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DISTORTION PRODUCT OTOACOUSTIC EMISSIONS PROVIDE CLUES TO HEARING MECHANISMS IN THE FROG Pantelis N. Vassilakis, Sebastiaan W. F. Meenderink, and Peter M. Narins Department of Physiological Science University of California at Los Angeles - Los Angeles, CA 90095-1606 USA (Corresponding author: Peter M. Narins: [email protected]) RESULTS INTRODUCTION - BACKGROUND Experiment 1: DPOAE I/O curves f = 600Hz (R. catesbeiana) f1 == 1500Hz f1 1500Hz (R. (R. catesbeiana) catesbeiana) 35 Noise Noise 25 25 AP: 2f1-f2 15 BP: 2f1-f2 15 5 Noise 0 -5 -10 1250 1250 750 1750 2250 f 1 (Hz) 50 60 70 80 90 40 b 50 Amphibian Papilla 70 80 90 Basilar Papilla 45 f1 = = 1800Hz (R. pipiens) p. pipiens) f1 1800Hz (R. f1 = (R. p. pipiens) f1 = 800Hz 800Hz (R. pipiens) f1 = (R. catesbeiana) f1 = 600Hz 600Hz (R. catesbeiana) 35 f1 = = 1500Hz (R. catesbeiana) catesbeiana) f1 1500Hz (R. 35 -10 Amphibian papilla Basilar papilla 750 1250 1750 2250 2750 f 2 (Hz) 50 c 60 70 80 90 30 40 d L1 = L2 (dB SPL) 50 60 70 80 90 L1 = L2 (dB SPL) 5 2f2-f1 Noise 0 -5 -10 L2 = 60dB SPL FIG. 2 10 f1=800Hz (AP) f1=1500Hz (BP) f1=1500Hz (BP) Noise Noise 5 0 -5 5 0 -5 -10 -10 -15 -15 50 55 60 65 45 50 b L2 (dB SPL) 10 f1=800Hz (AP) f1=1500Hz (BP) Noise Noise 5 0 -5 -15 50 55 60 0 -5 -10 65 45 L2 (dB SPL) 50 2250 2750 55 60 65 The level of each DPOAE depends most on the level of its neighboring (in frequency) primary [i.e. (b) & (c)]. L1-L2 = 10dB = 7.5dB 1100 1600 2100 2600 f 2 (Hz) 2f2-f1 5 Noise 0 -5 -10 600 1100 1100 1600 2100 2600 DP frequency (Hz) Male Male Female Female Noise Noise 5 0 -5 -10 5 0 -5 -10 FIG. 6 750 1250 1750 2250 -15 2750 DP Frequency (Hz) a 250 750 1250 1750 2250 2750 f 2 (Hz) b = 0dB = -2.5dB = -5dB 0 = -7.5dB Male Male 10 10 Female = -10dB Female Noise Noise -15 200 400 600 800 1000 1200 f 1 (Hz) a 1400 1600 FIG. 3 10 2f 2-f 1 Level (dB SPL) -10 2f 1-f 2 Level (dB SPL) Noise -5 5 0 -5 -10 FIG. 7 = 7.5dB -15 = 5dB 100 = 2.5dB 5 5 0 -5 -10 L1-L2 = 10dB 600 1100 1600 2100 2600 -15 100 600 1100 1600 2100 2600 = 0dB = -2.5dB a DP Frequency (Hz) b f 2 (Hz) = -5dB 0 = -7.5dB = -10dB Noise -5 -10 -15 200 400 600 800 1000 f 1 (Hz) 1200 1400 1600 1 _ 2f1-f2 I/O curves from the frog AP are similar to mammalian DPOAE I/O curves (non-monotonic response with a notch for L1,L2~ 70dB SPL), indicating that an amplification process may be present in the frog AP. Since the frog ear lacks OHCs, our results implicate hair cell bundle movement, which may be analogous to mammalian OHC somatic motility. BP DPOAE I/O curves are rather monotonic, suggesting that no amplification process is present in this papilla. The difference between AP and BP may be linked to respective innervation differences, consistent with the fact that only the AP is tonotopically organized.