Nasal EPAP

Nasal EPAP (Expiratory Positive Airway Pressure) is a treatment for snoring and obstructive sleep apnea (OSA). Nasal EPAP utilizes the user’s own breathing to create positive airway pressure to prevent obstructed breathing. The first commercially available nasal EPAP device indicated for the treatment of obstructive sleep apnea (Provent Therapy) was cleared by the United States FDA in 2008. To treat snoring, over-the-counter devices like Theravent are now available using the same nasal EPAP technology. In a series of published articles, nasal EPAP has been shown to provide statistically significant reductions in apnea hypopnea index (AHI), oxygen desaturation index (ODI) and sleepiness, with high patient acceptance and compliance. It has also been proven, through clinical tests, to reduce snoring by 76%.^{[1][2][3][4][5][6][7][8][9][10][11][12]}

Background

Obstructive Sleep Apnea (OSA)

Obstructive sleep apnea (OSA) is a common medical condition that can be associated with a variety of symptoms and morbidities. OSA frequently results in excessive daytime sleepiness, which is associated with an increased risk of motor vehicle accidents.^[13][14] OSA has also been linked to hypertension, stroke, congestive heart failure, cardiac arrhythmia and depression.^{[15][16][17][18]}

The gold standard treatment of OSA, continuous positive airway pressure (CPAP), is effective for any severity of OSA as long as the patient remains compliant with therapy. However, CPAP therapy can be cumbersome, noisy and uncomfortable, and many patients either cannot tolerate CPAP at all, or only use it sporadically. It has been reported that 46 to 83% of patients with OSA are non-adherent to CPAP treatment.^[19] Thus, while CPAP is highly efficacious in a laboratory setting, it is not used regularly at home by a large proportion of patients.

A goal of successful treatment is to prevent as many breathing disturbances as possible, which requires both efficacy and utilization. If a therapy such as CPAP reduces the apnea–hypopnea index (AHI) from 40 to 10 events per hour but is only used for 50% of total sleep time, the effective AHI is 25.^[20][21]

Response to non-CPAP therapies is typically expressed as the percentage of patients who achieve either a ≥ 50% AHI reduction, or an AHI of less than 10. The basic treatment principle of OSA is to maximally reduce the AHI, recognizing that achieving an AHI of less than 10 may not be possible in all patients, especially those with severe OSA. In these cases, a partial AHI reduction may be better than non-treatment.

Using EPAP to treat snoring

EPAP can also be used to treat snoring, a lesser condition than OSA, but with similar causes. Snoring is caused by vibrations in a person’s airway as they breathe out. EPAP devices in this category increase the pressure inside the airway using the power of an individual’s own breathing to keep the airway stable. Maintaining an open airway can reduce or even relieve snoring.^[22]

Theravent is the first FDA-cleared EPAP device indicated to reduce or eliminate snoring.^[23]

Technology and mechanism of action

Nasal EPAP was developed by Ventus Medical (Belmont, California) and is now made available by Theravent, Inc as well as TIOSA, Inc the creators of the NED Device. Theravent consists of a small valve attached externally to each nostril with hypoallergenic adhesive. The valve acts as a one-way resistor, permitting unobstructed inspiration. During expiration, the airflow is directed through small air channels, increasing the resistance. This increased resistance during expiration creates EPAP which is maintained until the start of the next inspiration. Whereas CPAP provides positive pressure during both inspiration and expiration, EPAP only creates pressure during expiration.

Snoring is treated through a nightly-use device that affixes over an individual’s nostrils to create a seal. Within the device, a small valve opens and closes as the individual breathes to keep the airway continuously open thus treating the root of the problem for most snorers.^[24]

Obstructive sleep apnea is traditionally thought of as an inspiratory disease. However, it is important to note that the closure of the upper airway has its origins at the end of expiration, when the pressure in the airway is zero. Morrell et al. showed that upper airway cross sectional area progressively decreased in the four breaths prior to an obstructive apnea, with this area being smallest at end-expiration. Their conclusion was that this expiratory narrowing made it more likely for the airway to completely collapse during the subsequent inspiration.^[25] Nasal EPAP devices create increased expiratory pressures which are maintained through the end of expiration and until the start of the subsequent inspiration.

