Unilateral Sensorineural Hearing Loss


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Introduction
• What dilemmas?
– Increasing number and complexity of tests
– Increasing costs of medical care
– What do tests results mean?
– At what point does cost of testing outweigh value of “rule out” diagnosis?
– How far do we go to diagnose etiology?
  
Overview
• Diagnosis of the following:
– Unilateral Childhood SNHL of unknown duration
– Sudden sensorineural hearing loss
– Unilateral inner ear complaints

Unilateral Childhood SNHL
• Unilateral SNHL in moderate to profound range correlates with:
– Poor academic performance
– Increased chance of repeating a grade
– Behavioral problems
Intervention prior to 6 months results in advantages in communication

• Universal infant screening has led to earlier diagnosis
• Congenital hearing loss may be delayed
• Joint Committee on Infant Hearing guidelines for persistent periodic screening:
– Child with family history of early onset SNHL
– Prenatal infection that may lead to SNHL
– Neurofibromatosis II
– Persistent pulmonary hypertension 

• Epidemiology
– Average age of diagnosis unilateral SNHL is 8.7 yo.
– Bilateral SNHL grater than 50dB, 1-2/1000
– Unilateral SNHL greater than 50 dB, 3/1000
– Genetic cause in 50% of individuals



• Initial referral because of failed audiogram, parental concerns.
• Confirmed with audiogram, OAE, ABR
• In younger children, otolaryngologist must screen for conductive etiology


• Differential diagnosis
– Syndrome with hearing loss
– Other genetic cause
– Meningitis
– Intrauterine infection
– Trauma to cochlea, vestibule, VIII
– Exposure to ototoxic drug
– Prematurity
– Autoimmune disease
– Hyperbilirubinemia
– Neurofibromatosis type II
– Anoxic Brain injury
– Mumps
– Neurodegenerative disorder
– Malignant infiltration
– Ischemic insult of cochlea
– Cochlear hydrops





• Genetic basis in 50%
– Over 200 syndromes include deafness or hearing impairment
– Identification of syndrome allows efficient screening for other anomalies


• Usher syndrome
– Autosomal recessive disorder
– Retinitis pigmentosa and SNHL
– Early intervention for future visual and auditory impairment
– Bilateral cochlear implant should be considered


Waardenburg syndrome
– SNHL
– White forelock
– Multicolored iries
– Dystropia canthorum
– hypertelorism





• Jervell and Lange-Nielsen
– Autosomal dominant
– Seen in 1.6 to 6 per million
– Prolonged QT interval and increased risk of sudden death
– First degree relatives need screening with EKG


• Neurofibromatosis Type II
– Autosomal dominant
– Bilateral acoustic neuromas
– Meningiomas
– Spinal schwannomas
– Posterior capsular lens opacities

• Alports syndrome
– Autosomal dominant or recessive, or x-linked
– Slowly progressive bilateral SNHL, can be asymmetrical
– Progressive renal failure
– Persistent microscopic hematuria
– Episodic gross hematuria precipitated by URI



• Branchio-oto-renal syndrome
– 1/40,000 live births
– 60% with branchial cleft cysts
– 20% with pure SNHL, majority mixed
– Shared antigen between the stria vascuularis and glomeruli

• Noonan’s syndrome
– 1/2500 live births
– Webbed neck
– Pinna abnormalities
– Short stature
– 10-15% with SNHL

• CHARGE Syndrome
– Coloboma
– Heart Defects
– Atresia choanae
– Retarded growth
– Genital hypoplasia
– Ear abnormalities and deafness
– Associated with Mondini malformation

• Fechner’s syndrome
– High frequency SNHL
– Proteinuria
– Macrothrombocytopenia
– Ocular disease
– Extremely rare

• Pendred syndrome
– Autosomal recessive
– Congenital SNHL
– Goiter
– Hypothyroidism (varies)
– Abnormal perchlorate discharge test
– Associated with Mondini and Large Vestibular aqueduct

• Other causes
– TORCHS (Toxoplasmosis, Others, Rubella, Cytomegalovirus, Herpes simplex, Syphilis)
– Meningitis
– Ototoxic drug exposure
– Maternal drug alcohol use
– Maternal use of teratogenic drug (thalidomide)


