S LEEP A PNEA

1. SLEEP APNEA Stephen A. Schendel, M.D., D.D.S. Richard L. Jacobson, D.M.D., M.S. Joseph A. Broujerdi, M.D., D.M.D. Prepared by Jenny R. Armstrong, B.A.

2. Stephen A. Schendel, M.D., D.D.S. • Surgical interests are craniofacial and maxillofacial surgery, including sleep apnea and orthognathicsurgery • Professor of Surgery Emeritus at Stanford University Medical Center and Lucile Packard Children’s Hospital EDUCATION AND TRAINING: • Graduate of University of Minnesota Dental School in 1973 • Residency at Parkland Memorial Hospital in Dallas • Studied as a Fulbright Fellow at the University of Nantes in France • Emphasis of cleft lip & palate surgery and dentofacial orthopedics under the tutelage of Dr. Jean Delaire • Graduate of University of Hawaii Medical School in 1983 • Assistant to Dr. Paul Tessier 1987 to 1988 in Paris, France • General Surgery internship at Baylor University Medical Center, Dallas • General Surgery and Plastic Surgery training at Stanford University Medical Center ACHIEVEMENTS: • Recipient of a Chateaubriand French Research Fellowship • Full-time faculty of the Division of Plastic and Reconstructive Surgery at Stanford University Medical School from 1989 until 2007 • Leader in the field of distraction osteogenesis for the correction of facial deformities. • Board-certified in Oral and Maxillofacial Surgery and Plastic Surgery • Fellow of the American College of Surgeons • Fellow in the American Academy of Pediatrics • Former President of the American Society of Maxillofacial Surgeons • Former board member of the American Society of Plastic Surgeons from 1992 to 2002 • Former Chief of Plastic Surgery at Stanford University Medical Center and Chief of Pediatric Surgery • Chairman of the Department of Functional Restoration from 1994 to 2001 • Director of The Craniofacial Anomalies Center at Lucile Packard Children’s Hospital from 1994-2007 • Full-time faculty of the Division of Plastic and Reconstructive Surgery at Stanford University Medical School from 1989 until 2007 PUBLICATIONS • He has published over 100 articles and chapters including a textbook on maxillofacial surgery.

3. Richard L. Jacobson, D.M.D., M.S. • Board certified orthodontist practicing in Pacific Palisades for 30 years • Additional areas of interest and expertise include orthognathic surgery and temporomandibular joint disorders • Part-time instructor at UCLA School of Dentistry Department of Orthodontics EDUCATION AND TRAINING: • UCLA School of Dentistry Department of Orthodontics 1981 • M.S. in Oral Biology UCLA 1979-1983 TMJ Department • American Institute of Bioprogressive Education • Mentored by Robert M. Ricketts, D.D.S., M.S., and Tom Graber, D.D.S., M.S, PhD. SERVICE • Director of the Foundation for Orthodontic Research and Education 1990-2000, elected President in 2000 • Director of the Western Orthogmorphic Diagnostic team • Service on the UCLA/St. John's Cleft Palate and Craniofacial Team • President of the UCLA Orthodontics Alumni Association 1985, 2001 • Reviewer for the American Journal of Orthodontics and World Journal of Orthodontics (2011) • International Review Board approval for an airway study on 1300 patients (May 2011) PUBLICATIONS • Textbook: Radiographic Cephalometry: From Basics to 3-D (Quintessence) • American Journal of Orthodontics, Journal of Clinical Orthodontics, Journal of Oral and Maxillofacial Surgery

4. Joseph A. Broujerdi, M.D., D.M.D. • Dual training in Plastic & Reconstructive surgery and Oral & Maxillofacial Surgery • Sub-specialty and surgical interests: Cranio-Maxillofacial Surgery and Surgical Treatment of Sleep Disorders EDUCATION AND TRAINING: • Graduate of the University of Pennsylvania School of Dental Medicine • Craniofacial/Pediatric Plastic Surgery fellowship at Stanford University Medical Center, Lucile Packard Children’s Hospital • Plastic & Reconstructive Surgery at Wayne State University/Detroit University Medical Center • General Surgery and Oral & Maxillofacial Surgery at SUNY Downstate/Kings County Hospital Center ACHIEVEMENTS: • Recipient of Henry M. Goldman award from the University of Pennsylvania PUBLICATIONS: • Dr. Broujerdi has written many papers covering new developments in the field of Plastic & Reconstructive Surgery, contributed to peer-reviewed journals, and co-authored a book chapter on Maxillofacial Surgery. He has given presentations and spoken at national and international conferences.

