United States), and placebo. The 16 subjects received each medication at 11 pm, with a 2-week washout between medications. One group of 8 was tested at 9 am and the other 8 subjects at 11 am. Those taking zolpidem showed no residual performance impairment, as measured by simulated driving, a test drive, and saccadic eye movements.

Staner et al25 reported similar results when comparing zolpidem, zopiclone, lormetazepam (not approved in the United States), and placebo. Using a driving simulator and electroencephalography (EEG), they evaluated 23 subjects diagnosed with insomnia at 9 and 11 hours post-dose. Zolpidem did not significantly impair driving ability and did not differ from placebo on EEG analysis (resting or driving). The study showed driving impairment with zopiclone and lormetazepam, along with characteristic benzodiazepine EEG changes. This study further supports evidence of limited impairment on driving after appropriate use of zolpidem.

Informed consent

In the informed consent process, failing to warn a patient about medication side effects can lead to legal claims against both manufacturers and prescribers. With any medication, patients have the right to know about a drug’s risks, benefits, and alternate therapies—including no therapy.

Two standards are associated with informed consent and negligence:

  • The “reasonable practitioner” standard outlined in Natanson v. Kline (1960)26 mandates that the prescribing physician has revealed all that an “average, reasonable practitioner” would disclose in similar circumstances.
  • The “reasonable patient” standard set in Canterbury v. Spence (1972)27 mandates that the prescribing physician has informed the patient about the proposed treatment, its side effects, and alternatives to the proposed treatment that a reasonable patient would consider material to the decision of whether or not to undergo treatment.
Failure to warn. Plaintiffs may allege a failure to warn if a drug manufacturer withheld information, thus not adequately warning the dispensing provider. In Reyes v. Wyeth Laboratories, for example, the U.S. Fifth Circuit Court of Appeals ruled that the polio vaccine’s manufacturer failed to warn the parents of a child who contracted polio from the vaccine about the 1-in-a-million chance of this adverse effect.28

The vaccine was licensed as a prescription drug but administered through county health departments. In 1970, a nurse in a Texas Department of Health clinic administered the vaccine to 8-month-old Anita Reyes without telling the girl’s parents of warnings in the package circular. Holding Wyeth Laboratories to a reasonableness standard, the court found that the company knew or should have known how the vaccine would be distributed.

The package insert was not shown to have given inadequate warning, and the vaccine was not shown to be defective (it was a trivalent live-virus Sabin oral polio vaccine, as intended).

Vioxx cases. Similarly, some plaintiffs have been awarded millions of dollars (as in Ernst v. Merck & Co., Inc.29) in rulings that Merck & Co. failed to disclose the risk of cardiotoxicity with the arthritis drug rofecoxib (Vioxx) and thus failed to provide physicians with information needed when prescribing the drug. In Humeston v. Merck & Co.,30 a Texas court in 2005 held that Vioxx’s warning labels were adequate. In a retrial, however, the New Jersey Superior Court awarded the plaintiff $47.5 million.31

As with the polio vaccine and Vioxx litigations, courts are being asked to decide if patients were adequately informed about sleep-driving and other risks associated with the use of sedative-hypnotics.

Clinical recommendations

Zolpidem—like many other medications—carries a substantial risk of side effects, even when used appropriately. However, given the medical and mental health risks of untreated insomnia, the benefits of a medication such as zolpidem will likely outweigh its risks.

Numerous studies have shown that zolpidem is effective for improving sleep latency and that there are mild, if any, residual side effects beyond what would normally be a restful night’s sleep. Impairments are evident, however, during the hours following the drug’s administration, with some effects lasting >5 hours depending on the dose.

Risk management. When prescribing nonbenzodiazepine hypnotics such as zolpidem, you may want to adopt a risk management approach as you would with other medications that can have serious side effects. An approach to benzodiazepine prescribing proposed by Bursztajn et al31 advocates:

  • using the informed-consent process to build an alliance with patients
  • not prescribing the medication in isolation of other beneficial therapies
  • being aware of and always documenting your decision-making process.
 

 

When you make patients aware of all risks, benefits, alternate therapies, and possible outcomes with no treatment, you have informed them effectively. Patients are then left to decide whether or not to agree to the treatment. You also are responsible for monitoring the patient, addressing the patient’s questions, and relaying important safety information.

When prescribing zolpidem, discuss safety information with the patient, such as:

  • Do not drive or operate heavy equipment for at least 5 to 6 hours after administration.
  • Have a safety plan in place for transportation during those hours.
  • Do not use this medication with alcohol or other sedative/hypnotics.
  • Contact the prescriber about any suspected adverse effects.
Related resources

Drug brand names

  • Diazepam • Valium
  • Eszopiclone • Lunesta
  • Midazolam • Versed
  • Oxazepam • Serax
  • Quazepam • Doral
  • Rofecoxib • Vioxx
  • Temazepam • Restoril
  • Triazolam • Halcion
  • Zolpidem • Ambien, Ambien CR
  • Zaleplon • Sonata
  • Zopiclone • Imovane (in Europe)
Disclosure

The authors report no financial relationships with any company whose products are mentioned in this article or with manufacturers of competing products.

Acknowledgments

The authors acknowledge the assistance and guidance of Linda T. Moore, JD, in preparing this manuscript.

References

1. Markon J. Sleeping Va. driver convicted in crash; man had taken too much Ambien. The Washington Post, August 2, 2006. Accessed August 26, 2006 from LexisNexis Academic Database.

2. Colten HR, Altevogt BM. Sleep disorders and sleep deprivation: an unmet public health problem. Available at: http://www.iom.edu/CMS/3740/23160/33668.aspx. Accessed February 21, 2007.

3. Mellinger GD, Balter MB, Uhlenhuth EH. Insomnia and its treatment; prevalence and correlates. Arch Gen Psychiatry 1985;42:225-32.

4. Barclay L. Driving, other erratic behaviors reported after taking zolpidem. Available at http://www.medscape.com/viewarticle/528415. Accessed February 21, 2007.

5. Gottlieb DJ, Redline S, Nieto FJ, et al. Association of usual sleep duration with hypertension: the Sleep Heart Health Study. Sleep 2006;29(8):1009-14.

6. Gottlieb DJ, Punjabi NM, Newman AB, et al. Association of sleep time with diabetes mellitus and impaired glucose tolerance. Arch Intern Med 2005;165(8):863-7.

7. Perlis ML, Smith LJ, Lyness JM, et al. Insomnia as a risk factor for onset of depression in the elderly. Behav Sleep Med 2006;4(2):104-13.

8. Verispan VONA. Top 200 brand name drugs by units in 2005. Drug Topics 2006. Available at: http://www.drugtopics.com/drugtopics/data/articlestandard/drugtopics/102006/311294/article.pdf. Accessed February 22, 2007.

9. sanofi-aventis Ambien prescribing information. Available at: http://products.sanofi-aventis.us/ambien/ambien.html. Accessed February 21, 2007.

10. Pear R. Patrick Kennedy crashes car into a Capitol Hill barrier. The New York Times, May 5, 2006. Accessed September 25, 2006 from LexisNexis Academic Database.

11. Janet Makinen and others v. Sanofi-Synthelabo & Sanofi-Synthelabo, Inc. Class action suit filed March 6, 2006 in U.S. District Court for the Southern District of New York, NY.

12. Tooher NL. Ambien users are filing lawsuits. Kansas City Daily Record, April 12, 2006. Accessed September 25, 2006 from LexisNexis Academic Database.

13. Verster JC, Veldhuijzen DS, Volkerts ER. Residual effects of sleep medication on driving ability. Sleep Med Rev 2004;8(4):309-25.

14. Wilkinson CJ. The acute effects of zolpidem, administered alone and with alcohol, on cognitive and psychomotor function. J Clin Psychiatry 1995;56(7):309-18.

15. Rush CR, Armstrong DL, Ali JA, Pazzaglia PJ. Benzodiazepine-receptor ligands in humans: acute performance-impairing, subject-rated and observer-rated effects. J Clin Psychopharmacol 1998;18(2):154-65.

