阅读说明：本技术 声学耳镜 (Acoustic otoscope ) 是由 马克·A·默林 杰依·A·车萨伟杰 王魏刚 崔东浩 于 2018-09-19 设计创作，主要内容包括：声学耳镜可以包括窥器尖端,所述窥器尖端用于耦合至耳道；激励源,所述激励源用于生成动态体积或压力,所述激励源动态体积或压力耦合至所述窥器尖端,所述激励源响应于输入控制；压力传感器,所述压力传感器用于估计所述窥器尖端中的压力并返回一系列测量值；以及控制器,所述控制器耦合至所述激励源输入控制并且还耦合以接收压力传感器测量值。(The acoustic otoscope may include a speculum tip for coupling to an ear canal; an excitation source for generating a dynamic volume or pressure coupled to the speculum tip, the excitation source being responsive to an input control; a pressure sensor for estimating the pressure in the speculum tip and returning a series of measurements; and a controller coupled to the excitation source input control and further coupled to receive pressure sensor measurements.)

1. An acoustic otoscope comprising:

a speculum tip for coupling to an ear canal;

an excitation source for generating a dynamic volume or pressure coupled to the speculum tip, the excitation source being responsive to an input control;

a pressure sensor for estimating the pressure in the speculum tip and returning a series of measurements;

a controller coupled to the excitation source input control and further coupled to receive pressure sensor measurements;

the controller thereby generating the stimulus source input control and in response acquiring a series of associated pressure measurements;

the controller forming a series of differences by subtracting the scaled pressure measurement output from the excitation input;

deriving an exudate metric from the series of differences, and the exudate metric having an increased exudate metric value in at least one of:

the series of differences has an increasing magnitude of difference with a step change in pressure or volume compared to a subsequent difference;

the series of differences has an elevated difference magnitude for the low frequency pressure or volume excitation compared to the difference magnitude for the high frequency pressure or volume excitation.

2. An acoustic otoscope as recited in claim 1, wherein said scaled pressure measurements use a scaling factor that causes a midpoint value of said pressure measurements to be substantially equal to said excitation source midpoint input value.

3. The acoustic otoscope of claim 1, wherein the excitation source input waveform is sinusoidal.

4. The acoustic otoscope of claim 1 wherein the excitation source input waveform is trapezoidal.

5. An acoustic otoscope as recited in claim 1, wherein said series of differences are averaged over at least 4 acquisition cycles.

6. An acoustic otoscope as recited in claim 3, wherein said sinusoidal excitation source input waveform and pressure sensor measurement waveforms are acquired at a number of frequencies to determine corner frequencies.

7. The acoustic otoscope of claim 5, wherein the exudate metric is generated by comparing the corner frequency to a threshold frequency for a normal tympanic membrane, viral fluid adjacent to the tympanic membrane, and mucoid fluid adjacent to the tympanic membrane.

8. The acoustic otoscope of claim 1, wherein the excitation source comprises a movable diaphragm, a movable piston, or a differential pressure source coupled to a speculum tip through a hose.

9. The acoustic otoscope according to claim 1, wherein said excitation source comprises a diaphragm or a piston enclosed in said speculum tip or speculum tip holder.

10. An acoustic otoscope as recited in claim 1, wherein said excitation source is coupled to a source of higher or lower air pressure through one or more valves controlled by said excitation input.

11. An acoustic otoscope having:

a speculum tip having a seal for sealing an ear canal;

an excitation source that changes pressure or volume and is coupled to the speculum tip, the excitation source having an input;

a pressure sensor coupled to the speculum tip and providing a pressure measurement output;

a controller that generates an excitation source input waveform, the controller further coupled to the pressure sensor and receiving a pressure measurement output waveform;

the controller generates the excitation input source waveform and simultaneously compares the pressure measurements to the excitation waveform to form an exudate metric.

12. The acoustic otoscope of claim 11, wherein the excitation source causes at least one of a volume change or a pressure change.

13. An acoustic otoscope as recited in claim 11, wherein said excitation source is a moving diaphragm.

14. The acoustic otoscope of claim 11, wherein the exudate metric is a non-diagnostic speculum tip leak detection for at least one of:

a transfer function of pressure measurements to an excitation waveform below the first threshold;

a high frequency transfer function of pressure measurements to the excitation waveform is below the third threshold;

detecting a negative pressure response when the excitation source is a volume adjusting piston or diaphragm that returns to an original position;

no change in pressure measurement value is detected in response to the excitation waveform.