The exact mechanism through which nasal EPAP treats OSA is still unclear, but several mechanisms appear most likely:

1) Positive end-expiratory pressure (PEEP) leading to increased end-expiratory lung volumes (or FRC) that increases longitudinal traction on the pharynx, rendering it less collapsible (“tracheal tug”).^[26] Indeed, the role of increased lung volumes in decreasing the compliance of the upper airway has been well described in the literature.^[27]

2) Dilatation of the upper airway by EPAP which carries over until the start of the next inspiration.^[28]

3) Mild hypercapnia due to reduced ventilation which would lead to increased respiratory drive to the upper airway.^[29]

Recommended patients^[30]

1) Individuals suffering from snoring who are looking for a daily-use treatment device would be eligible for over-the-counter EPAP devices specifically designed to treat snoring only.

2) Patients who have been clinically diagnosed with OSA would be eligible for a prescription-only EPAP device.

a) Patients (mild, moderate or severe) who have rejected or are non-compliant with prescribed CPAP

b) Newly diagnosed mild/moderate OSA patients without significant co-morbidities

c) CPAP compliant patients looking for alternatives for travel

For patients with moderate to severe OSA who are compliant with prescribed CPAP therapy in their normal setting, CPAP has been shown to provide better relief than EPAP.^[31]

Acclimation to nasal EPAP^[32]

It may take several days for patients to acclimate to breathing with nasal EPAP. Important recommendations include:

1) Understanding that the first few nights using nasal EPAP may be difficult, but that it improves over the ensuing days

2) Removing the device during initial nights if the user has difficulty sleeping with the device

3) Breathing through the mouth while awake and falling asleep

4) Understanding it may take up to ten nights or more to acclimate to nasal EPAP

Selected nasal EPAP clinical studies

A Novel Non-Prescription Nasal EPAP Device (Theravent) to Treat Snoring by Rajiv Doshi, MD and Philip Westbrook, MD

A novel nasal expiratory positive airway pressure device for the treatment of obstructive sleep apnea: a randomized controlled trial
Berry RB, Kryger MH, Massie CA. [SLEEP 2011; 34:479-485]^[33]

250 OSA patients from 19 centers were enrolled in this prospective, multicenter, parallel-group, sham controlled, randomized double-blind trial with three-month follow up. Patients were enrolled and randomized to a sham or nasal EPAP group. During the first week of treatment, patients underwent 2 in lab PSGs on non-consecutive nights (one device-on, one device-off in randomly assigned order). After three months of treatment, patients underwent another two in lab PSGs with the device on and device off. Outcomes included a comparison of the difference in the AHI between device-on and device-off nights in the nasal EPAP and sham groups at week one and at three months.

Treatment effect by severity is shown in Figure 1. Nasal EPAP reduced the median AHI from 8.8 to 3.9 in mild OSA patients (p < 0.001), from 20.5 to 8.4 in moderate OSA patients (p < 0.001) and from 48.2 to 18.9 in severe OSA patients (p < 0.001). At month three, treatment success (defined as at least a 50% reduction in the AHI or an AHI of less than 10) was achieved in 50.7% of patients in the nasal EPAP group. Based on patient self-report, the median percentage of nights the nasal EPAP device was used for the entire night was 88.2%. There were no serious device related adverse events reported. The authors concluded that nasal EPAP is an effective treatment alternative for a substantial percentage of the OSA population.

A convenient expiratory positive airway pressure nasal device for the treatment of sleep apnea in patients non-adherent with continuous positive airway pressure.
Walsh JK, Griffin KS, Forst EH, et al. [Sleep Medicine 2011;12:147-52]^[34]

This study focused on OSA patients who were non-adherent to CPAP. Most patients had moderate to severe OSA, with over half of the patients having a baseline AHI ≥ 30. A total of 59 patients with OSA who refused CPAP or used CPAP for less than 3 hours per night were provided the nasal EPAP device, of which 47 patients (80%) tolerated the device. Patients then underwent baseline sleep studies and 43 of these patients met enrollment criteria. Of these 43 patients, 24 (56%) met efficacy criteria based on AHI and symptom response. The responding patients continued on the device for 5 weeks, followed by a final in lab PSG to verify ongoing efficacy. The mean baseline AHI in these patients was 31.9 which decreased to 16.4 at 5 weeks. The Epworth Sleepiness Scale improved from a baseline of 12.3 to 8.7 (p = 0.001). Device use was reported an average of 92% of all sleep hours. This study in non-adherent CPAP patients demonstrated that nasal EPAP can lead to improvements in AHI and sleepiness, along with a high degree of treatment adherence.