16. Mattila MJ, Vanakoski J, Kalska H, Seppala T. Effects of alcohol, zolpidem, and some other sedatives and hypnotics on human performance and memory. Pharmacol Biochem Behav 1998;59(4):917-23.

17. Mintzer MZ, Griffiths RR. Selective effects of zolpidem on human memory functions. J Psychopharmacol 1999;13(1):18-31.

18. Verster JC, Volkerts ER, Schreuder AH, et al. Residual effects of middle-of-the-night administration of zaleplon and zolpidem on driving ability, memory functions, and psychomotor performance. J Clin Psychopharmacol 2002;22(6):576-83.

19. Paul MA, Gray G, Kenny G, Pigeau RA. Impact of melatonin, zaleplon, zopiclone, and temazepam on psychomotor performance. Aviat Space Environ Med 2003;74(12):1263-70.

20. Partinen M, Hirvonen K, Hublin C, et al. Effects of after-midnight intake of zolpidem and temazepam on driving ability in women with non-organic insomnia. Sleep Med 2003;4(6):553-61.

21. Rush CR, Armstrong DL, Ali JA, Pazzaglia PJ. Benzodiazepine-receptor ligands in humans: acute performance-impairing, subject-rated and observer-rated effects. J Clin Psychopharmacol 1998;18(2):154-65.

22. Logan BK, Couper FJ. Zolpidem and driving impairment. J Forensic Sci 2001;46(1):105-10.

23. Fairweather DB, Kerr JS, Hindmarch I. The effects of acute and repeated doses of zolpidem on subjective sleep, psychomotor performance and cognitive function in elderly volunteers. Eur J Clin Pharmacol 1992;43(6):597-601.

24. Bocca ML, Le Doze F, Etard O, et al. Residual effect of zolpidem 10 mg and zopiclone 7.5 mg versus flunitrazepam 1 mg and placebo on driving performance and ocular saccades. Psychopharmacology (Berl) 1999;143(4):373-9.

25. Staner L, Ertle S, Boeijinga P, et al. Next-day residual effects of hypnotics in DSM-IV primary insomnia: a driving simulator study with simultaneous electroencephalogram monitoring. Psychopharmacology (Berl) 2005;181(4):790-8.

26. Natanson v. Kline 300 P.2d 1093 (1960).

27. Canterbury v. Spence 464 F.2d 772 (1972).

28. Reyes v. Wyeth Laboratories. 498 F.2d 1264 (1974).

29. Ernst v. Merck & Co. 24 PLLR 149 (2005).

30. Humeston v. Merck & Co., No. ATL-L-2272-03-MT, Super. Ct., Atlantic County, NJ, November 3, 2005.

31. Johnson LA. Jury blames Vioxx for man’s heart attack, awards $47.5 million. Available at http://news.findlaw.com/ap/o/51/03-12-2007/85f9000f67cd576a.html. Accessed March 16, 2007.

32. Bursztajn HJ, Brodsky A. Ethical and legal dimensions of benzodiazepine prescription: a commentary. Psychiatr Ann 1998;28(3):121-7.

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“Sleep driving” blamed on the hypnotic zolpidem was used as a defense last year in Virginia in a criminal case involving impaired driving. The defendant’s attorney argued that the defendant should not be held criminally liable because he was “essentially unconscious” and the accident therefore was involuntary.

The “sleep driving” defense failed when testimony revealed the defendant had taken 5 times the recommended zolpidem dose before the accident. The judge found him guilty of a felony charge of driving under the influence of a sleep medication.1

Sedative-hypnotics are increasingly being used to treat insomnia2-4 and as a result some patients try to drive while under the drugs’ sedating effects. Also, new FDA-ordered labeling for all 13 available prescription sleep aids warns of potential risks of “complex sleep-related behaviors,” including driving, phoning, and eating while asleep (Box 1).

Hypnotics can improve quality of life and well-being by addressing insomnia’s complications—hypertension, diabetes, coronary artery disease, depression, and anxiety5-7—but they also have been associated with impaired motor coordination and somnambulism. To help you and your patients weigh sleep medications’ relative risks and benefits, we report on clinical studies and court cases in the literature. Most of the data focus on zolpidem, by far the most prescribed hypnotic (Box 2).8,9

Box 1

New labeling for hypnotics: Sleep-related behaviors

Labeling of all sedative-hypnotic drugs now carries FDA-ordered precautions about “sleep-driving and other complex behaviors” that may occur without the patient being fully awake. FDA cited reports of patients preparing and eating food, making phone calls, and having sex after taking a sedative-hypnotic, usually without memory of the event. A warning also was added about rare, potentially fatal anaphylactic reactions in patients taking first or later doses of sleep medications.

Steven Galson, MD, MPH, director of FDA’s Center for Drug Evaluation and Research, said the labeling changes were needed to inform patients and prescribers about the risks of sleep aids that “are well-tolerated and effective for many people.”

Source: Walsh S, Rawlings K. FDA requests label change for all sleep disorder drug products. Available at www.fda.gov/bbs/topics/NEWS/2007/NEW01587.html.

Zolpidem incidents and cases

In 2005, Americans filled 43 million prescriptions for sedative-hypnotics—26.5 million for zolpidem alone—compared with 29 million prescriptions in 2001.4 In addition to the new the FDA-requested warnings about sleep-related behaviors, zolpidem’s labeling cautions patients about operating heavy machinery, driving, or engaging in hazardous occupations after taking the drug. The manufacturer tells patients:

  • to ingest zolpidem only before going to bed
  • that they may experience residual sedation the following day.
Not all patients heed the precautions or follow dosing recommendations, however.

Impaired driving. Besides the “sleep driving” case in Virginia, a highly publicized zolpidem-related driving incident occurred May 4, 2006, when U.S. Representative Patrick Kennedy was involved in an accident after having taken zolpidem in combination with an antinausea medication. Another driving-related case has used zolpidem as a defense for impairment, but the court decided that the medication was not at fault because the defendant also had ingested alcohol.10

Other litigation. Although zolpidem-related impairment apparently has not been used successfully as a defense for a driving incident, class action suits alleging failure to disclose potentially harmful side effects have been filed against the manufacturer.

In Janet Makinen and others v. sanofi-aventis,11 at least 500 plaintiffs claim zolpidem is related to sleep-driving, sleep-eating, and other somnambulistic behaviors. Plaintiffs allege negligence, breach of implied warranties, fraud, unfair trade practices, express warranty violations, strict liability, and consumer fraud violations. Other suits claim dangerous sleep-related side effects with zolpidem use.12

What clinical evidence shows

Driving impairment. Clinical studies have shown conflicting results about driving impairment associated with zolpidem. The literature falls into 2 categories, based on treatment duration:

  • Zolpidem affects performance and memory within the first 4 to 5 hours of administration (Table 1).
  • Beyond 5 hours, no residual effects on performance have been identified (Table 2), and repeat nightly dosing has not caused impairment or tolerance.
Verster et al13 examined residual effects of benzodiazepines and the nonbenzodiazepines zolpidem, zopiclone (available in the United States as eszopiclone), and zaleplon on driving ability, as reported in studies of on-the-road driving, driving simulators, epidemiologic data, and closed-road driving. This review found that:

  • All sedative hypnotic benzodiazepines had statistically significant residual effects 10 to 11 hours after ingestion, with longer periods of impairment corresponding to medications with longer half-lives.
  • Zopiclone was associated with significant residual impairment for up to 10 hours after ingestion.
  • Zolpidem and zaleplon showed no significant impairment in driving 10 to 11 hours after ingestion. Impairment was found, however, when zolpidem was taken within 5 hours of driving.14-18
 

 