15. The acoustic otoscope of claim 11 wherein the volume excitation waveform is sinusoidal and the exudate metric is based on a frequency response functionWherein:

Δ p (f) is the pressure amplitude at a plurality of discrete frequencies;

Δ v (f) is the volume excitation amplitude at a plurality of discrete frequencies;

the corner frequency being when the response function is smaller than the value at higher frequenciesThe frequency f of time.

16. The acoustic otoscope of claim 11 wherein the volume excitation waveform is a trapezoidal waveform and the exudate metric is based on a difference between the volume excitation waveform and a pressure measurement waveform, wherein the pressure measurement waveform is scaled to a midpoint of the waveform.

17. An acoustic otoscope as recited in claim 16, wherein said midpoint is the earliest point in time at which the slope of the pressure measurement waveform changes to its initial value of 1/4 or less, or a half interval point, whichever occurs first.

18. The acoustic otoscope of claim 17 wherein the exudate metric is based on a maximum amplitude of the difference waveform before the midpoint.

19. A method for forming a exudate metric, the method operating on a speculum tip having an examination hole for coupling to an ear canal and tympanic membrane to be characterized, the speculum tip coupled to a pressure measurement sensor for measuring pressure in the speculum tip and a pressure excitation generator for regulating the pressure in the speculum tip, the method comprising:

forming a pressure stimulus coupled to the speculum tip;

measuring a pressure response;

determining, based on a transfer function of the pressure response to the pressure stimulus, at least one of:

pressure seal leakage;

a healthy tympanic membrane;

a tympanic membrane coupled to the aqueous fluid;

a tympanic membrane fluidly coupled to a relatively viscous bacteria.

20. The method of claim 19, wherein the determination is made based on comparing a first measurement of a healthy ear to another ear.

21. The method of claim 19, wherein the determination is based on a characterization of at least one of: the frequency response corner frequency, the time delay of the step response, or the coefficient is fitted to the parameters of the attenuation equation.

22. The method of claim 21, wherein the attenuation equation is

Or

Technical Field

The present disclosure relates to an otoscope (otoscope) for characterizing fluid on a proximal surface of a tympanic membrane in a mammalian ear. In particular, the present disclosure relates to viscosity measurement of fluids adjacent to the tympanic membrane by measuring time and frequency dependent displacement of the tympanic membrane in response to acoustic volume excitation applied to the ear canal.

Background

Acute Otitis Media (AOM) is a common disease of the inner ear involving tissue inflammation and fluid pressure impinging on the tympanic membrane. Acute otitis media may be caused by viral infection, otitis media caused by viral infection may usually resolve without treatment, or it may be caused by bacterial infection, otitis media caused by bacterial infection may develop and lead to hearing loss or other harmful and irreversible effects. Unfortunately, it is difficult to distinguish between viral or bacterial infections using currently available diagnostic devices, and the treatment approaches for two potential infections are very different. For bacterial infections, antibiotics are the first treatment of choice, whereas for viral infections, the infection tends to resolve itself and antibiotics are not only ineffective, but may also lead to antibiotic resistance, which reduces their effectiveness in treating subsequent bacterial infections. Accurate diagnosis of acute otitis media is important because AOM may be a precursor to chronic otitis media with effusion (COME), an indication of surgical drainage of exudates and insertion of a catheter in the tympanic membrane.

A definitive diagnostic tool for inner ear infections is myringotomy, an invasive procedure that involves incising the tympanic membrane, withdrawing fluid, and examining the exudate under a microscope to identify infectious agents in the exudate. This procedure is used only in severe cases because of complications resulting from it. This is a dilemma for medical practitioners because the prescription of antibiotics for viral infections is believed to lead to the evolution of antibiotic resistance in bacteria, which can lead to more serious consequences for the rest of the life, and there is no effective therapeutic result because the treatment of viral infectious agents with antibiotics is ineffective. There is a need for improved diagnostic tools for diagnosing acute otitis media.

Object of the Invention

A first object of the invention is an apparatus for estimating the mobility of the tympanic membrane by introducing a volume displacement excitation into a sealed ear canal, the measurement of the tympanic membrane displacement being performed using a measurement pressure indicator in the tympanic membrane.