A multicenter, prospective study of a novel nasal EPAP device in the treatment of obstructive sleep apnea. Efficacy and 30-day adherence.
Rosenthal L, Massie CA, Dolan DC, et al. [Journal of Clinical Sleep Medicine 2009;5:532-37]^[7]

This multicenter prospective study was specifically designed to assess adherence over a 30 day period, and also evaluated efficacy based on serial in lab PSG studies. A total of 34 patients with OSA underwent a 30 day trial of the nasal EPAP device. Patients kept a daily log and weekly phone calls were conducted by study staff. Participants reported using the nasal EPAP device all night long for 94.4% of the possible nights during the in-home trial. The 30 day study demonstrated a significant improvement in AHI (p = 0.001) and symptomatic improvement as measured by Epworth Sleepiness Scale (p < 0.001) and Pittsburgh Sleep Quality Index (p = 0.042). Percentage of the night spent snoring was also reduced significantly (p = 0.013). The authors concluded that treatment with nasal EPAP was well tolerated and accepted by patients in the study.

A pilot evaluation of a nasal expiratory resistance device for the treatment of obstructive sleep apnea.
Colrain IM, Brooks S, Black J. [Journal of Clinical Sleep Medicine 2008;4(5):426-433].^[8]

Thirty patients (24 with OSA, 6 with primary snoring) underwent 2 nights of in lab PSG, with and without the EPAP device with the order of nights counterbalanced to minimize first night effect. The studies were scored blind to treatment condition. The AHI (p < 0.001) and ODI (p < 0.01) both significantly decreased, and the percentage of the night spent above 90% saturation (p < 0.05) increased significantly with device use. The observed duration of snoring significantly decreased (p < 0.001) with nasal EPAP use.

Predictors of response to a nasal expiratory resistor device and its potential mechanisms of action for treatment of obstructive sleep apnea.
Patel AV, Hwang D, Masdeu MJ et al. [Journal of Clinical Sleep Medicine 2011;7(1):13-22].^[2]

This study sought to provide data to better understand the potential mechanisms of action of a nasal EPAP device. Twenty patients with OSA underwent 3 in-lab PSGS including diagnostic, therapeutic (nasal EPAP), and CPAP studies. Intranasal pressures, PCO₂, closing pressures (Pcrit), and awake lung volumes in different body positions were also measured. There were significant reductions in AHI (p < 0.05) and RDI (p < 0.0001) with nasal EPAP compared to the diagnostic study. No significant predictors of therapeutic response were found. Successful treatment of breathing events was associated with creation and maintenance of elevated end expiratory pressure. The authors concluded that nasal EPAP can treat sleep disordered breathing across the full spectrum of severity.

Long term use of a nasal expiratory positive airway pressure (EPAP) device as a treatment for obstructive sleep apnea.
Kryger MH, Berry RB, Massie CA. [Journal of Clinical Sleep Medicine 2011:7:5:449-453.]^[35]

This 13-center study was an extension of the three-month (Berry at al) study and designed to evaluate the long-term effectiveness of nasal EPAP after 12 months of follow-up. 41 patients from the nasal EPAP arm of the three-month study who met adherence and efficacy criteria were continued on therapy and returned for in lab PSG after 12 months of treatment. Results from these 12 month PSGs were compared against their baseline results. Median AHI was reduced from 15.7 to 4.7 (baseline device-off versus month 12 device-on). The AHI (median) reduction was 71.3% (p < 0.001). Percentage of time snoring was reduced by 74% (p < 0.001). The Epworth Sleepiness Scale decreased from 11.1 ± 4.2 to 6.0 ± 3.2 (p < 0.001) over the twelve months of study. The median percentage of nights patients reported using the device the entire night was 89.3%. The authors concluded that nasal EPAP significantly reduced the AHI and snoring and improved daytime sleepiness after 12 months of treatment. Long-term compliance was deemed excellent.