Table 1

Studies of zolpidem-associated driving skills impairment
(

Author/designDoses and timingDriving skills assessmentsConclusions
Wilkinson, 199514 Blinded; 29 subjectsZolpidem, 10 mg, 15 mg, and placebo in combination with an alcoholic drink (to reach a BAC of 0.08%) or placebo drink; testing 45 min, 130 min, and 230 min after administrationVisual backward masking test (approximates driving performance) and attention testsZolpidem produced significant impairment in combination with alcohol and when administered alone during peak effect assessment; alcohol did not potentiate zolpidem’s effects; additive effects of alcohol seen with 10-mg dose but not 15-mg dose of zolpidem
Rush et al, 199815 Double-blind, crossover; 9 subjectsZolpidem, 7.5, 15, and 22.5 mg; quazepam, 15, 30, and 45 mg; triazolam, 0.1875, 0.375, and 0.5625 mg; testing ½, 1, 1½, 2, 2½, 3, 4, 5, and 6 hours after administrationSubject- and observer-rated questionnaires; tests of recall and delayed recognitionPerformance-impairing effects of zolpidem were virtually indistinguishable from those of classic benzodiazepines, such as triazolam
Mattila et al, 199816 Randomized, placebo-controlled, double-blind, crossover; 12 subjectsZolpidem, 15 mg; diazepam, 15 mg; oxazepam, 30 mg; zopiclone, 7.5 mg; alcohol testing before and 1, 3½, and 5 hours after administrationSimulated driving and other measuresZolpidem impaired coordination, reaction, and cognition at 1 and 3½ hours; tracking remained impaired at 5 hours; all agents (especially zolpidem) impaired learning and memory
Mintzer et al, 199917 Double-blind, placebo-controlled; 16 subjectsZolpidem, 15 mg/70 kg (dosed by subject weight); testing ½, 1, 2, and 3 hours after administrationMemory tasks (recall, fragment completion, recognition)Zolpidem interfered with explicit but not implicit memory after administration; zolpidem produced a specific deficit in acquisition of contextual information
Verster et al, 200418 2-step randomized, placebo-controlled, double-blind, crossover; 30 subjectsZolpidem, 10 mg and 20 mg; zaleplon, 10 mg and 20 mg; middle-of-the-night dosing; testing 4 hours after dosingOn-the-road driving and other tests of attention, learning, and thinkingZolpidem, 10 mg and 20 mg, significantly impaired driving function; zolpidem, 20 mg, produced significant impairment on all psychomotor and memory tests; zaleplon, 10 mg and 20 mg, did not differ significantly from placebo
BAC: Blood alcohol concentration
Table 2

Studies of zolpidem-associated driving skills impairment
(>5 hours after dosing)

Author/designDoses and timingDriving skills assessmentsConclusions
Fairweather et al, 199223 Randomized, placebo-controlled; 24 older volunteers taking no other medicationsZolpidem, 5 mg or 10 mg, or placebo taken before bedtime; testing 8.5 hours after administrationNumerous, including reactive time, memory, word recognitionZolpidem consistently helped with sleep latency, with no residual performance deficits; no tolerance seen with repeated dosing
Bocca et al, 199924 Double-blind, crossover; 16 volunteersZolpidem, 10 mg; zopiclone, 7.5 mg; flunitrazepam,* 1 mg; and placebo given at 11 PM, with testing at 9 AMDriving simulation and real time test drive; eye movements measured after driving testsNo residual effects with zolpidem; zopiclone impaired driving ability and increased saccadic latency; flunitrazepam impaired early morning driving and saccadic eye movements longer than zopiclone
Partinen et al, 200320 Randomized, placebo-controlled, double-blind, 3-period crossover; 18 women with insomniaZolpidem, 10 mg; temazepam, 20 mg; dosing at 2 AM, testing 5.5 hours after dosingDriving simulation; delayed word recall and memory testing (FePsy test)No statistically significant effects on driving ability with either drug; no significant differences in FePsy results compared with baseline or placebo
Staner et al, 200525 Randomized, placebo-controlled, double-blind, four-way crossover; 23 subjects with DSM-IV-TR diagnosis of insomniaZolpidem, 10 mg; zopiclone, 7.5 mg; lormetazepam,* 1 mg; 7 days of dosing; tests given 9 to 11 hours post-dosingDriving simulation; EEG at rest and while drivingZolpidem showed no impairment of driving ability and no EEG changes compared with placebo; driving impairment and EEG alterations were found with zopiclone and lormetazepam
* Hypnotics not approved in the United States but available elsewhere.

Acute effects (

Combined with alcohol. Wilkinson14 conducted a randomized, 6-way crossover study in which subjects received 10- or 15-mg doses of zolpidem or placebo plus an alcoholic beverage (enough to obtain a blood alcohol concentration [BAC] of ~0.08%) or placebo beverage. Tests given shortly after patients took the study medications showed that zolpidem caused statistically significant impairment both in combination with alcohol and alone during peak drug effect—identified as 45 minutes after ingestion. Alcohol did not potentiate the impairment associated with zolpidem.

Using a similar design, Mattila et al16 compared acute performance impairment associated with zolpidem, diazepam, oxazepam, and zopiclone. In this randomized, double-blinded, crossover study, all comparison medications impaired antecedent learning and memory, but zolpidem given at 15 mg had the greatest effect. Zolpidem impaired coordination, reactive functioning, and cognitive skills at 1 and 3.5 hours after administration, and simulated driving test performance remained impaired at 5 hours (approximately two half-lives of the medication). Of note is that the 15-mg zolpidem dose used in this study was shown by Wilkinson et al14 to be more impairing than the recommended maximum 10-mg dose.

 

 

A study from the University of Toronto19 that did not include zolpidem examined potential psychomotor performance deficits and sleepiness in a comparison of time-released melatonin, 6 mg; zaleplon, 10 mg; zopiclone, 7.5 mg; temazepam, 15 mg, and placebo. Tests were given to 9 men and 14 women, ages 21 to 53, just before drug administration and 7 hours later.

Zaleplon had the greatest effect on psychomotor performance, followed by temazepam and zopiclone. Aside from prolonged perceived sleepiness, melatonin and placebo did not interfere with performance testing.

Box 2

Zolpidem: Approved for ‘short-term’ insomnia

Zolpidem, a benzodiazepine receptor agonist, was the 7th most prescribed drug in the United States in 2005 (2006 data not available).8 It is FDA-approved for short-term treatment of insomnia, although “short-term” is not defined. Package labeling states:

This nonbenzodiazepine hypnotic has been shown to decrease sleep latency and increase sleep duration for up to 35 days in controlled clinical trials. Patients should be evaluated for a primary psychiatric or medical illness if insomnia does not remit after 7 to 10 days of treatment.

An imidazopyridine that acts as an agonist of GABA A1, zolpidem produces sedation while avoiding anticonvulsant, anxiolytic, and muscle relaxation effects. Available in 5- and 10-mg tablets, the drug is rapidly absorbed in the GI tract and excreted primarily through the kidneys. Its half-life is approximately 2.5 hours (approximately 3 hours in elderly patients). The most common side effects are daytime drowsiness, dizziness, and diarrhea; others include asthenia, hiccup, and diplopia.9

Middle-of-the-night dosing. Effects of zolpidem and zaleplon on driving ability, memory, and psychomotor performance were compared by Verster et al18 in a randomized, controlled trial. The double-blind, 5-period crossover design measured the effects of middle-of-the-night use of zaleplon, 10 or 20 mg; zolpidem, 10 or 20 mg; or placebo on:

  • driving ability 4 hours after administration
  • memory and psychomotor performance 6 hours after administration.
As expected, subjects taking zolpidem showed impairment on all measures. The 10- and 20-mg doses significantly impaired driving 4 hours after ingestion, with the 20-mg dose—twice the recommended maximum dose—producing greater impairment. The 20-mg dose—but not the 10-mg dose—also significantly impaired memory and psychomotor function. Zaleplon did not impair driving ability, memory, or psychomotor testing.