A second object of the present invention is a method for determining the viscosity of a fluid adjacent to the tympanic membrane by applying a volume displacement excitation and developing measurements of time and frequency domain characteristics of the pressure as an indicator of the tympanic membrane displacement.

A third object of the present invention is a device for characterizing fluid adjacent to the tympanic membrane, the device having a speculum tip for sealing the ear canal, a volume displacement source for changing the ear canal volume, and a pressure measurement for determining the effect of the displacement change on the measured external ear canal ear pressure, after which a exudate metric (metric) is generated based on the amplitude and phase of the pressure response in time or equivalently in frequency.

Disclosure of Invention

In one example, the controller is operable to vary the volume of air sealed to and coupled to the cavity of the ear canal. The change in volume of air coupled to the ear canal, referred to as av (t), is a function of time. A series of continuous or discrete pressure measurements are taken during the time interval in which the air volume change occurs and the air volume change is compared to the pressure measurements in at least one of the time domain response or the frequency domain response. In this way, the degree of displacement of the eardrum in response to changes in air volume may be determined and a viscosity metric may be developed. In alternative embodiments, a pressure regulator may be used that introduces or removes a fixed volume of air to increase or decrease the drum pressure.

In another example, a method for determining the presence or degree of acute otitis media has a cyclical volume displacement step whereby a chamber having a dynamically adjustable internal volume is coupled to a sealed ear canal, for example, by a speculum tip comprising a pressure measurement sensor, the method compares the volume change (as an excitation source coupled to the ear canal) with a pressure change measured in the ear canal (as a response), characterizes time domain static and dynamic responses to determine at least one of a frequency response or a time response of the tympanic membrane, maps a mobility metric from which the presence, absence or composition of fluid adjacent to the tympanic membrane can be determined.

Aspects of the present disclosure provide an acoustic otoscope. The acoustic otoscope may include a speculum tip for coupling to an ear canal; an excitation source for generating a dynamic volume or pressure coupled to the speculum tip, the excitation source being responsive to an input control; a pressure sensor for estimating the pressure in the speculum tip and returning a series of measurements; a controller coupled to the excitation source input control and further coupled to receive pressure sensor measurements; the controller thereby generating the stimulus input control and acquiring a series of associated pressure measurements in response thereto; the controller forming a series of difference values by subtracting the scaled pressure measurement output from the excitation input; deriving an exudate metric from the series of differences, and the exudate metric having an increased exudate metric value in at least one of: the series of differences has an increasing magnitude of difference with a step change in pressure or volume compared to a subsequent difference; the series of differences has a difference magnitude of the elevated low frequency pressure or volume excitation compared to a difference magnitude of the high frequency pressure or volume excitation.

In some embodiments, the scaled pressure measurements may use a scaling factor that causes a midpoint value of the pressure measurements to be substantially equal to the excitation source midpoint input value. In some embodiments, the excitation source input waveform may be sinusoidal. In some embodiments, the stimulus input waveform may be trapezoidal. In some embodiments, the series of differences may be averaged over at least 4 acquisition cycles. In some embodiments, the sinusoidal excitation source input waveform and pressure sensor measurement waveform may be acquired at several frequencies to determine a corner frequency (corner frequency). In some embodiments, the exudate metric may be generated by comparing the corner frequency to a threshold frequency for a normal tympanic membrane, viral fluid adjacent to the tympanic membrane, and mucoid fluid adjacent to the tympanic membrane.

In some embodiments, the excitation source may comprise a movable diaphragm, a movable piston, or a differential pressure source coupled to the speculum tip through a hose. In some embodiments, the excitation source may comprise a diaphragm or piston enclosed in the speculum tip or speculum tip holder. In some embodiments, the excitation source may be coupled to a source of higher or lower air pressure by controlling one or more valves by the excitation input.

Aspects of the present disclosure provide an acoustic otoscope. The acoustic otoscope may include a speculum tip having a seal for sealing off an ear canal; an excitation source that changes pressure or volume and is coupled to the speculum tip, the excitation source having an input; a pressure sensor coupled to the speculum tip and providing a pressure measurement output; a controller that generates an excitation source input waveform, the controller further coupled to the pressure sensor and receiving a pressure measurement output waveform; the controller generates the excitation input source waveform and simultaneously compares the pressure measurements to the excitation waveform to form an exudate metric.