5. Relevant Terminology

6. EPIDEMIOLOGY

7. Epidemiology of Snoring • Affects 90 million adults in the USA • 37% of adults self-report snoring a few nights a week in previous year • 27% of adults self-report snoring every night • Studies indicate that a more reasonable estimate is 50% of adults snore • Men slightly more likely to snore than women National Sleep Foundation, 2002. Sleep in America. www.sleepfoundation.org, 4 May 2011 Powell N., Riley R., Schendel S. California Sleep Institute, 2009. www.calsleep.com, Snoring. 4 May 2011

8. Epidemiology of UARS • No gender bias • Non-obese (BMI <25) • Younger patient • Mean age 37.5 years Guilleminault C., Takaoka S. 2009, Signs and Symptoms of Obstructive Sleep Apnea And Upper Airway Resistance Syndrome. Friedman M., ed. Sleep Apnea and Snoring: Surgical and Non-Surgical Therapy, Saunders Elsevier, Chicago, p 3-8.

9. Epidemiology of Sleep Apnea • 2-5% of the population • 18 million people in the USA • More males than females until menopause • 25% of adult men • 9% of adult women • Typically presents between ages of 40-60 • 1/3 of those with OSA have cases severe enough to warrant immediate treatment Stevens, Damien R. Sleep Medicine Secrets. Hanley & Belfus, Inc.: Philadelphia, 3004. p 3 Powell N., Riley R., Schendel S. California Sleep Institute, 2009. www.calsleep.com, Snoring. 4 May 2011

10. Epidemiology of Sleep Apnea Friedman et al, 2009. pp 3, 51.

11. Epidemiology of Sleep Apnea: Women National Sleep Foundation, Women and Sleep. http://www.sleepfoundation.org/article/sleep-topics/women-and-sleep 4 May 2011

12. Symptoms Friedman et al, pp 1

13. Non-Specific Symptoms: Women Friedman et al, pp 8

14. Epidemiology of Sleep Apnea

15. Epidemiology of Sleep Apnea: Medical Complications

16. ANATOMY

17. AirwayAnatomy

18. Airway Anatomy Friedman et.al, 2009. pp 96

19. Anatomy: Nasopharynx

20. Anatomy: Nasopharynx • Airflow of Inspiration • Parabolic curve • directed superiorly through the nostril • Up through the nasal cavity passing the turbinates • Posteriorly passes through the nasopharynx

21. Anatomy: Internal Nasal Valve • 4 structures • SUPERIOR: Upper lateral cartilage • MEDIAL: Nasal septum • INFERIOR: Pyriform aperture • POSTERIOR: Head of inferior turbinate • Narrowest part of the nasal passage • Source of nasal resistance • Narrowest portion of IV is region between septum and near the posterior border of the upper lateral cartilage • 10-15 degrees in Caucasians • Wider in African Americans and Asians • IV angles < 10 degrees more prone to nasal valve collapse Friedman et.al, 2009. pp 120

22. Anatomy: Turbinates • Filter and heat air from 0 to 36 and humidify it • Special air flow receptor cells on surface of inferior turbinates • Secretes mucous that keeps nose moist and limits drying Friedman et.al, 2009. pp 120

23. Anatomy: External Nasal Valve • Nares • Alar margin • Soft tissue triangle • Columella • Nasal sill • Nasal vestibule • Inside the external naris • Septum and Columella are located medially • Alar sidewalls are lateral to the vestibule • Vibrissae • Located within vestibule • Filter air • Direct air posteriorly into nasal cavity • Limit rate of inspired air Friedman et.al, 2009. pp 120

24. Anatomy: Nasal Musculature • Elevator muscles • Procerus • Levatorlabiisuperiorisalaequenasi • Anomalusnasi • Depressor muscles • Alar nasalis • Depressor septinasi • Compressor muscles • Transverse nasalis • Compressor nariummino • Dilator muscles • Alar muscles • Dilate the IV to keep the lumen open

25. Airflow: Nasal Structures • IV and EV function together to deliver smooth air current • Inspiration: • Nostrils flare • EV is increased • Bernoulli Principle • Intraluminal pressure in the IV decreases when airflow is increased • cartilage in nose counterbalances tendency towards IV collapse • IV area should remain unchanged during normal nasal function