Partinen et al20 used the recommended zolpidem dose in a similar study of after-midnight use by women with insomnia. The double-blind, randomized, controlled trial evaluated performance with a driving simulator and neuropsychological testing 5.5 hours after medication dosing. Patients taking zolpidem, 10 mg, showed no significant impairment when compared with those taking placebo. Some patients scored poorly on the driving tests alone, and the authors concluded that this group was more susceptible to zolpidem’s effect.

Memory. In a double-blind, placebo-controlled trial by Mintzner et al,17 zolpidem dosed by patient weight at 15 mg/70 kg:

  • significantly impaired explicit memory (requires conscious recollection for recall)
  • did not affect implicit memory (lack of conscious awareness in the act of recollection).
Explicit memory for material presented before drug administration and previously acquired knowledge was not affected. Zolpidem spared explicit and implicit memory for material presented before administration, but subjects had difficulty acquiring contextual information after the dose was given.

These findings support complaints of zolpidem-related anterograde amnestic episodes, which also occur with some benzodiazepines (such as midazolam).

Similar to benzodiazepines? Rush et al’s results21 support Mintzer’s assertion17 that zolpidem shares many side effects with benzodiazepines. Performance impairment associated with zolpidem—as rated by subjects and observers—is virtually indistinguishable from a benzodiazepine effect, except that the duration is shorter with zolpidem (5 hours), compared with up to 10 hours for benzodiazepines.

Logan and Couper22 reviewed police reports and toxicology profiles of individuals suspected of driving while impaired. Zolpidem was found in 29 subjects, 5 of whom showed no other substances. In those 5, zolpidem blood levels ranged from 0.08 to 1.40 mg/L and did not appear to correlate with the degree of impairment.

Residual effects (>5 hours)

Older patients. In a randomized, placebo-controlled trial by Fairweather et al,23 zolpidem improved sleep latency in 24 subjects ages 63 to 80. No evidence of impairment in reactive time, memory, or word recognition was found 8.5 hours after nighttime dosing, and tolerance was not seen after 1 week of repeated dosing.

 

 

Driving impairment. Bocca et al24 compared degree of driving impairment by zolpidem, zopiclone, flunitrazepam (not approved in the United States), and placebo. The 16 subjects received each medication at 11 pm, with a 2-week washout between medications. One group of 8 was tested at 9 am and the other 8 subjects at 11 am. Those taking zolpidem showed no residual performance impairment, as measured by simulated driving, a test drive, and saccadic eye movements.

Staner et al25 reported similar results when comparing zolpidem, zopiclone, lormetazepam (not approved in the United States), and placebo. Using a driving simulator and electroencephalography (EEG), they evaluated 23 subjects diagnosed with insomnia at 9 and 11 hours post-dose. Zolpidem did not significantly impair driving ability and did not differ from placebo on EEG analysis (resting or driving). The study showed driving impairment with zopiclone and lormetazepam, along with characteristic benzodiazepine EEG changes. This study further supports evidence of limited impairment on driving after appropriate use of zolpidem.

Informed consent

In the informed consent process, failing to warn a patient about medication side effects can lead to legal claims against both manufacturers and prescribers. With any medication, patients have the right to know about a drug’s risks, benefits, and alternate therapies—including no therapy.

Two standards are associated with informed consent and negligence:

  • The “reasonable practitioner” standard outlined in Natanson v. Kline (1960)26 mandates that the prescribing physician has revealed all that an “average, reasonable practitioner” would disclose in similar circumstances.
  • The “reasonable patient” standard set in Canterbury v. Spence (1972)27 mandates that the prescribing physician has informed the patient about the proposed treatment, its side effects, and alternatives to the proposed treatment that a reasonable patient would consider material to the decision of whether or not to undergo treatment.
Failure to warn. Plaintiffs may allege a failure to warn if a drug manufacturer withheld information, thus not adequately warning the dispensing provider. In Reyes v. Wyeth Laboratories, for example, the U.S. Fifth Circuit Court of Appeals ruled that the polio vaccine’s manufacturer failed to warn the parents of a child who contracted polio from the vaccine about the 1-in-a-million chance of this adverse effect.28

The vaccine was licensed as a prescription drug but administered through county health departments. In 1970, a nurse in a Texas Department of Health clinic administered the vaccine to 8-month-old Anita Reyes without telling the girl’s parents of warnings in the package circular. Holding Wyeth Laboratories to a reasonableness standard, the court found that the company knew or should have known how the vaccine would be distributed.

The package insert was not shown to have given inadequate warning, and the vaccine was not shown to be defective (it was a trivalent live-virus Sabin oral polio vaccine, as intended).

Vioxx cases. Similarly, some plaintiffs have been awarded millions of dollars (as in Ernst v. Merck & Co., Inc.29) in rulings that Merck & Co. failed to disclose the risk of cardiotoxicity with the arthritis drug rofecoxib (Vioxx) and thus failed to provide physicians with information needed when prescribing the drug. In Humeston v. Merck & Co.,30 a Texas court in 2005 held that Vioxx’s warning labels were adequate. In a retrial, however, the New Jersey Superior Court awarded the plaintiff $47.5 million.31

As with the polio vaccine and Vioxx litigations, courts are being asked to decide if patients were adequately informed about sleep-driving and other risks associated with the use of sedative-hypnotics.

Clinical recommendations

Zolpidem—like many other medications—carries a substantial risk of side effects, even when used appropriately. However, given the medical and mental health risks of untreated insomnia, the benefits of a medication such as zolpidem will likely outweigh its risks.

Numerous studies have shown that zolpidem is effective for improving sleep latency and that there are mild, if any, residual side effects beyond what would normally be a restful night’s sleep. Impairments are evident, however, during the hours following the drug’s administration, with some effects lasting >5 hours depending on the dose.

Risk management. When prescribing nonbenzodiazepine hypnotics such as zolpidem, you may want to adopt a risk management approach as you would with other medications that can have serious side effects. An approach to benzodiazepine prescribing proposed by Bursztajn et al31 advocates:

  • using the informed-consent process to build an alliance with patients
  • not prescribing the medication in isolation of other beneficial therapies
  • being aware of and always documenting your decision-making process.
 

 

When you make patients aware of all risks, benefits, alternate therapies, and possible outcomes with no treatment, you have informed them effectively. Patients are then left to decide whether or not to agree to the treatment. You also are responsible for monitoring the patient, addressing the patient’s questions, and relaying important safety information.

When prescribing zolpidem, discuss safety information with the patient, such as:

  • Do not drive or operate heavy equipment for at least 5 to 6 hours after administration.
  • Have a safety plan in place for transportation during those hours.
  • Do not use this medication with alcohol or other sedative/hypnotics.
  • Contact the prescriber about any suspected adverse effects.
Related resources

Drug brand names

  • Diazepam • Valium
  • Eszopiclone • Lunesta
  • Midazolam • Versed
  • Oxazepam • Serax
  • Quazepam • Doral
  • Rofecoxib • Vioxx
  • Temazepam • Restoril
  • Triazolam • Halcion
  • Zolpidem • Ambien, Ambien CR
  • Zaleplon • Sonata
  • Zopiclone • Imovane (in Europe)
Disclosure

The authors report no financial relationships with any company whose products are mentioned in this article or with manufacturers of competing products.

Acknowledgments

The authors acknowledge the assistance and guidance of Linda T. Moore, JD, in preparing this manuscript.

“Sleep driving” blamed on the hypnotic zolpidem was used as a defense last year in Virginia in a criminal case involving impaired driving. The defendant’s attorney argued that the defendant should not be held criminally liable because he was “essentially unconscious” and the accident therefore was involuntary.

The “sleep driving” defense failed when testimony revealed the defendant had taken 5 times the recommended zolpidem dose before the accident. The judge found him guilty of a felony charge of driving under the influence of a sleep medication.1

Sedative-hypnotics are increasingly being used to treat insomnia2-4 and as a result some patients try to drive while under the drugs’ sedating effects. Also, new FDA-ordered labeling for all 13 available prescription sleep aids warns of potential risks of “complex sleep-related behaviors,” including driving, phoning, and eating while asleep (Box 1).