In some embodiments, the excitation source may cause at least one of a volume change or a pressure change. In some embodiments, the excitation source may be a moving diaphragm. In some embodiments, after establishing the monotonic sequence of the first, second, and third thresholds, the exudate metric may be at least one of the following non-diagnostic speculum tip leak detections: a transfer function (transfer function) of the pressure measurement to the excitation waveform is below the first threshold; a high frequency transfer function of pressure measurements to the excitation waveform is below the third threshold; detecting a negative pressure response when the excitation source is a volume adjusting piston or diaphragm that returns to an original position; no change in pressure measurement value is detected in response to the excitation waveform.

In some embodiments, the volume excitation waveform may be sinusoidal and the exudate metric is based on a frequency response functionWherein: Δ p (f) is the pressure amplitude at a plurality of discrete frequencies; Δ v (f) is the volume excitation amplitude at a plurality of discrete frequencies; and the corner frequency is when the response function is smaller than the value at higher frequenciesThe frequency f of time. In some embodiments, the volume excitation waveform may be a trapezoidal waveform and the exudate metric is based on a difference between the volume excitation waveform and a pressure measurement waveform, wherein the pressure measurement waveform is scaled to a midpoint of the waveform. In some embodiments, the midpoint may be the earliest point in time among the points in time at which the slope of the pressure measurement waveform changes to its initial value of 1/4 or less, or the midpoint may be a half-spaced point, whichever occurs first in both the earliest point in time and the half-spaced point). In some embodiments, the exudate metric may be based on a maximum amplitude of the difference waveform before the midpoint.

Aspects of the present disclosure provide a method for forming an exudate metric. The method may be performed on a speculum tip having an inspection aperture for coupling to the ear canal and tympanic membrane to be characterized. The speculum tip may be coupled to a pressure measuring sensor for measuring the pressure in the speculum tip and a pressure excitation generator for regulating the pressure in the speculum tip. The method may include forming a pressure stimulus coupled to the speculum tip; measuring a pressure response; based on a transfer function of the pressure response to the pressure stimulus, determining at least one of: pressure seal leakage; a healthy tympanic membrane; a tympanic membrane coupled to the aqueous fluid; a tympanic membrane fluidly coupled to a relatively viscous bacteria.

In some embodiments, the determination may be made based on comparing the first measurement of the healthy ear to the other ear. In some embodiments, the determination may be based on a characterization of at least one of: the frequency response corner frequency, the time delay of the step response, or the coefficient is fitted to the parameters of the attenuation equation. In some embodiments, the attenuation equation isOr Is incorporated by reference

All publications, patents, and patent applications mentioned in this specification are herein incorporated by reference to the same extent as if each individual publication, patent, or patent application was specifically and individually indicated to be incorporated by reference.

Drawings

The novel features of the invention are set forth with particularity in the appended claims. A better understanding of the features and advantages of the present invention will be obtained by reference to the following detailed description that sets forth illustrative embodiments, in which the principles of the invention are utilized, and the accompanying drawings of which:

fig. 1 shows a schematic diagram of a pressure responsive controller coupled to a human ear canal.

Fig. 2 shows an amplitude transfer plot and a phase transfer plot for various exudate conditions.

FIG. 3A shows a plot of a first volumetric excitation and an exemplary response.

FIG. 3B shows a plot of a second volumetric excitation and an exemplary response.

Fig. 4 shows a plot of a third volume stimulus and an exemplary response.

FIG. 5 shows a plot of a fourth volume excitation and an exemplary response.

Fig. 6 shows a block diagram of an otoscope measuring tympanic membrane displacement in response to a displacement source.

Detailed Description

Fig. 1 shows an otoscope 130 comprising a speculum tip 116 for insertion into the ear canal of a subject to be characterized. Lens 126 is coupled to an optical unit 114, which optical unit 114 provides inspection of the outer ear, as provided by prior art otoscopes such as Welch Allyn 25070-M. The pressure excitation generator 106 couples the volume change from the excitation generator to the speculum tip 116 through the hose 112, and the pressure measurement hose coupled to the pressure sensor 108 provides a measurement of the pressure change in the speculum tip 116 from the volume change of the excitation generator. It may be desirable to seal the speculum tip 116 in the location where it is attached to the optical unit 114 to minimize the volume that is excited to include only the ear canal and the volume of the speculum tip 116, or the speculum tip 116 may be sealed to the ear canal at other locations, including the concha and tragus at the entrance to the ear canal or at any location where sealing to the ear canal is accomplished.