Diagnostic Testing
• CBC with Differential
• Platelet studies
• ANA, ESR, RF
• BUN, Creatinine, Urinalysis
• Serum glucose
• Thyroid function tests, Perchlorate test
• RPR, TTPA
• GJB2 (Connexin 26)
• EKG
• CT, MRI

• CBC with differential
– Used to screen for leukemia or lymphoma
– Hearing loss due to hyperviscosity or temporal bone infiltration
– 1 case of leukemia with hearing loss as initial manifestation in literature
– Low yield

• Platelet studies
– Drawn to exclude Fechner syndrome
– Patients with family history, ocular disease, history of diagnosed proteinuria should be screened
– Test is low yield

• ANA, ESR, RF
– Drawn to screen for autoimmune disorders, Lupus, Cogan's, juvenile rheumatoid arthritis
– Test nonspecific
– Positive RF is 0.7% sensitive in detecting juvenile RA
– Testing without history of joint pain or other signs of systemic autoimmune disorders is low yield

• BUN, Creatinine, Urinalysis
– Used to screen for concurrent kidney disease such as Alport’s disease
– Should be drawn with history of gross hematuria, family history of kidney disease, family history of slowly progressive hearing loss
– Routine screening is low yield

• Serum glucose
– Used to screen for Alston syndrome (Impaired glucose tolerance, retinal degeneration, neurosensory deafness, acanthosis nigricans, hepatic dysfunction)
– Only 50 cases reported since 1959
– Very low yield

• Thyroid function testing
– Drawn to screen for hypothyroidism and Pendred syndrome
– Hearing loss as a sole symptom of hypothyroidism is very rare
– Pendred syndrome not always associated with hypothyroidism. Perchlorate testing test of choice
– Testing highest yield in children with goiter, signs of hypothyroidism, large vestibular aqueduct or Mondini malformation

• RPR, TTPA
– Drawn to look for syphilis.
– Hearing loss with tertiary syphilis usually associated with other manifestations of the disease, but can be sole manifestation
– History of maternal syphilis exposure, signs of tertiary syphilis make testing higher yield
– Testing low yield

• EKG
– Used to screen for prolonged QT interval in Jervall and Lange-Nielson syndrome
– Test highest yield with family history of childhood death or syncope
– Low yield

• GJB2 gene (Connexin 26)
– Responsible for as much as 50% of autosomal recessive nonsyndromic hearing loss
– Use most important in genetic counseling for parents of hearing impaired children
– Homozygous children have a 25% chance of having siblings with hearing loss. Negative or heterozygous results gives siblings 14% chance

• CT and MRI
– Used to scan for inner ear malformations
– Mondini malformation associated with perilymphatic fistulas and recurrent meningitis
– Large vestibular aqueduct associated with hearing loss as a result of minor head trauma
– MRI used for screening for acoustic neuroma in children with neurofibromatosis type II
Mafong et al, Laryngoscope 2002
• Retrospective chart review 114 children with SNHL
• ANA, RF, ESR, CBC, Platelet studies, BUN, Creatinine, Urinalysis, Serum Glucose, FT4, TSH, T3, FTA-ABS, RPR, EKG, CT scans reviewed
• EKG positive in 1 of 15 patients tested.
• ESR and ANA were positive in 22% of patients. No correlation with clinical disease. Occasional nonspecific abnormalities in CBC.
• All other laboratory testing negative.
• CT scan
– 39% with abnormality
– Large vestibular aqueduct in 13%
– Cochlear dysplasia in 7%
– MRI added to diagnosis in 4, one of which related to hearing loss (fistulous connection from IAC to temporal bone)
• Authors concluded that routine laboratory evaluation should be reconsidered given its low diagnostic yield
• They supported routine use of EKG and CT scan.