Retrospective cases series analysis of a nasal expiratory positive airway pressure (EPAP) device to treat obstructive sleep apnea in a clinical practice.
Adams G. [SLEEP Abstract Supplement, 2011 (34):A146]^[36]

This retrospective analysis was completed to evaluate patient acceptance and AHI reduction using nasal EPAP in a real world clinical practice. OSA patients (with AHI > 10) received 10 nights of sample EPAP devices for in-home evaluation. Patients that acclimated returned for efficacy confirmation using standard in lab PSG. During these treatment PSGs, adjunctive therapy such as positional therapy or chin straps was used, when necessary, to optimize treatment effect. 151 patients sampled nasal EPAP and 131 were in the analysis group. Of the analysis group, 75% acclimated to the device. The median AHI was reduced from 25.8 to 4.2 (p < 0.001). A treatment AHI < 10 was achieved in 80.7% of all patients and 90.6% of those with mild/moderate OSA. The author concluded that nasal EPAP achieved statistically significant improvements in AHI and that treatment acceptance was excellent.

Cited references

1. ↑ A Novel Non-Prescription Nasal EPAP Device (Theravent) to Treat Snoring by Rajiv Doshi, MD and Philip Westrbook, MD
2. 1 2 Patel AV, Hwang D, Masdeu MJ et al. Predictors of response to a nasal expiratory resistor device and its potential mechanisms of action for treatment of obstructive sleep apnea. J Clin Sleep Med 2011;7:13-22.
3. ↑ Colrain I, Turlington S. The use of a nasal resistance valve to treat sleep disordered breathing. SLEEP Abstract Supplement. 2008;31: A172.
4. ↑ CW Braga, Q Chen, O Burschtin, et al. Imaging of FRC and upper airway dimensions by MRI during application of nEPAP in patients with SDB, 12th International Symposium, Sleep and Breathing, Barcelona, Spain April 2011.
5. ↑ Berry RB, Kryger MH, Massie CA. A novel nasal expiratory positive airway pressure device for the treatment of obstructive sleep apnea: a randomized controlled trial. SLEEP 2011;34:479-485.
6. ↑ Walsh JK, Griffin KS, Forst EH, et al. A convenient expiratory positive airway pressure nasal device for the treatment of sleep apnea in patients non-adherent with continuous positive airway pressure. Sleep Med 2011;12:147-52.
7. 1 2 Rosenthal L, Massie CA, Dolan DC, et al. A multicenter, prospective study of a novel nasal EPAP device in the treatment of obstructive sleep apnea. Efficacy and 30-day adherence. J Clin Sleep Med 2009;5:532-37.
8. 1 2 Colrain IM, Brooks S, Black J. A pilot evaluation of a nasal expiratory resistance device for the treatment of obstructive sleep apnea. J Clin Sleep Med 2008;4:426-33.
9. ↑ Kryger MH, Berry RB, Massie CA. Long term use of a nasal expiratory positive airway pressure (EPAP) device as a treatment for obstructive sleep apnea. J Clin Sleep Med 2011:7:5:449-453.
10. ↑ Adams, G, Retrospective cases series analysis of a nasal expiratory positive airway pressure (EPAP) device to treat obstructive sleep apnea in a clinical practice, SLEEP Abstract Supplement, 2011 (34):A146.
11. ↑ Hwang D, Becker K, Chang J et al.Nasal EPAP as a major therapeutic option in a clinical sleep center setting, SLEEP Abstract Supplement, 2011 (34):A146.
12. ↑ Massie C, Hart RW. Clinical efficacy of a nasal expiratory positive airway pressure (EPAP) device for the treatment of obstructive sleep apnea, SLEEP Abstract Supplement, 2011 (34):A146.
13. ↑ George CF. Sleep apnea, alertness, and motor vehicle crashes. Am J Respir Crit Care Med 2007;176(10):954-956.
14. ↑ Sassani A, Findley LJ, Kryger M et al. Reducing motor-vehicle collisions, costs, and fatalities by treating obstructive sleep apnea syndrome. SLEEP 2004;27:453-158.
15. ↑ Smith R, Ronald J, Delaive K et al. What are obstructive sleep apnea patients being treated for prior to this diagnosis? Chest 2002;121:164-172.
16. ↑ Yaggi H, Concato J, Kernan W et al. Obstructive sleep apnea as a risk factor for stroke and death. N Engl J Med 2005; 353: 2034-2041.