26. Normal nose contributes to 50% of upper airway resistance Causes for Nasal Obstruction 3 Causes

27. Structures of the Nose Often indicating nasal Obstruction

28. Anatomy: Oropharynx & Hypopharynx

29. Anatomy: Retropalatal Space • Hard Palate • Bony structure • Separates nasal and oral cavities • Occupies 2/3 of total oral palate • Soft Palate • Occupies 1/3 of total oral palate • Uvula • Prevents air escape into nasal cavity during speech • secretes mucus for swallowing and digestion • prevents choking and regurgitation of liquids • controls gag reflex • prevents passage of food/liquids into nasal passages • Tongue

30. Anatomy: Palate • Soft Palate • Fibromuscular tissue • Separates oral and nasal cavities • Ends posteriorly with the uvula • Musculature: • Levatorvelipalatini • Tensor velipalatini • Palatopharyngeus • Musculus uvulae • Palatoglossus • Nerve • Pharyngeal Plexus • CN V2 • Function: • Mucous secretion • Prevents regurgitation of food into nasal cavity

31. Anatomy: Retroglossal Space • Epiglottis • Base of Tongue • Hyoid • Genioglossus, geniohyoid, and middle pharyngeal constrictor muscles insert on hyoid bone • Tonsils • Mandible • Genioglossus

32. Causes of Potential Airway Obstruction • MOST COMMON CAUSE IS ANATOMIC ABNORMALITY LEADING TO OBSTRUCTION

33. Major Sites of Potential Airway Obstruction • Nose • Septum • Nasal valve • Turbinate • Polyp • Palate • Oropharynx • Tonsils • Lateral pharynx • Tongue • Mandible • Hyoid • Epiglottis

34. Sleep Architecture • Sleep Stages: • REM – Rapid Eye Movement • 20-25% of total sleep time • Memorable dreaming occurs as well as atonia • NREM – Non-Rapid Eye Movement • 3 Stages: • N1 • Somnolence • Sudden twitches/jerks can occur with onset of sleep • Loss of muscle tone • N2 • Muscular activity decreases • Awareness of external environment disappears • 45-55% of total sleep in adults • N3 – Delta Sleep or Slow-Wave Sleep • Parasomnias occur • NREM-REM Cycle • N1  N2  N3  N2  REM • Each cycle lasts from 90 to 110 minutes on average • Deep sleep is stage N3 and occurs earlier in cycle • REM is later in sleep cycle before awakening

35. DIAGNOSTICS

36. Diagnosing Sleep Apnea in our Practice

37. Clinical Examination

38. Clinical Examination: BMI

39. Clinical Examination: Nasopharynx

40. Clinical Examination: Nasopharynx

41. Clinical Examination: Oropharynx and Hypopharynx

42. Clinical Examination: Tongue Size • Mallampati Position of Tongue • Based upon patient sticking tongue out • 3 grades • Friedman Tongue Postions (FTP) • Method to approximate obstruction at hypopharyngeal level • Evaluate tongue in neutral, natural position inside mouth • Repeat procedure 5 times • 5 Positions • I – Tonsils, Uvula, Pillars • IIa– Uvula • IIb – Most of soft palate, base of uvula • III – Some of soft palate • IV – Only hard palate Friedman et al., 2009, pp 106

43. Clinical Examination: Tonsil Size • 0 – surgically absent • 1 – less than 25% • hidden within pillars • 2 – 25-50% • extending to pillars • 3 – 50-75% • Extending beyond pillars • 4 – 75-100% • Extending to midline

44. Clinical Examination: OSAHS Score Friedman et al., 2009, pp 109 • INTERPRETING RESULTS • >8 Positive OSAHS • 74% effective in predicting severe OSAHS (AHI >45) • <4 Negative OSAHS • 67% effective in predicting AHI <20

45. Clinical Examination: Craniofacial Characteristics

46. Clinical Examination: Epworth Sleepiness Scale (ESS)

47. Clinical Examination: Epworth Sleepiness Scale (ESS)

48. Clinical Examination: Mueller Maneuver • THERE IS SOME EVIDENCE THAT • MUELLER MANEUVER DOES NOT REFLECT ACTUAL SITES OF OBSTRUCTION DURING SLEEP Friedman et al., 2009, pp 104, 224

49. Upper Airway Analysis

50. Historically: 2-D Cephamalometric Analysis • Standardized lateral x-ray of H&N for skeletal and soft tissue assessment • Multiple bony and soft tissue measurements • Skeletal Class I, II, III • Good estimate of A-P dimension • No estimate of transverse dimension • Performed upright when patient is awake • muscles are active • Head position is different than when resting • may underestimate degree tissue falls