Conclusions
• EKG – sudden childhood death
• CT – High incidence of abnormality
– Large vestibular aqueduct – avoid contact sports
– Used for preoperative information should bilateral SNHL develop
– Mondini malformation lead to further testing
• Syphilis
– Rare without classical stigmata (interstitial keratitis, Hutchinson’s teeth, mulberry molars, bilateral painless knee effusions, nasal septal perforation, saddle nose deformity)
– Simple treatment, potentially fatal
– Recommend testing with RPR, confirmation with TTPA
• GJB2 (Connexin 26)
– Screening only if result will affect future childhood planning
– Genetics consult warranted for counseling of results
- Fever or illness more than 3 weeks, gingival bleeding, bone or joint pain, signs of autoimmune disease, order CBC and ANA, ESR, RF
- Family history of progressive early onset hearing loss in first or second degree relative, order urinalysis, genetics consult
• Family history of progressive vision loss or visual complaints, order ophthalmology consult
• History of hematuria or family history of kidney failure, order urinalysis. If urinalysis positive order BUN, creatinine
• Thyroid goiter, signs of hypothyroidism, Mondini malformation, large vestibular aqueduct by CT scan, order thyroid function test, consider perchlorate test
• History of frequent urination, excessive thirst, order serum glucose
• History of progressive hearing loss, gait or vestibular symptoms, focal neurological symptoms, order MRI of brain and IAC’s
• History of neurofibroma, meningioma, glioma, schwannoma, juvenile posterior subcapsular lenticular opacity or family history of Neurofibromatosis type II, order MRI of brain and IAC’s.
Sudden Sensorineural Hearing Loss
• Incidence estimated between 5 and 20 per 100,000
• Most common between ages of 40 and 54
• Loss of at least 30dB in 3 contiguous frequencies in 72 hours or less
• 65% diagnosed will spontaneously recover within 20dB or greater than 50% of total loss

Sudden Sensorineural Hearing Loss
• Etiology
– Vascular compromise from hyperviscosity, embolic event, vasospasm.
– Intracochlear membrane rupture or perilymph fistulas
– Viral infection
– Autoimmune inner ear disease, systemic autoimmune disease (Cogan’s, Wegner’s, polyarteritis nodosa, temporal arteritis, Berger's, SLE)

• Diagnostic testing
– CBC
– ESR, ANA, RF
– Serum Glucose
– T3, T4, TSH
– PT, PTT
– RPR, TTPA
– HIV
– Lyme titer
– Cholesterol/Triglycerides
– Anti-hsp 70 (68KD heat shock protein)
– MRI
Sudden Sensorineural Hearing Loss
• CBC
• ESR, ANA, RF
• Serum Glucose
• Thyroid function studies
• RPR, TTPA
• PT, PTT
– Used to look for hemorrhagic etiology of SSNHL
– Patients likely to have other manifestations of coagulopathy
– Higher yield if patient currently on an anticoagulant
• HIV
– Shown to decrease hearing in up to 30% of patients with active infection compared to controls.
– Literature shows 3 cases of SSNHL with positive HIV
– Low yield
– HIV treatment early improves life expectancy
• Lyme titer
– No literature case reports of Lyme disease as an etiology
– Recent history of tick exposure
– Low yield
• Gagnebin 2000 (French study)
– Analyzed screening HIV, Lyme, syphilis
– 102 charts reviewed
– Two patients with positive Lyme titers, not responding to treatment
– All HIV negative
– Latent syphilis without signs of neurosyphilis in one patient
– Concluded screening is low yield without history
• Anti-hsp70 (68KD heat shock protein)
– Thought to be a marker of autoimmune inner ear etiology
– Early studies have shown steroid responsiveness in patients with positive tests
– Samuelsson screened 27 with SSNHL and 100 controls. 19% and 14% respectively (not significant)
– Yeom in 2003 tested for anti-hsp 70 in 20 patients with rapidly progressive SNHL and 20 controls. No significant difference
• Anti-hsp70 (68KD heat shock protein)
– Testing is high yield
– Question as to validity of results
– Question of utility of positive results
(most patients treated with steroids)
• Cholesterol and Triglycerides
– Labyrinthine artery atherosclerosis as an etiology
– Friedrich – 49 patients with neurootologic symptoms. Increased LDL and LDL/HDL ratio as compared to controls
– Nuti – No significant difference in cholesterol and LDL/HDL ratio with controls