When inserted into the ear canal of a subject (see details 122), a conformable seal 120 may be used that comfortably seals the speculum tip 116, thereby providing effective coupling of the volume change produced by the volume excitation generator 106 to the inner ear and tympanic membrane 124. The volume (or pressure) excitation generator 106 may be any of the following: a voice coil integrated with a movable diaphragm, a diaphragm coupled to a piston actuator, or any mechanism that modulates a volume or introduces an external pressure source, which is coupled to the speculum tip 116 to induce a pressure change (e.g., by changing the enclosed volume or introducing and removing a gas, such as air, from a fixed volume), which couples the pressure change to the speculum tip 116 and the tympanic membrane. In this description, although a volume adjustment device such as a diaphragm or piston is described, it should be understood that the pressure change produced by the pressure excitation generator 105 may be created by any volume displacement method. The volume change is intended to cause a very slight change in the position of the tympanic membrane 124. If no fluid is present behind the tympanic membrane 124, the tympanic membrane is free to move and accommodate slowly varying (low frequency) volume changes with negligible pressure changes. If there is fluid behind the tympanic membrane 124, the tympanic membrane will exhibit reduced displacement for high frequency pressure changes. Furthermore, for the tympanic membrane coupled with an aqueous viral fluid or mucoid infectious fluid, the tympanic membrane may respond poorly to volume changes at high frequencies, which results in a greater pressure change for a given incremental volume change when there is fluid adjacent to the less mobile tympanic membrane, and the greater the mass of fluid present, the greater the kinetic contraction of the tympanic membrane at lower frequencies, resulting in greater induced pressure at higher frequencies.

When the fluid is adjacent to the tympanic membrane, the mobility of the tympanic membrane may be reduced, which results in greater pressure for a given volume change at high frequency. This is illustrated in the frequency response plot of fig. 2, which shows the variation of the pressure variation difference (AP) divided by the volume variation difference (AV) with frequency, scaled to fixed TM units of AP/AV. Curve 208 shows the pressure change versus volume change response curve for a healthy ear, which produces minimal pressure change at low frequencies for incremental volume changes, since the volume of the system remains relatively fixed and pressure changes are minimal because there is no adjacent fluidly coupled active tympanic membrane to track the displacement changes of the excitation generator. The fluid adjacent to the TM adds mass and restricts the motion of the TM at higher frequencies, resulting in increased speculum 116 pressure at the lower frequencies 212 of curve 206, and the TM-fixed "glue ear" produces a response curve 204 with an associated corner frequency 210, where the volume change results in a greater incremental pressure.

The plot of fig. 2 shows a pressure/volume versus frequency transfer function, such as a sinusoidal volume modulation measured as a pressure versus frequency transfer function. Each curve has a corner frequency at which the transfer function flattens with increasing frequency. A low frequency volume change that does not produce a pressure change in the ear indicates that the tympanic membrane is free to move at this frequency and, because of the increased inertia of the adjacent fluid coupling, the tympanic membrane is not free to move, and thus the pressure increases, the various states of the tympanic membrane are shown in the plot of fig. 2. For example, a healthy tympanic membrane that is free to move over a wide frequency range without resistance is shown as waveform 208 with corner frequency 214. In the presence of aqueous fluids from viral infection behind the tympanic membrane, the mobility of the tympanic membrane 124 is reduced and therefore no longer able to respond to intermediate frequencies (212) and produce speculum pressure modulation at these frequencies, as shown by the pressure/volume response curve 206. The final stage of the ear infection, where bacterial material with a density greater than the viral watery fluid collects on the tympanic membrane and becomes "glue ear", further reduces the amplitude response and frequency range, as shown by curve 204, indicating that the tympanic membrane is not moving in response to volume/pressure excitation, except at the lowest pressure excitation frequency 210. Each corner frequency 210, 212, and 214 is determined by the mass and volume of the fluid that restricts TM motion.