(Fig. 1) 2 _ Highest DPOAEs (R. p. pipiens, f2/f1 = 1.15) were generally obtained for L1 L2. Our data are again similar to mammalian results, consistent with a similarity in neural tuning curves. Since the frog ear lacks a BM (thought to be responsible for the shape of mammalian neural tuning curves), the observed similarity between frogs and mammals suggests that some other mechanical structure (possibly the tectorial membrane) may function analogously to the mammalian BM. (Figs. 2,3) 3 _ DPOAEs are produced in both papillae. R. catesbeiana generally produce higher amplitude emissions than R. p. pipiens. (Figs. 4,5) 4 _ In contrast to mammalian results, generation of the 2f1-f2 DPOAE in the frog appears to occur primarily at or near the DPOAE frequency place, while the generation of the 2f2-f1 DPOAE occurs primarily at a frequency place between the primaries. This difference may be linked to an anatomical difference that results in the acoustic energy following opposite paths through the mammalian and frog inner ears. (Figs 4,5) 5 _ Females from both R. p. pipiens and R. catesbeiana produce higher level emissions than males in both papillae. DPOAE-based sexual dimorphism has been reported in humans and other mammals. It may be linked to inner ear anatomical differences, middle ear transfer impedance differences, hormonal differences, nerve-fiber tuning differences, and/or behavioral and environmental factors. (Figs, 6,7) REFERENCES R. catesbeiana = 2.5dB 5 2f 1-f2 Level (dB SPL) 600 Basilar papilla 10 10 = 5dB 2f 2-f1 Level (dB SPL) Amphibian papilla DPOAEs levels from R. p. pipiens (Fig. 4) and R. catesbeiana (Fig. 5) as a function of: (a) f1, (b) f2, and (c) DP frequency. The dashed vertical line marks the “break” in the frequency coverage of the AP and the BP. DPOAEs arise from both papillae. For 2f1-f2, the dip in the plot aligns best with the vertical line when DPOAE level is plotted as a function of DP frequency (c). For 2f2-f1, the alignment is best when DPOAE level is plotted as a function of f2 (b). Note- there is also near alignment in the plot of DPOAE level against f1 (a). 250 10 b -10 c -15 Results from Fig. 2 in the form of DPOAE audiograms, confirming maximum DPOAE levels for |L1-L2| 0 at most frequencies tested and for both cubic DPOAEs. -5 100 DP frequency (Hz) L1 (dB SPL) d 0 R. p. pipiens -15 45 Noise 65 f1=800Hz (AP) f1=1500Hz (BP) 2f2 -f1 Level (dB SPL) 2f 2-f 1 Level (dB SPL) 60 L2 = 60dB SPL -10 c 55 1750 L1 (dB SPL) L1 = 60dB SPL 10 DPOAE levels versus L2 for fixed L1 [(a) & (c)] and versus L1 for fixed L2 [(b) & (d)]. 1250 2f 2-f 1 Level (dB SPL) f1=800Hz (AP) 750 c 2f 1-f 2 Level (dB SPL) 10 FIG. 5 -15 250 L1 = 60dB SPL 2f2-f1 2f1-f2 -15 Experiment 2: DPOAE vs. |L1-L2| (R. p. pipiens) 2600 10 DP Level (dB SPL) 40 DP Level (dB SPL) -15 30 2100 2f1-f2 -5 -15 1600 5 b 5 -5 1100 1100 f 1 (Hz) 100 10 5 600 -15 b 15 Noise -5 250 BP: 2f2-f1 2f2-f1 FIG. 4 -15 AP: 2f2-f1 15 -10 2f1-f2 0 25 25 -5 10 5 Noise Noise 2f 2-f 1 Level (dB SPL) 60 L1 = L2 (dB SPL) 45 0 2f1-f2 30 L1 = L2 (dB SPL) Noise a DP Level (dB SPL) 40 2f2-f1 5 100 2750 -15 30 2f1-f2 -15 a DP Level (dB SPL) -15 5 Data recording / analysis: Signal from subjects’ ears was fed to an FFT analyzer (SRS-SR770). The DPOAE level reported was the max. of 5 adjacent analysis bands centered at the DPOAE frequency band. Noise was estimated by averaging the levels of 18 analysis bands surrounding the 5 bands used to determine the DPOAE level (system distortion: ~ 84dB below the primaries). 