• Cholesterol and Triglycerides
– Ullrich – tested lipids and triglycerides in 24 patients with SSNHL. No significant difference from controls
– Kojima – 12 patients with SSNHL
• Event was at least 1 month prior study
• Patients with total cholesterol greater than 230mg/dL treated with diet and medications
• Significant improvement in 125-2000 Hz
– American College of Physicians recommends screening for lipid abnormalities in men 35-65 and women 45-65 years of age using total cholesterol level only.
– Cholesterol or triglyceride levels as an etiology of SSNHL likely low probability
– Testing in this age range is high yield

• MRI
– Used to screen for acoustic neuroma
– Patients with acoustic neuroma present with SSNHL 10% of the time
– As high as 2.5% of all patients with SSNHL have an acoustic neuroma
– Able to screen for acoustic neuroma and other causes of hearing loss
– Aronzon – treated patients with SSNHL and MRI proven acoustic neuroma with high dose of steroids
• Improvement in hearing of all patients
• Response to steroids does not exclude acoustic neuroma
Conclusions
• All patients should be screened with RPR, confirmed with TTPA (treatable, life threatening, low cost)
• MRI in all patients, regardless of response to steroids
• Total cholesterol in men aged 35-65, women aged 45-65 if no testing in the last year
Conclusions
• HIV testing in all patients with high risk of STD, +/- in all patients
• ESR, ANA, RF in patients with history and physical findings of autoimmune etiology, response to steroid, but relapse after taper
Sudden Sensorineural Hearing Loss
• CBC, Thyroid function tests, PT, PTT, Lyme titers based on history or physical exam findings only
• 68 KD protein in research settings, +/- in response to steroids with relapse after steroid taper
Acoustic Neuroma
• 12 per million per year
• MRI can detect tumors as small as 3mm
• Gold standard for diagnosis is MRI of IAC’s with gadolinium
• Test cost at this institution is $3200 

Acoustic Neuroma
• ABR
– Alternative to MRI for diagnosis
– MRI generally 5 times more expensive than ABR
– Decreased sensitivity
– Cost at this institution is $500
• Sensitivity of ABR
– Wilson 1992 – sensitivity of 85%, 67% for small tumors
– Chandrasekhar 1995 – sensitivity of 92%, 83% for small tumors
– Gordon 1995 – sensitivity 88%, 69% for small tumors
– Ruckershern 1996 – sensitivity of 63%, PPV 26%
• Robinette and Bauch
– Retrospective review to identify 95 patients with acoustic neuromas
– Divided into 3 groups
• High risk – asymmetric hearing loss of greater than 20 DB over three frequencies, greater than 30% decrease of word recognition
• Intermediate risk – SSNHL or unexplained persistent unilateral tinnitus
• Low risk – isolated vertigo or historically explained intermittent tinnitus or historically explained SNHL
• Used probability of acoustic in each group as (30%, 5%, 1%)
• Sensitivity of detecting tumors with ABR based on size (100% large, 93% medium, 82% small)
• Used PPV of 12% in ABR
• Calculated cost of MRI for patients in each group
• Calculated cost of ABR, and MRI for all ABR’s suggestive of acoustic neuroma
• Calculated cost difference of two groups based on risk from history and physical
• Calculated number acoustic neuromas missed if first screened with ABR
• High risk - $40,000, no missed tumors
• Intermediate risk - $900,000, clinician would miss 4 tumors in 900 patients screened
• Low risk – $1.7 million, 1 tumor missed out of 1600 screened
• Authors recommended clinical decision making with consideration of cost savings in intermediate to low risk groups

Conclusion
• MRI in:
– All patients with unilateral SNHL greater than 20dB difference from unaffected side not explained by history
– Word discrimination difference of 30% or greater from asymptomatic side
• MRI
– Unilateral persistent tinnitus not explained by history
– Persistent vertigo
– Unilateral sudden SNHL, regardless of response to steroids

• ABR vs. MRI
– Historically explained unilateral tinnitus
– Historically explained hearing loss
– Isolated vertigo

Summary
• Number of diagnostic tests expanding
• Physicians asked more and more to evaluate medical necessity and cost benefit of diagnostic testing
• Research projects based on cost analysis
• Balance of cost containment and diagnostic accuracy

Jacques Peltier, MD
Francis B. Quinn, Jr., MD
University of Texas Medical Branch