Animal experiments in mature guinea pigs were devised to determine whether and to what extent inner ear damage can be caused by in vivo use of the erbium laser for stapedotomy. The present study examined the laser effect in connection with perforation of the basal convolution of the cochlea and subsequent application in the opened cochlea. Acoustic evoked potentials as compound action potentials (CAP) were recorded for changes in inner ear function. Findings demonstrated that five applications of the erbium:YSGG (yttrium-scandium-gallium-garnet) laser (energy, 85 mJ/pulse; energy density, 36 J/cm2) were needed to create a footplate perforation of 500-600 microns and did not lead to CAP alteration in any animal (n = 20). An increase of the repetition rate from 1 to 5 Hz likewise caused no CAP alteration (n = 17). Application of high total energies in the open cochlea (n = 5) to determine the safety of the laser system for stapedotomy revealed that a 10-fold increase in the total energy required for adequate perforation led to irreversible CAP alterations and no CAP could be recorded at a 15-fold increase in total energy. In contrast, a 5-fold maximum increase in total energy caused no CAP alterations. These results demonstrate the safety of the Er:YSGG laser comparable to that of the CO2 laser for stapedotomy, supporting its utility as an alternative method for surgery.
The diagnosis of Menière's disease is uncertain when the typical symptoms do not occur completely and definitely. A reliable finding of an endolymphatic hydrops (EH) is the base for a correct prognosis and therapy. Electrocochleography is a proven diagnostic procedure but requires a lot of time and of technical know-how. The mobility of cochlear partition can be tested by low-frequency masking (LFM) recording the phase dependent subjective masked threshold of a short test tone. We performed electrocochleography and LFM in 29 patients with suspected Menière's disease at the same day. Both tests pointed at an EH in 62%, and in 24% the results showed correspondent negative results. In 14% the results were inconsistent. Both methods also showed in 59% of the contralateral ears without symptomatic signs the indication of an EH. Considering the good conformity of both tests the easier LFM can be recommended for detection of EH.
Experiments were performed in guinea pigs to clarify which, if any, of the CO2 lasers used can damage the inner ear on application of the laser parameters required for stapedotomy. A further aim was to determine their application safety. The basal convolution of the guinea-pig cochlea was chosen as the application site, since its thickness is similar to that of the human stapes base. We examined the laser effect in connection with perforation of the basal convolution and subsequent application in the open cochlea. Acoustic evoked potentials (compound action potentials [CAP]) yielded information on inner-ear function. Animals without laser treatment were used as controls. Perforation of the basal convolution and laser applications in the open cochlea with the same parameters did not lead to a measurable CAP alteration with the CO2 cw laser (power: 8 W, pulse duration: 50 ms, power density: 3200 W/cm2). An increase of the laser power to 15 W (power density: 6000 W/cm2) and of the pulse duration to 200 and 500 ms (energy: 3 J and 7.5 J) caused partly irreversible CAP alterations; finally, no potential could be recorded any more at a maximal laser power and pulse duration (15 W and 500 ms). Examination of high power densities (40,000 and 60,000 W/cm2) through reduction of the laser beam diameter to 180 microns yielded comparable results.(ABSTRACT TRUNCATED AT 250 WORDS)
Click polarity has little influence on brainstem potentials. We applied an auditory stimulus similar to a step function generated in a closed acoustic system. The influence of stimulus onset steepness (comprising rise time and intensity) on wave V latency and amplitude was investigated. A remarkable latency prolongation was observed for condensation (C) compared with rarefaction (R), if a sharp bend at the foot of the slope was avoided. The C latency lag was nearly the amount of rise time. The effect can be explained by cochlear travel time. Wave V amplitude for R slopes was significantly enhanced. At high intensity and short rise time, it reached twice the values found with C slopes, or with clicks of either polarity. Although the explanations found are not yet satisfactory, a clinical application in cochlear diagnosis is predictable.
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