Hypnotics can improve quality of life and well-being by addressing insomnia’s complications—hypertension, diabetes, coronary artery disease, depression, and anxiety5-7—but they also have been associated with impaired motor coordination and somnambulism. To help you and your patients weigh sleep medications’ relative risks and benefits, we report on clinical studies and court cases in the literature. Most of the data focus on zolpidem, by far the most prescribed hypnotic (Box 2).8,9

Box 1

New labeling for hypnotics: Sleep-related behaviors

Labeling of all sedative-hypnotic drugs now carries FDA-ordered precautions about “sleep-driving and other complex behaviors” that may occur without the patient being fully awake. FDA cited reports of patients preparing and eating food, making phone calls, and having sex after taking a sedative-hypnotic, usually without memory of the event. A warning also was added about rare, potentially fatal anaphylactic reactions in patients taking first or later doses of sleep medications.

Steven Galson, MD, MPH, director of FDA’s Center for Drug Evaluation and Research, said the labeling changes were needed to inform patients and prescribers about the risks of sleep aids that “are well-tolerated and effective for many people.”

Source: Walsh S, Rawlings K. FDA requests label change for all sleep disorder drug products. Available at www.fda.gov/bbs/topics/NEWS/2007/NEW01587.html.

Zolpidem incidents and cases

In 2005, Americans filled 43 million prescriptions for sedative-hypnotics—26.5 million for zolpidem alone—compared with 29 million prescriptions in 2001.4 In addition to the new the FDA-requested warnings about sleep-related behaviors, zolpidem’s labeling cautions patients about operating heavy machinery, driving, or engaging in hazardous occupations after taking the drug. The manufacturer tells patients:

  • to ingest zolpidem only before going to bed
  • that they may experience residual sedation the following day.
Not all patients heed the precautions or follow dosing recommendations, however.

Impaired driving. Besides the “sleep driving” case in Virginia, a highly publicized zolpidem-related driving incident occurred May 4, 2006, when U.S. Representative Patrick Kennedy was involved in an accident after having taken zolpidem in combination with an antinausea medication. Another driving-related case has used zolpidem as a defense for impairment, but the court decided that the medication was not at fault because the defendant also had ingested alcohol.10

Other litigation. Although zolpidem-related impairment apparently has not been used successfully as a defense for a driving incident, class action suits alleging failure to disclose potentially harmful side effects have been filed against the manufacturer.

In Janet Makinen and others v. sanofi-aventis,11 at least 500 plaintiffs claim zolpidem is related to sleep-driving, sleep-eating, and other somnambulistic behaviors. Plaintiffs allege negligence, breach of implied warranties, fraud, unfair trade practices, express warranty violations, strict liability, and consumer fraud violations. Other suits claim dangerous sleep-related side effects with zolpidem use.12

What clinical evidence shows

Driving impairment. Clinical studies have shown conflicting results about driving impairment associated with zolpidem. The literature falls into 2 categories, based on treatment duration:

  • Zolpidem affects performance and memory within the first 4 to 5 hours of administration (Table 1).
  • Beyond 5 hours, no residual effects on performance have been identified (Table 2), and repeat nightly dosing has not caused impairment or tolerance.
Verster et al13 examined residual effects of benzodiazepines and the nonbenzodiazepines zolpidem, zopiclone (available in the United States as eszopiclone), and zaleplon on driving ability, as reported in studies of on-the-road driving, driving simulators, epidemiologic data, and closed-road driving. This review found that:

  • All sedative hypnotic benzodiazepines had statistically significant residual effects 10 to 11 hours after ingestion, with longer periods of impairment corresponding to medications with longer half-lives.
  • Zopiclone was associated with significant residual impairment for up to 10 hours after ingestion.
  • Zolpidem and zaleplon showed no significant impairment in driving 10 to 11 hours after ingestion. Impairment was found, however, when zolpidem was taken within 5 hours of driving.14-18
 

 

Table 1

Studies of zolpidem-associated driving skills impairment
(

Author/designDoses and timingDriving skills assessmentsConclusions
Wilkinson, 199514 Blinded; 29 subjectsZolpidem, 10 mg, 15 mg, and placebo in combination with an alcoholic drink (to reach a BAC of 0.08%) or placebo drink; testing 45 min, 130 min, and 230 min after administrationVisual backward masking test (approximates driving performance) and attention testsZolpidem produced significant impairment in combination with alcohol and when administered alone during peak effect assessment; alcohol did not potentiate zolpidem’s effects; additive effects of alcohol seen with 10-mg dose but not 15-mg dose of zolpidem
Rush et al, 199815 Double-blind, crossover; 9 subjectsZolpidem, 7.5, 15, and 22.5 mg; quazepam, 15, 30, and 45 mg; triazolam, 0.1875, 0.375, and 0.5625 mg; testing ½, 1, 1½, 2, 2½, 3, 4, 5, and 6 hours after administrationSubject- and observer-rated questionnaires; tests of recall and delayed recognitionPerformance-impairing effects of zolpidem were virtually indistinguishable from those of classic benzodiazepines, such as triazolam
Mattila et al, 199816 Randomized, placebo-controlled, double-blind, crossover; 12 subjectsZolpidem, 15 mg; diazepam, 15 mg; oxazepam, 30 mg; zopiclone, 7.5 mg; alcohol testing before and 1, 3½, and 5 hours after administrationSimulated driving and other measuresZolpidem impaired coordination, reaction, and cognition at 1 and 3½ hours; tracking remained impaired at 5 hours; all agents (especially zolpidem) impaired learning and memory
Mintzer et al, 199917 Double-blind, placebo-controlled; 16 subjectsZolpidem, 15 mg/70 kg (dosed by subject weight); testing ½, 1, 2, and 3 hours after administrationMemory tasks (recall, fragment completion, recognition)Zolpidem interfered with explicit but not implicit memory after administration; zolpidem produced a specific deficit in acquisition of contextual information
Verster et al, 200418 2-step randomized, placebo-controlled, double-blind, crossover; 30 subjectsZolpidem, 10 mg and 20 mg; zaleplon, 10 mg and 20 mg; middle-of-the-night dosing; testing 4 hours after dosingOn-the-road driving and other tests of attention, learning, and thinkingZolpidem, 10 mg and 20 mg, significantly impaired driving function; zolpidem, 20 mg, produced significant impairment on all psychomotor and memory tests; zaleplon, 10 mg and 20 mg, did not differ significantly from placebo
BAC: Blood alcohol concentration
Table 2

Studies of zolpidem-associated driving skills impairment
(>5 hours after dosing)

Author/designDoses and timingDriving skills assessmentsConclusions
Fairweather et al, 199223 Randomized, placebo-controlled; 24 older volunteers taking no other medicationsZolpidem, 5 mg or 10 mg, or placebo taken before bedtime; testing 8.5 hours after administrationNumerous, including reactive time, memory, word recognitionZolpidem consistently helped with sleep latency, with no residual performance deficits; no tolerance seen with repeated dosing
Bocca et al, 199924 Double-blind, crossover; 16 volunteersZolpidem, 10 mg; zopiclone, 7.5 mg; flunitrazepam,* 1 mg; and placebo given at 11 PM, with testing at 9 AMDriving simulation and real time test drive; eye movements measured after driving testsNo residual effects with zolpidem; zopiclone impaired driving ability and increased saccadic latency; flunitrazepam impaired early morning driving and saccadic eye movements longer than zopiclone
Partinen et al, 200320 Randomized, placebo-controlled, double-blind, 3-period crossover; 18 women with insomniaZolpidem, 10 mg; temazepam, 20 mg; dosing at 2 AM, testing 5.5 hours after dosingDriving simulation; delayed word recall and memory testing (FePsy test)No statistically significant effects on driving ability with either drug; no significant differences in FePsy results compared with baseline or placebo
Staner et al, 200525 Randomized, placebo-controlled, double-blind, four-way crossover; 23 subjects with DSM-IV-TR diagnosis of insomniaZolpidem, 10 mg; zopiclone, 7.5 mg; lormetazepam,* 1 mg; 7 days of dosing; tests given 9 to 11 hours post-dosingDriving simulation; EEG at rest and while drivingZolpidem showed no impairment of driving ability and no EEG changes compared with placebo; driving impairment and EEG alterations were found with zopiclone and lormetazepam
* Hypnotics not approved in the United States but available elsewhere.