17. ↑ Gami A, Howard D, Olson E, et al. Day-night pattern of sudden death in obstructive sleep apnea. N Engl J Med 2005;352:1206-1214.
18. ↑ Nieto FJ, Young TB, Lind BK et al. Association of sleep-disordered breathing, sleep apnea, and hypertension in a large community-based study. Sleep Heart Health Study. JAMA. 2000;283(14):1829.
19. ↑ Weaver TE, Grunstein RR. Adherence to continuous positive airway pressure therapy: the challenge to effective treatment. Proc Am Thorac Soc. 2008;5(2):173.
20. ↑ Berry RB, Kryger MH, Massie CA. A novel nasal expiratory positive airway pressure device for the treatment of obstructive sleep apnea: a randomized controlled trial. SLEEP 2011;34:479-485.
21. ↑ 19. Ravesloot M, de Vries N. Reliable Calculation of the Efficacy of Non-Surgical and Surgical Treatment of Obstructive Sleep Apnea Revisited. SLEEP 2011;34(1):105-110.
22. ↑ Patient-Oriented Guide to Snoring by Mark Daniel Higgins and Sean Tolhurst
23. ↑ A Novel Non-Prescription Nasal EPAP Device (Theravent) to Treat Snoring by Rajiv Doshi, MD and Philip Westbrook, MD
24. ↑ A Novel Non-Prescription Nasal EPAP Device (Theravent) to Treat Snoring by Rajiv Doshi, MD and Philip Westbrook, MD
25. ↑ Morrell MJ, Arabi Y, Zahn B, et al. Progressive retropalatal narrowing preceding obstructive apnea. Am J Respir Crit Care Med. 1998;158:1974-1981.
26. ↑ White D. Auto-PEEP to treat obstructive sleep apnea. J Clin Sleep Med 2009; 6: 538-539.
27. ↑ Heinzer RC, Stanchina ML, Malhotra A, et al. Lung volume and continuous positive airway pressure requirements in obstructive sleep apnea. Am J Respir Crit Care Med 2005;172:114-7.
28. ↑ Patel AV, Hwang D, Masdeu MJ et al. Predictors of response to a nasal expiratory resistor device and its potential mechanisms of action for treatment of obstructive sleep apnea. J Clin Sleep Med 2011;7:13-22.
29. ↑ 23. Braga CW, Chen Q, Burschtin O, et al. Changes in lung volume and upper airway using MRI during application of nasal expiratory positive airway pressure in patients with sleep disordered breathing. J Appl Physiol 2011; 111:1400-1409.
30. ↑ Adams G, Hwang D, Skinger L, et al. Use of Nasal EPAP for the Treatment of Obstructive Sleep Apnea in Adult Patients: A Guide for Respiratory Therapists. Respiratory Therapy 2011; 6(5).
31. ↑ Rossi, V. A.; Winter, B.; Rahman, N. M.; Yu, L. -M.; Fallon, J.; Clarenbach, C. F.; Bloch, K. E.; Stradling, J. R.; Kohler, M. (2013). "The effects of Provent on moderate to severe obstructive sleep apnoea during continuous positive airway pressure therapy withdrawal: A randomised controlled trial". Thorax 68 (9): 854–859. doi:10.1136/thoraxjnl-2013-203508. PMID 23723343. 
32. ↑ Doshi R, Westbrook P. Nasal Expiratory Positive Airway Pressure (EPAP) for the Treatment of Obstructive Sleep Apnea: A Review of Clinical Studies of Provent Therapy. Respiratory Therapy 2011; 6(4).
33. ↑ Berry RB, Kryger MH, Massie CA. A novel nasal expiratory positive airway pressure device for the treatment of obstructive sleep apnea: a randomized controlled trial. SLEEP 2011;34:479-485.
34. ↑ Walsh JK, Griffin KS, Forst EH, et al. A convenient expiratory positive airway pressure nasal device for the treatment of sleep apnea in patients non-adherent with continuous positive airway pressure. Sleep Med 2011;12:147-52
35. ↑ Kryger MH, Berry RB, Massie CA. Long term use of a nasal expiratory positive airway pressure (EPAP) device as a treatment for obstructive sleep apnea. J Clin Sleep Med 2011:7:5:449-453.
36. ↑ Adams, G, Retrospective cases series analysis of a nasal expiratory positive airway pressure (EPAP) device to treat obstructive sleep apnea in a clinical practice, SLEEP Abstract Supplement, 2011 (34):A146.

Additional references

Hwang D, Becker K, Chang J et al.Nasal EPAP as a major therapeutic option in a clinical sleep center setting, SLEEP Abstract Supplement, 2011 (34):A146.

Mahadevia AK, Onal E, Lopata M. Effects of expiratory positive airway pressure on sleep-induced respiratory abnormalities in patients with hypersomnia-sleep apnea syndrome. Am Rev Dis 1983; 128:708-11.