2f2-f1 -15 -5 R. catesbeiana 2f1-f2 10 METHODS Stimuli: Primary-tone parameters: 240 ≤ f2, f1 ≤ 3000Hz (~ 0.1f1Hz steps) and 35 ≤ L1, L2 ≤ 85dB (2.5dB steps). Stimuli generated by a Real Time Processor (TDTRP2) and fed to a speaker/microphone assembly (ER10-C). R. p. pipiens 250 -5 10 5 5 a Anesthesia: Intramuscular injection, pentobarbital sodium solution (Nembutal, 50mg/ml: ~0.9-1.0 μl/g body mass) DP Level (dB SPL) f1 == 1800Hz pipiens) f1 1800Hz (R. p. pipiens) f11 = 600Hz (R. catesbeiana) 35 45 Subjects: 10 northern leopard frogs (R. p. pipiens) and 10 bullfrogs (R. catesbeiana), 5 males and 5 females each - both ears. 10 45 2f 1-f 2 Level (dB SPL) The present work examines the DPOAE parameter space in the frog (in terms of the primary tones’ frequency range as well as absolute and relative SP levels) and the relationship among DPOAE levels and the subjects’ species and sex (f2/f1 = 1.15) Basilar Papilla f1 == 800Hz pipiens) f1 800Hz (R. (R. p. pipiens) 2f 1-f 2 Level (dB SPL) DPOAEs have been recorded from the frog (Van Dijk et al, 2002), despite the fact that the frog inner ear has neither a BM (Capranica, 1976) nor morphologically distinct OHCs (Lewis et al., 1982). Experiment 3: DPOAE Audiograms (L1, L2 = 60dB SPL) DP Level (dB SPL) 45 a Mammalian DPOAEs have been linked to the inner ear’s (a) outer hair cell (OHC) motility, (b) cochlear amplifier, and (c) overlap of the primary tones’ basilar membrane (BM) disturbances. FIG. 1 Amphibian Papilla 2f 1-f 2 Level (dB SPL) Distortion product otoacoustic emissions (DPOAEs) arise when the ear is stimulated by two sine signals (primaries) with appropriate frequency (f1, f2) and stimulus (L1, L2) levels. Otoacoustic emissions (OAEs) in general and DPOAEs in particular have provided means of examining inner ear mechanisms in mammals (Shera & Guinan, 2003) and other vertebrates (Rosowski et al., 1984). CONCLUSIONS Comparison between DPOAE audiograms from both ears of 5 male and 5 female R. p. pipiens (Fig. 6) and R. catesbeiana (Fig. 7). (a) The level of 2f1-f2 is plotted as a function of DP frequency and (b) the level of 2f2-f1 is plotted as a function of f2 (see Figs. 4,5). Female subjects consistently exhibit stronger emissions than males, especially from the BP. Capranica, R. R. (1976). “Morphology and physiology of the auditory system,” in Frog Neurobiology, edited by R. Llinas, and W. Precht (Springer Verlag, Berlin), pp. 551-575. Lewis, E. R., Leverenz, E. L., and Koyama, H. (1982). “The tonotopic organization of the bullfrog amphibian papilla, an auditory organ lacking a basilar membrane,” J. Comp. Physiol., 145: 437-445. Rosowski, J. J., Peake, W. T., and White, J. R. (1984). “Cochlear nonlinearities inferred from two-tone distortion products in the ear canal of the alligator lizard,” Hear. Res., 13: 141-158. Shera, C. A., and Guinan, J. J. Jr. (2003). “Stimulus-frequencyemission group delay: A test of coherent reflection filtering and a window on cochlear tuning,” J. Acoust. Soc. Am., 113(5): 27622772. Van Dijk, P., Mason, M. J., and Narins, P. M. (2002). “Distortion product otoacoustic emissions in frogs: correlation with middle and inner ear properties,” Hear. Res., 173: 100-108.