Acute effects (

Combined with alcohol. Wilkinson14 conducted a randomized, 6-way crossover study in which subjects received 10- or 15-mg doses of zolpidem or placebo plus an alcoholic beverage (enough to obtain a blood alcohol concentration [BAC] of ~0.08%) or placebo beverage. Tests given shortly after patients took the study medications showed that zolpidem caused statistically significant impairment both in combination with alcohol and alone during peak drug effect—identified as 45 minutes after ingestion. Alcohol did not potentiate the impairment associated with zolpidem.

Using a similar design, Mattila et al16 compared acute performance impairment associated with zolpidem, diazepam, oxazepam, and zopiclone. In this randomized, double-blinded, crossover study, all comparison medications impaired antecedent learning and memory, but zolpidem given at 15 mg had the greatest effect. Zolpidem impaired coordination, reactive functioning, and cognitive skills at 1 and 3.5 hours after administration, and simulated driving test performance remained impaired at 5 hours (approximately two half-lives of the medication). Of note is that the 15-mg zolpidem dose used in this study was shown by Wilkinson et al14 to be more impairing than the recommended maximum 10-mg dose.

 

 

A study from the University of Toronto19 that did not include zolpidem examined potential psychomotor performance deficits and sleepiness in a comparison of time-released melatonin, 6 mg; zaleplon, 10 mg; zopiclone, 7.5 mg; temazepam, 15 mg, and placebo. Tests were given to 9 men and 14 women, ages 21 to 53, just before drug administration and 7 hours later.

Zaleplon had the greatest effect on psychomotor performance, followed by temazepam and zopiclone. Aside from prolonged perceived sleepiness, melatonin and placebo did not interfere with performance testing.

Box 2

Zolpidem: Approved for ‘short-term’ insomnia

Zolpidem, a benzodiazepine receptor agonist, was the 7th most prescribed drug in the United States in 2005 (2006 data not available).8 It is FDA-approved for short-term treatment of insomnia, although “short-term” is not defined. Package labeling states:

This nonbenzodiazepine hypnotic has been shown to decrease sleep latency and increase sleep duration for up to 35 days in controlled clinical trials. Patients should be evaluated for a primary psychiatric or medical illness if insomnia does not remit after 7 to 10 days of treatment.

An imidazopyridine that acts as an agonist of GABA A1, zolpidem produces sedation while avoiding anticonvulsant, anxiolytic, and muscle relaxation effects. Available in 5- and 10-mg tablets, the drug is rapidly absorbed in the GI tract and excreted primarily through the kidneys. Its half-life is approximately 2.5 hours (approximately 3 hours in elderly patients). The most common side effects are daytime drowsiness, dizziness, and diarrhea; others include asthenia, hiccup, and diplopia.9

Middle-of-the-night dosing. Effects of zolpidem and zaleplon on driving ability, memory, and psychomotor performance were compared by Verster et al18 in a randomized, controlled trial. The double-blind, 5-period crossover design measured the effects of middle-of-the-night use of zaleplon, 10 or 20 mg; zolpidem, 10 or 20 mg; or placebo on:

  • driving ability 4 hours after administration
  • memory and psychomotor performance 6 hours after administration.
As expected, subjects taking zolpidem showed impairment on all measures. The 10- and 20-mg doses significantly impaired driving 4 hours after ingestion, with the 20-mg dose—twice the recommended maximum dose—producing greater impairment. The 20-mg dose—but not the 10-mg dose—also significantly impaired memory and psychomotor function. Zaleplon did not impair driving ability, memory, or psychomotor testing.

Partinen et al20 used the recommended zolpidem dose in a similar study of after-midnight use by women with insomnia. The double-blind, randomized, controlled trial evaluated performance with a driving simulator and neuropsychological testing 5.5 hours after medication dosing. Patients taking zolpidem, 10 mg, showed no significant impairment when compared with those taking placebo. Some patients scored poorly on the driving tests alone, and the authors concluded that this group was more susceptible to zolpidem’s effect.

Memory. In a double-blind, placebo-controlled trial by Mintzner et al,17 zolpidem dosed by patient weight at 15 mg/70 kg:

  • significantly impaired explicit memory (requires conscious recollection for recall)
  • did not affect implicit memory (lack of conscious awareness in the act of recollection).
Explicit memory for material presented before drug administration and previously acquired knowledge was not affected. Zolpidem spared explicit and implicit memory for material presented before administration, but subjects had difficulty acquiring contextual information after the dose was given.

These findings support complaints of zolpidem-related anterograde amnestic episodes, which also occur with some benzodiazepines (such as midazolam).

Similar to benzodiazepines? Rush et al’s results21 support Mintzer’s assertion17 that zolpidem shares many side effects with benzodiazepines. Performance impairment associated with zolpidem—as rated by subjects and observers—is virtually indistinguishable from a benzodiazepine effect, except that the duration is shorter with zolpidem (5 hours), compared with up to 10 hours for benzodiazepines.

Logan and Couper22 reviewed police reports and toxicology profiles of individuals suspected of driving while impaired. Zolpidem was found in 29 subjects, 5 of whom showed no other substances. In those 5, zolpidem blood levels ranged from 0.08 to 1.40 mg/L and did not appear to correlate with the degree of impairment.

Residual effects (>5 hours)

Older patients. In a randomized, placebo-controlled trial by Fairweather et al,23 zolpidem improved sleep latency in 24 subjects ages 63 to 80. No evidence of impairment in reactive time, memory, or word recognition was found 8.5 hours after nighttime dosing, and tolerance was not seen after 1 week of repeated dosing.

 

 

Driving impairment. Bocca et al24 compared degree of driving impairment by zolpidem, zopiclone, flunitrazepam (not approved in the United States), and placebo. The 16 subjects received each medication at 11 pm, with a 2-week washout between medications. One group of 8 was tested at 9 am and the other 8 subjects at 11 am. Those taking zolpidem showed no residual performance impairment, as measured by simulated driving, a test drive, and saccadic eye movements.

Staner et al25 reported similar results when comparing zolpidem, zopiclone, lormetazepam (not approved in the United States), and placebo. Using a driving simulator and electroencephalography (EEG), they evaluated 23 subjects diagnosed with insomnia at 9 and 11 hours post-dose. Zolpidem did not significantly impair driving ability and did not differ from placebo on EEG analysis (resting or driving). The study showed driving impairment with zopiclone and lormetazepam, along with characteristic benzodiazepine EEG changes. This study further supports evidence of limited impairment on driving after appropriate use of zolpidem.

Informed consent

In the informed consent process, failing to warn a patient about medication side effects can lead to legal claims against both manufacturers and prescribers. With any medication, patients have the right to know about a drug’s risks, benefits, and alternate therapies—including no therapy.

Two standards are associated with informed consent and negligence:

  • The “reasonable practitioner” standard outlined in Natanson v. Kline (1960)26 mandates that the prescribing physician has revealed all that an “average, reasonable practitioner” would disclose in similar circumstances.
  • The “reasonable patient” standard set in Canterbury v. Spence (1972)27 mandates that the prescribing physician has informed the patient about the proposed treatment, its side effects, and alternatives to the proposed treatment that a reasonable patient would consider material to the decision of whether or not to undergo treatment.
Failure to warn. Plaintiffs may allege a failure to warn if a drug manufacturer withheld information, thus not adequately warning the dispensing provider. In Reyes v. Wyeth Laboratories, for example, the U.S. Fifth Circuit Court of Appeals ruled that the polio vaccine’s manufacturer failed to warn the parents of a child who contracted polio from the vaccine about the 1-in-a-million chance of this adverse effect.28

The vaccine was licensed as a prescription drug but administered through county health departments. In 1970, a nurse in a Texas Department of Health clinic administered the vaccine to 8-month-old Anita Reyes without telling the girl’s parents of warnings in the package circular. Holding Wyeth Laboratories to a reasonableness standard, the court found that the company knew or should have known how the vaccine would be distributed.

