4.4 Eustachian tube dysfunction and the C-tympanogram
A normal middle-ear cavity is at, or very near, atmospheric pressure. Atmospheric pressure is not constant — it falls about 1 kPa per 100 m of altitude, drops slightly with weather systems, and varies internally with the body’s gas-exchange activities. The middle ear’s role in maintaining its pressure-balance with the outside world is a small but persistent housekeeping task: the Eustachian tube opens transiently — typically with each swallow and yawn — to vent the small built-up pressure differentials. When this housekeeping fails, the middle-ear pressure drifts and the tympanogram shifts accordingly.
This lesson covers the physiology of middle-ear pressure regulation, the C-tympanogram that signals its failure, and how clinicians distinguish transient dysfunction from chronic disease.
The cycle of middle-ear pressure regulation
The middle-ear mucosa continuously absorbs gases — primarily oxygen and carbon dioxide — into the venous capillaries that line the cavity. The absorption is slow but inexorable: about 1 mL of mixed-air equivalent per day for an adult. Without compensation, the gas in the cavity would deplete and the pressure would drop linearly with the amount absorbed. The volume is fixed (the cavity walls don’t budge), so by the ideal gas law a drop in produces a proportional drop in at constant , .
The Eustachian tube — running from the front wall of the middle ear, anteromedially, down to the nasopharynx behind the soft palate — opens against muscle tension (tensor veli palatini, levator veli palatini, salpingopharyngeus) when we swallow. At each opening, the middle ear briefly equilibrates with nasopharyngeal pressure — which is, to within a fraction of a kPa, atmospheric. Roughly: 60–80 swallows per hour, of which a fraction successfully open the tube, comfortably replace the gas lost to absorption.
When this loop is interrupted — by mucosal swelling in a cold, by reduced muscular tone, by abnormal tubal anatomy, or by external pressure changes (a flight or scuba dive) faster than the tube can clear — the middle ear’s pressure drifts. At sufficient negative pressure (typically below −200 daPa), the eardrum is pulled inward and its operating compliance shifts — the type-C tympanogram results.
What the type-C tympanogram looks like
A type-C tympanogram has the shape of a normal type A — a clean bell-shaped peak of normal height — but the peak is displaced into the negative pressure region:
| Feature | Type A | Type C |
|---|---|---|
| Peak height | 0.3 – 1.4 mmho | 0.3 – 1.4 mmho (normal) |
| Peak pressure (TPP) | −100 to +50 daPa | < −100 daPa |
| Width / gradient | Normal | Normal |
| ECV | Normal | Normal |
The interpretation is direct: middle-ear pressure is below atmospheric by the magnitude of the peak shift. The audiogram in this state typically shows no loss, or a small (5–15 dB) low-frequency conductive loss as the stretched eardrum becomes less effective at transferring acoustic energy. The reflex thresholds are normal or slightly elevated. The patient often describes a “stuffy” or “full” sensation in the ear, and reports that swallowing or yawning provides intermittent relief.
Transient vs chronic dysfunction
The clinical question is not just “is there ET dysfunction” but is it transient or chronic, and does it predict middle-ear disease?
Transient dysfunction is overwhelmingly the most common cause of a type-C tympanogram in an otherwise asymptomatic patient. The most frequent triggers:
- Common cold or upper-respiratory infection. Mucosal swelling of the tubal opening prevents successful opening for the duration of the inflammation. Resolves within 1–3 weeks after the URI clears.
- Recent air travel. Cabin pressure typically equilibrates at 1800 m equivalent altitude, ~80 kPa, leaving the middle ear hypertensive on descent if the tube cannot vent quickly enough.
- Recent allergies (seasonal or environmental). Mucosal edema, similar mechanism to URI.
- Recent swimming in cold water. Caloric stimulus and reflex tubal closure.
Transient dysfunction does not require treatment — the standard recommendation is observation with follow-up tympanometry at 4–6 weeks if symptoms persist, or earlier if hearing is affected.
Chronic dysfunction is the worry. Persistent type-C tympanograms (3+ months) predict:
- Eventual progression to otitis media with effusion — the middle-ear absorption continues, mucosal transudate accumulates from the sustained negative pressure, and the tympanogram converts from type C to type B. This is the dominant pathway in pediatric otitis media: the eustachian tube in children is shorter, more horizontal, and less efficient than the adult’s, so transient dysfunction during routine URIs more often progresses to chronic disease.
- Atelectasis of the tympanic membrane (long-standing retraction stretches the drum, occasionally to the point of erosive contact with the ossicles).
- Cholesteatoma in extreme chronic retraction cases, where invaginated skin forms a keratin-filled cyst that erodes the ossicles and skull base.
The chronic-disease workup adds tympanostomy tube placement (especially in pediatric patients with three or more discrete episodes), otoscopic imaging, and increasingly Eustachian-tube balloon dilation in adult-onset chronic ET dysfunction.
The Valsalva and Toynbee manoeuvres
Two bedside tests probe Eustachian-tube function:
- Valsalva manoeuvre. The patient closes mouth and nose and exhales gently against the closed nasopharynx. A working ET will pop the middle-ear pressure positive and the tympanogram TPP shifts upward by 50–200 daPa.
- Toynbee manoeuvre. The patient swallows while pinching the nostrils. The closed nasopharynx draws a slight negative pressure as the soft palate descends, and a working ET will shift TPP downward.
Both manoeuvres are typically done with the probe in place, the patient performing the manoeuvre, and a second tympanogram taken immediately. A consistent shift in TPP (in the expected direction) verifies a patent ET; absence of shift suggests obstruction.
Closing the chapter
That closes Chapter 4. The arc: a single piece of hardware — a probe with a speaker, a microphone, and a pressure pump — produces two of the most diagnostically rich tests in audiology. The tympanogram (Lessons 4.1 and 4.2) localises pathology to specific anatomical structures within the middle ear in about a minute; the acoustic reflex (4.3) extends the diagnostic reach across the entire central auditory pathway from cochlea to brainstem; the type-C tympanogram and Eustachian-tube manoeuvres (4.4) characterise pressure regulation. Tympanometry’s combination of speed, objectivity, and diagnostic specificity is why it is the audiologist’s second test, immediately after the audiogram, in essentially every clinical workup.
The next chapter introduces the second great objective probe — the otoacoustic emission, a physical output of the healthy cochlea that we can record from a probe in the ear canal.
Next chapter: Ch 5 — Otoacoustic emissions.