Fig. 3A illustrates another perspective and method of characterizing TM using a frequency domain excitation curve 302 (sinusoidal volume variation) and corresponding pressure (used as an indicator of tympanic membrane location) 306. By examining the amplitude and phase delay 310 of the measured pressure curve 306 at a particular period 304, and repeating the measurements at other frequencies, a plot of the phase delay 310 and amplitude can be derived from the response waveform 306. In another exemplary embodiment, the phase and amplitude responses may be collected by using chirped frequency excitation that varies over a continuously repeating cycle period to measure the displacement response (by pressure) of the tympanic membrane to the volume excitation (chirped frequency displacement) in a single frequency scan. The transfer function of the tympanic membrane may be determined as a familiar curve that normalizes the amplitude of 306 to that of waveform 302, where the phase delay 310 is expressed in degrees, both measured as a function of frequency. Transfer function amplitude and phase can be used clinically, where thresholds are established for frequencies where the amplitude transfer function drops by 3dB or 6dB or where the phase lags by 45 degrees to determine frequency breakpoints, where the frequency breakpoints can be used as a mobility metric, where high frequency breakpoints indicate normal ears, low frequency breakpoints indicate exudate, and lower frequency breakpoints indicate gel ears.

Fig. 3B shows an alternative time domain response, where a step change 320 in the instantaneous applied volume, and a pressure response curve 326 is observed, similarly with a time domain delay 324, and some rounding response related to the loss of high frequency components due to the mechanical inertia of the tympanic membrane and adjacent fluid, where the time delay 324 and the degree of rounding are related to the mobility of the tympanic membrane, which may also be an indicator of whether exudate is present, water-like exudate or dense bacterial mucoid exudate. A measurement metric using the response 326 of fig. 3B may use a time response threshold to determine the health of the tympanic membrane, where a relatively longer time response 324 indicates a glue ear, a shorter response indicates exudate, and a shorter response indicates a normal ear.

In another measurement method, a trapezoidal pressure excitation 402 is applied by the controller 104 and the measured pressure 406 in the speculum tip 406 is examined to determine a settling time (settling time) t 1404, which settling time t 1404 is the time when the instantaneous rate of change of the pressure decreases to its initial rate of change value, e.g., 1/4, or the settling time t 1404 is chosen to be a certain fixed time 404, whichever occurs first. A scaling factor k is applied to the measured pressure waveform 406 such that at time t 1404, k × Δ P (t1) ═ Δ V (t 1). When k is determined from the measurement value, a difference waveform (difference waveform) dp (t)408 is calculated such that dp (t) becomes Δ v (t) -k × Δ p (t). The waveform 408 is examined and the peak value dp (max) is determined and tested according to the following criteria (where the first, second and third thresholds are established as a monotonically increasing series of thresholds):

if dP < T1 (first threshold), then there may be no fluid present;

if T1< ═ dP < ═ T2 (second threshold), then aqueous fluid may be present;

if T2< ═ dP < ═ T3 (third threshold), then mucoid fluid or gel may be present.

In another example, the difference dp (t) is formed by averaging a Δ (t) and Δ p (t) over several instances.

In another example, the volume excitation a Δ (t) rise time Tr 401 varies over several consecutive cycles in a group, each group of pressure excitations being the same, the pressure response of each cycle is averaged to provide a composite Δ p (t) to provide a reliable pressure response for each group of cycles, and the rise time Tr 401 is varied in different groups of measurement cycles to characterize the tympanic membrane for various pressure excitation rise times.

In another example, Δ V rise time 401 is reduced to a minimum and the pressure response rise time 405 from 0 to tr and fall time 406 from tr to t2 are examined and fitted to a curve. For example, the pressure rise time response 405 (or t-difference rise time 409) may be fit toAnd fits the fall t time 408 as

Wherein:

pr (t) is the rise time of 405 or 409 from 0 to tr;

pf (t) is the fall time of 406 or 408 deviating to 0 at t 2;

t is time (x-axis of the curve);

kl is the amplitude scaling constant;

t1 is a rise time coefficient determined by curve fitting matching, having time units;

t2 is a fall time coefficient determined by curve fitting matching, having time units;

after determining k1 and T1 or k2 and T2 from at least one of the response waveforms 408, 409, 405, or 406, an exudate metric may then be developed, where relatively longer T1 or T2 and relatively larger k1 and k2 indicate less likelihood of exudate or glue ears, and relatively shorter T1 or T2 indicate more likelihood of exudate, while shorter T1 or T2 with larger values of k1 and k2 indicate glue ears, and where relatively smaller values of kl and k2 (particularly with relatively shorter T1 or T2) may be used to indicate a poor seal (or perforated TM).

