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First published online November 19, 2007
Journal of Experimental Biology 210, 4244-4253 (2007)
Published by The Company of Biologists 2007
doi: 10.1242/jeb.009290

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The flexural stiffness of superficial neuromasts in the zebrafish (Danio rerio) lateral line

Matthew J. McHenry^1,* and Sietse M. van Netten²

¹ Department of Ecology and Evolution, 321 Steinhaus Hall, University of California, Irvine, CA 92697, USA
² Department of Neurobiophysics, University of Groningen, Neurobiophysics, Nijenborgh 4, 9747 AG Groningen, The Netherlands

View larger version (55K): [in this window] [in a new window]   Fig. 1. The morphology of superficial neuromasts in the lateral line of a zebrafish larva. Photographs from separate individuals illustrate the scale and location of the neuromast studied and its constitutent morphology. (A) A larva from a dorsal perspective illustrates the location of the P8 neuromast. The dashed lines show the region of interest in B. (B) The trunk neuromasts are visible in the caudal region with incident illumination. A single P8 neuromast is highlighted by dashed lines. (C) The kinocilia and cupula of a P8 neuromast are visible when examined with Nomarski optics after coating the cupula with polystyrene microspheres. A visual slice parallel to the sagittal plane (dashed line) is shown in D. (D) This cross-section of the cupula illustrates its major morphological features.

View larger version (29K): [in this window] [in a new window]   Fig. 2. High-speed microscopy was used to track the position of the glass fiber used for stiffness measurements. (A) Individual larvae were inserted into a bed of agar with their tails pinned beneath a dull probe (triangle) under the objective lens of a fixed-stage compound microscope. When held in this position, the tip of a glass fiber was pressed against the middle of an individual neuromast (inset). (B) During experiments, the position of the fiber was recorded with a high-speed video camera mounted on the microscope. Video recordings were analyzed to track the movement of the edge of the glass fiber. A single video frame from one of these recordings is shown with the edge (purple line) that was found for the prescribed pixel stripe. (C) The pixel intensity along this stripe is shown with a curve fit (green line). (D) The first derivative of the fitted line with respect to position was used to find the position of maximum change in pixel intensity. This point was interpreted as the edge of the glass fiber.

View larger version (16K): [in this window] [in a new window]   Fig. 3. A representative measurement of the flexural stiffness of a superficial neuromast. (A) Each stiffness measurement was calculated from measurements of the position of the fiber tip (xtip, purple) and fiber base (xbase, green) of the glass fiber when pressed against a cupula. Noise was filtered from the raw data (light lines) to yield the position measurements used in the calculation (dark lines). (B) The filtered position data (solid black line) were used to calculate the stiffness of the cupula. The slope of a linear curve fitted to these data (gray line, m=0.440) yielded a flexural stiffness for the cupula [(EI)cup=2.28x10–20 N m2] using Eqn 3. A slope equal to unity (dashed line, m=1) represents the relationship predicted for a completely compliant neuromast. (C) The positional changes from B provide the basis for the calculation of the deflection of the cupulae and the force exerted by the fiber to cause that deflection.

View larger version (4K): [in this window] [in a new window]   Fig. 4. The relationship between the number of hair cells (each with one kinocilium) and the flexural stiffness of the cupula [(EI)cup]. Mean values (±1s.d., numbers next to points denote the sample size for each point) are shown for neuromasts of a variable number of hair cells. The trend line represents a significant (P<0.015) weighted linear regression that suggests that most of the variation (r2=0.81) in flexural stiffness is related to the number of hair cells. This trend was predicted by our hypothesis (Eqn 5), which interprets the slope of this line (2.4x10–21 N m2) as the stiffness generated by a single kinocilium.

View larger version (13K): [in this window] [in a new window]   Fig. 5. Measurement of flexural stiffness (EI) of a kinocilium compared with that of a flagellum. (A) The schematic illustration of a portion of an axoneme shows major features of the ultrastructure of flagella and kinocilia. (B) Arrows directed at the axonemes above each bar indicate the direction of loading for each measurement of stiffness. Flagellar stiffness was measured in demembranated sperm of the sand dollar (Clypeaster japonicus) activated by ATP (Ishijima and Hiramoto, 1994). (i) The stiffness of a flagellum when loaded along its beating plane is shown in comparison to measurements of stiffness for (ii) a kinocilium from the present study (error flags denote 95% confidence intervals) and the stiffness of (iii) a flagellum when loaded perpendicular to the beating plane.

View larger version (29K): [in this window] [in a new window]   Fig. 6. Variation in morphology and mechanics along the height of the cupula. (A) A schematic illustration showing the major morphological differences along the height of a cupula. (B) Photographs of cross-sections of a typical neuromast at three different heights. (C) The diameter of the cupula decreases with height, as shown by mean values (points and heavy line, ±1s.d. shown by thin lines, numbers indicate sample size). (D) The number of kinocilia in a cross-section decreases with height. Data for individual cupulae (gray lines) and mean values (points and heavy line, ±1s.d. shown by thin lines) are shown. (E) The mean values of the morphological data in D, along with our measurements of flexural stiffness (EI, Fig. 4), provide the basis for calculations of cupular flexural stiffness versus height. The total flexural stiffness of the cupula (gray line) is dominated by the stiffness provided by the kinocilia (green line) in the proximal region. The stiffness of the cupular matrix provides a substantially more flexible structure in the distal region, where kinocilia are absent.

View larger version (19K): [in this window] [in a new window]   Fig. 7. Proposed model for the mechanics of a superficial neuromast compared with the mechanics of a canal neuromast. (A) The major morphological features of a superficial neuromast each have a functional analog. (B) The proposed model consists of a flexible two-part beam that is driven by a boundary layer of water flow and coupled to a linear pivotal spring at its base. The presence of kinocilia causes the proximal part of this beam to be substantially stiffer than the distal part, which consists solely of matrix material. The morphology and mechanics of superficial neuromasts is contrasted with (C,D) the model for a canal neuromast (van Netten and Kroese, 1987). (C) The same major anatomical features of a superficial neuromast are present in the canal neuromast, but (D) kinocilia do not play a functional role that is distinct from the hair bundles, which collectively function as a linear spring. Furthermore, the cupula is modeled as a rigid hemispherical body that is coupled to the hair bundles. The freestream flow within the canal is not greatly influenced by boundary layer dynamics for the frequencies to which these neuromasts are sensitive (van Netten, 2006) and may therefore be modeled as a uniform freestream.