The package insert was not shown to have given inadequate warning, and the vaccine was not shown to be defective (it was a trivalent live-virus Sabin oral polio vaccine, as intended).

Vioxx cases. Similarly, some plaintiffs have been awarded millions of dollars (as in Ernst v. Merck & Co., Inc.29) in rulings that Merck & Co. failed to disclose the risk of cardiotoxicity with the arthritis drug rofecoxib (Vioxx) and thus failed to provide physicians with information needed when prescribing the drug. In Humeston v. Merck & Co.,30 a Texas court in 2005 held that Vioxx’s warning labels were adequate. In a retrial, however, the New Jersey Superior Court awarded the plaintiff $47.5 million.31

As with the polio vaccine and Vioxx litigations, courts are being asked to decide if patients were adequately informed about sleep-driving and other risks associated with the use of sedative-hypnotics.

Clinical recommendations

Zolpidem—like many other medications—carries a substantial risk of side effects, even when used appropriately. However, given the medical and mental health risks of untreated insomnia, the benefits of a medication such as zolpidem will likely outweigh its risks.

Numerous studies have shown that zolpidem is effective for improving sleep latency and that there are mild, if any, residual side effects beyond what would normally be a restful night’s sleep. Impairments are evident, however, during the hours following the drug’s administration, with some effects lasting >5 hours depending on the dose.

Risk management. When prescribing nonbenzodiazepine hypnotics such as zolpidem, you may want to adopt a risk management approach as you would with other medications that can have serious side effects. An approach to benzodiazepine prescribing proposed by Bursztajn et al31 advocates:

  • using the informed-consent process to build an alliance with patients
  • not prescribing the medication in isolation of other beneficial therapies
  • being aware of and always documenting your decision-making process.
 

 

When you make patients aware of all risks, benefits, alternate therapies, and possible outcomes with no treatment, you have informed them effectively. Patients are then left to decide whether or not to agree to the treatment. You also are responsible for monitoring the patient, addressing the patient’s questions, and relaying important safety information.

When prescribing zolpidem, discuss safety information with the patient, such as:

  • Do not drive or operate heavy equipment for at least 5 to 6 hours after administration.
  • Have a safety plan in place for transportation during those hours.
  • Do not use this medication with alcohol or other sedative/hypnotics.
  • Contact the prescriber about any suspected adverse effects.
Related resources

Drug brand names

  • Diazepam • Valium
  • Eszopiclone • Lunesta
  • Midazolam • Versed
  • Oxazepam • Serax
  • Quazepam • Doral
  • Rofecoxib • Vioxx
  • Temazepam • Restoril
  • Triazolam • Halcion
  • Zolpidem • Ambien, Ambien CR
  • Zaleplon • Sonata
  • Zopiclone • Imovane (in Europe)
Disclosure

The authors report no financial relationships with any company whose products are mentioned in this article or with manufacturers of competing products.

Acknowledgments

The authors acknowledge the assistance and guidance of Linda T. Moore, JD, in preparing this manuscript.

References

1. Markon J. Sleeping Va. driver convicted in crash; man had taken too much Ambien. The Washington Post, August 2, 2006. Accessed August 26, 2006 from LexisNexis Academic Database.

2. Colten HR, Altevogt BM. Sleep disorders and sleep deprivation: an unmet public health problem. Available at: http://www.iom.edu/CMS/3740/23160/33668.aspx. Accessed February 21, 2007.

3. Mellinger GD, Balter MB, Uhlenhuth EH. Insomnia and its treatment; prevalence and correlates. Arch Gen Psychiatry 1985;42:225-32.

4. Barclay L. Driving, other erratic behaviors reported after taking zolpidem. Available at http://www.medscape.com/viewarticle/528415. Accessed February 21, 2007.

5. Gottlieb DJ, Redline S, Nieto FJ, et al. Association of usual sleep duration with hypertension: the Sleep Heart Health Study. Sleep 2006;29(8):1009-14.

6. Gottlieb DJ, Punjabi NM, Newman AB, et al. Association of sleep time with diabetes mellitus and impaired glucose tolerance. Arch Intern Med 2005;165(8):863-7.

7. Perlis ML, Smith LJ, Lyness JM, et al. Insomnia as a risk factor for onset of depression in the elderly. Behav Sleep Med 2006;4(2):104-13.

8. Verispan VONA. Top 200 brand name drugs by units in 2005. Drug Topics 2006. Available at: http://www.drugtopics.com/drugtopics/data/articlestandard/drugtopics/102006/311294/article.pdf. Accessed February 22, 2007.

9. sanofi-aventis Ambien prescribing information. Available at: http://products.sanofi-aventis.us/ambien/ambien.html. Accessed February 21, 2007.

10. Pear R. Patrick Kennedy crashes car into a Capitol Hill barrier. The New York Times, May 5, 2006. Accessed September 25, 2006 from LexisNexis Academic Database.

11. Janet Makinen and others v. Sanofi-Synthelabo & Sanofi-Synthelabo, Inc. Class action suit filed March 6, 2006 in U.S. District Court for the Southern District of New York, NY.

12. Tooher NL. Ambien users are filing lawsuits. Kansas City Daily Record, April 12, 2006. Accessed September 25, 2006 from LexisNexis Academic Database.

13. Verster JC, Veldhuijzen DS, Volkerts ER. Residual effects of sleep medication on driving ability. Sleep Med Rev 2004;8(4):309-25.

14. Wilkinson CJ. The acute effects of zolpidem, administered alone and with alcohol, on cognitive and psychomotor function. J Clin Psychiatry 1995;56(7):309-18.

15. Rush CR, Armstrong DL, Ali JA, Pazzaglia PJ. Benzodiazepine-receptor ligands in humans: acute performance-impairing, subject-rated and observer-rated effects. J Clin Psychopharmacol 1998;18(2):154-65.

16. Mattila MJ, Vanakoski J, Kalska H, Seppala T. Effects of alcohol, zolpidem, and some other sedatives and hypnotics on human performance and memory. Pharmacol Biochem Behav 1998;59(4):917-23.

17. Mintzer MZ, Griffiths RR. Selective effects of zolpidem on human memory functions. J Psychopharmacol 1999;13(1):18-31.

18. Verster JC, Volkerts ER, Schreuder AH, et al. Residual effects of middle-of-the-night administration of zaleplon and zolpidem on driving ability, memory functions, and psychomotor performance. J Clin Psychopharmacol 2002;22(6):576-83.

19. Paul MA, Gray G, Kenny G, Pigeau RA. Impact of melatonin, zaleplon, zopiclone, and temazepam on psychomotor performance. Aviat Space Environ Med 2003;74(12):1263-70.

20. Partinen M, Hirvonen K, Hublin C, et al. Effects of after-midnight intake of zolpidem and temazepam on driving ability in women with non-organic insomnia. Sleep Med 2003;4(6):553-61.

21. Rush CR, Armstrong DL, Ali JA, Pazzaglia PJ. Benzodiazepine-receptor ligands in humans: acute performance-impairing, subject-rated and observer-rated effects. J Clin Psychopharmacol 1998;18(2):154-65.

22. Logan BK, Couper FJ. Zolpidem and driving impairment. J Forensic Sci 2001;46(1):105-10.

23. Fairweather DB, Kerr JS, Hindmarch I. The effects of acute and repeated doses of zolpidem on subjective sleep, psychomotor performance and cognitive function in elderly volunteers. Eur J Clin Pharmacol 1992;43(6):597-601.