In another example, a sinusoidal volume excitation of 5 or more cycles of a burst (burst) is provided as Δ v (t), each cycle of the burst being used to average a measured pressure waveform for a single cycle at a frequency f by Δ p (t) to provide a pressure response point at a particular frequency f1, after which a frequency transfer function is calculated for each frequency fThereafter, the resulting transfer function response corner frequencies 214, 212, 210 of fig. 2 may be similarly used as threshold frequencies to determine normal tympanic membrane response, aqueous fluid behind the tympanic membrane, and mucous or gel tympanic membrane response, respectively.

In the case where only one ear is clinically suspected of infection, each of the above methods described in fig. 2, 3A, 3B, 4 and 5 can be used in the differential method by comparing the results of the left and right ears. Methods of differential comparison of healthy performance ears to suspected infected ears may provide normalization of diagnostic thresholds compared to models developed from the general population. For example, a factor of 2 for the frequency breakpoint difference of fig. 2 or 3A or a factor of 2 for the time response difference of fig. 3B or 4 may be used to determine exudate, and a factor of 4 or greater may be used to determine a glue ear, between a supposedly healthy ear and an ear suspected of being infected.

In another example, the characteristics of the pressure response are checked as evidence of seal 120 leakage. In the case of pressure leaks in the ear canal, the high frequency transmission is adversely affected and if the seal leaks sufficiently, the pressure in response to the pressure excitation is not measured. The pressure curves 420 and 422 of fig. 4 illustrate an example of a speculum tip leak, where a change in the piston/diaphragm volume 402 creates a transient positive pressure 420 and a consequent transient negative pressure 422 when the piston/diaphragm moves in the opposite direction. The duration of the measured pressure waveforms 420 and 422 may be examined to determine any of several conditions in which a poor speculum tip seal 120 may be identified, which are not limited to:

1) a shortened pressure time response that is less than the duration of the volume change stimulus;

2) no pressure response during volume change excitation;

3) a negative pressure response 422 in response to the volume adjusting piston/diaphragm returning to its original position.

Fig. 6 illustrates an alternative tympanic displacement measurement system including a piston (or membrane) 606 sealed 604 to form an enclosed chamber 608 with a displacement volume coupled through a hose 112 to a speculum tip 116 with an optical viewer 126. The piston actuator 602 (which may be a voice coil actuator or other electromagnetic actuator) moves the piston 606 along the axis of the chamber 608, with the displacement measured by the sensor 614 coupled to a displacement measurement 618. The central controller 601 issues commands to the piston actuator 602 to cause the piston 606 to adjust position, where the displacement 618 is measured and reported to the controller 601. The controller 601 also reads a pressure measurement 616 of the pressure generated in the speculum tip 116 transmitted from the chamber 608 to the speculum tip 116 through the hose 112.

In an exemplary embodiment, the piston diameter 606 is selected to have the same approximate diameter as a pediatric (or adult) tympanic membrane. The displacement of the piston 606 is adjusted and the pressure 110 is measured. For systems with small pressure changes and sealing, the output of the displacement measurement 618 can be taken as an indicator of tympanic membrane movement. Thus, for movement of the piston 608 that produces a small change in the measured pressure 616, the displacement of the piston 606 may be considered an indicator of tympanic membrane movement. In one example, the displacement of the piston 606 is swept and a break in the measured pressure measurement 616 frequency response is recorded, which represents an excitation frequency where the mobility of the tympanic membrane 124 is adversely affected by adjacent fluid mass that impedes high frequency modulation of the tympanic membrane 124. View 650 shows an alternative diaphragm pressure actuator 603 in which a voice coil 660 with leads 658 is actuated when a current is generated that causes permanent magnets 656 to attract or repel, thereby displacing the diaphragm 652 relative to a flexible support 654, the flexible support 654 providing a high frequency response for the diaphragm 652 in the enclosed space 608, as before coupled with the speculum tip 610, or the excitation generator may be enclosed in the speculum tip 116 of fig. 1, or in an adjacent housing 114.

Illustrative examples are provided for understanding the present invention, the scope of which is set forth in the following claims.

While preferred embodiments of the present invention have been shown and described herein, it will be obvious to those skilled in the art that such embodiments are provided by way of example only. Numerous variations, changes, and substitutions will now occur to those skilled in the art without departing from the invention. It should be understood that various alternatives to the embodiments of the invention described herein may be employed in practicing the invention. It is intended that the scope of the invention be defined by the following claims and that the methods and structures within the scope of these claims and their equivalents be covered thereby.