24. Bocca ML, Le Doze F, Etard O, et al. Residual effect of zolpidem 10 mg and zopiclone 7.5 mg versus flunitrazepam 1 mg and placebo on driving performance and ocular saccades. Psychopharmacology (Berl) 1999;143(4):373-9.

25. Staner L, Ertle S, Boeijinga P, et al. Next-day residual effects of hypnotics in DSM-IV primary insomnia: a driving simulator study with simultaneous electroencephalogram monitoring. Psychopharmacology (Berl) 2005;181(4):790-8.

26. Natanson v. Kline 300 P.2d 1093 (1960).

27. Canterbury v. Spence 464 F.2d 772 (1972).

28. Reyes v. Wyeth Laboratories. 498 F.2d 1264 (1974).

29. Ernst v. Merck & Co. 24 PLLR 149 (2005).

30. Humeston v. Merck & Co., No. ATL-L-2272-03-MT, Super. Ct., Atlantic County, NJ, November 3, 2005.

31. Johnson LA. Jury blames Vioxx for man’s heart attack, awards $47.5 million. Available at http://news.findlaw.com/ap/o/51/03-12-2007/85f9000f67cd576a.html. Accessed March 16, 2007.

32. Bursztajn HJ, Brodsky A. Ethical and legal dimensions of benzodiazepine prescription: a commentary. Psychiatr Ann 1998;28(3):121-7.

References

1. Markon J. Sleeping Va. driver convicted in crash; man had taken too much Ambien. The Washington Post, August 2, 2006. Accessed August 26, 2006 from LexisNexis Academic Database.

2. Colten HR, Altevogt BM. Sleep disorders and sleep deprivation: an unmet public health problem. Available at: http://www.iom.edu/CMS/3740/23160/33668.aspx. Accessed February 21, 2007.

3. Mellinger GD, Balter MB, Uhlenhuth EH. Insomnia and its treatment; prevalence and correlates. Arch Gen Psychiatry 1985;42:225-32.

4. Barclay L. Driving, other erratic behaviors reported after taking zolpidem. Available at http://www.medscape.com/viewarticle/528415. Accessed February 21, 2007.

5. Gottlieb DJ, Redline S, Nieto FJ, et al. Association of usual sleep duration with hypertension: the Sleep Heart Health Study. Sleep 2006;29(8):1009-14.

6. Gottlieb DJ, Punjabi NM, Newman AB, et al. Association of sleep time with diabetes mellitus and impaired glucose tolerance. Arch Intern Med 2005;165(8):863-7.

7. Perlis ML, Smith LJ, Lyness JM, et al. Insomnia as a risk factor for onset of depression in the elderly. Behav Sleep Med 2006;4(2):104-13.

8. Verispan VONA. Top 200 brand name drugs by units in 2005. Drug Topics 2006. Available at: http://www.drugtopics.com/drugtopics/data/articlestandard/drugtopics/102006/311294/article.pdf. Accessed February 22, 2007.

9. sanofi-aventis Ambien prescribing information. Available at: http://products.sanofi-aventis.us/ambien/ambien.html. Accessed February 21, 2007.

10. Pear R. Patrick Kennedy crashes car into a Capitol Hill barrier. The New York Times, May 5, 2006. Accessed September 25, 2006 from LexisNexis Academic Database.

11. Janet Makinen and others v. Sanofi-Synthelabo & Sanofi-Synthelabo, Inc. Class action suit filed March 6, 2006 in U.S. District Court for the Southern District of New York, NY.

12. Tooher NL. Ambien users are filing lawsuits. Kansas City Daily Record, April 12, 2006. Accessed September 25, 2006 from LexisNexis Academic Database.

13. Verster JC, Veldhuijzen DS, Volkerts ER. Residual effects of sleep medication on driving ability. Sleep Med Rev 2004;8(4):309-25.

14. Wilkinson CJ. The acute effects of zolpidem, administered alone and with alcohol, on cognitive and psychomotor function. J Clin Psychiatry 1995;56(7):309-18.

15. Rush CR, Armstrong DL, Ali JA, Pazzaglia PJ. Benzodiazepine-receptor ligands in humans: acute performance-impairing, subject-rated and observer-rated effects. J Clin Psychopharmacol 1998;18(2):154-65.

16. Mattila MJ, Vanakoski J, Kalska H, Seppala T. Effects of alcohol, zolpidem, and some other sedatives and hypnotics on human performance and memory. Pharmacol Biochem Behav 1998;59(4):917-23.

17. Mintzer MZ, Griffiths RR. Selective effects of zolpidem on human memory functions. J Psychopharmacol 1999;13(1):18-31.

18. Verster JC, Volkerts ER, Schreuder AH, et al. Residual effects of middle-of-the-night administration of zaleplon and zolpidem on driving ability, memory functions, and psychomotor performance. J Clin Psychopharmacol 2002;22(6):576-83.

19. Paul MA, Gray G, Kenny G, Pigeau RA. Impact of melatonin, zaleplon, zopiclone, and temazepam on psychomotor performance. Aviat Space Environ Med 2003;74(12):1263-70.

20. Partinen M, Hirvonen K, Hublin C, et al. Effects of after-midnight intake of zolpidem and temazepam on driving ability in women with non-organic insomnia. Sleep Med 2003;4(6):553-61.

21. Rush CR, Armstrong DL, Ali JA, Pazzaglia PJ. Benzodiazepine-receptor ligands in humans: acute performance-impairing, subject-rated and observer-rated effects. J Clin Psychopharmacol 1998;18(2):154-65.

22. Logan BK, Couper FJ. Zolpidem and driving impairment. J Forensic Sci 2001;46(1):105-10.

23. Fairweather DB, Kerr JS, Hindmarch I. The effects of acute and repeated doses of zolpidem on subjective sleep, psychomotor performance and cognitive function in elderly volunteers. Eur J Clin Pharmacol 1992;43(6):597-601.

24. Bocca ML, Le Doze F, Etard O, et al. Residual effect of zolpidem 10 mg and zopiclone 7.5 mg versus flunitrazepam 1 mg and placebo on driving performance and ocular saccades. Psychopharmacology (Berl) 1999;143(4):373-9.

25. Staner L, Ertle S, Boeijinga P, et al. Next-day residual effects of hypnotics in DSM-IV primary insomnia: a driving simulator study with simultaneous electroencephalogram monitoring. Psychopharmacology (Berl) 2005;181(4):790-8.

26. Natanson v. Kline 300 P.2d 1093 (1960).

27. Canterbury v. Spence 464 F.2d 772 (1972).

28. Reyes v. Wyeth Laboratories. 498 F.2d 1264 (1974).

29. Ernst v. Merck & Co. 24 PLLR 149 (2005).

30. Humeston v. Merck & Co., No. ATL-L-2272-03-MT, Super. Ct., Atlantic County, NJ, November 3, 2005.

31. Johnson LA. Jury blames Vioxx for man’s heart attack, awards $47.5 million. Available at http://news.findlaw.com/ap/o/51/03-12-2007/85f9000f67cd576a.html. Accessed March 16, 2007.

32. Bursztajn HJ, Brodsky A. Ethical and legal dimensions of benzodiazepine prescription: a commentary. Psychiatr Ann 1998;28(3):121-7.

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Current Psychiatry - 06(04)
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Current Psychiatry - 06(04)
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Hypnotics and driving: FDA action, clinical trials show need for precautions
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Hypnotics and driving: FDA action, clinical trials show need for precautions
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hypnotics; zolpidem; Ambien; nonbenzodiazepine hypnotics; insomnia; hypnotics and driving; Bradley Freeman; J. Jason Buckland; R. Gregg Dwyer; Richard L. Frierson
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hypnotics; zolpidem; Ambien; nonbenzodiazepine hypnotics; insomnia; hypnotics and driving; Bradley Freeman; J. Jason Buckland; R. Gregg Dwyer; Richard L. Frierson
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