Coupling and Elastic Loading Affect the Active Response by the Inner Ear Hair Cell Bundles

Active hair bundle motility has been proposed to underlie the amplification mechanism in the auditory endorgans of non-mammals and in the vestibular systems of all vertebrates, and to constitute a crucial component of cochlear amplification in mammals. We used semi-intact in vitro preparations of the bullfrog sacculus to study the effects of elastic mechanical loading on both natively coupled and freely oscillating hair bundles. For the latter, we attached glass fibers of different stiffness to the stereocilia and observed the induced changes in the spontaneous bundle movement. When driven with sinusoidal deflections, hair bundles displayed phase-locked response indicative of an Arnold Tongue, with the frequency selectivity highest at low amplitudes and decreasing under stronger stimulation. A striking broadening of the mode-locked response was seen with increasing stiffness of the load, until approximate impedance matching, where the phase-locked response remained flat over the physiological range of frequencies. When the otolithic membrane was left intact atop the preparation, the natural loading of the bundles likewise decreased their frequency selectivity with respect to that observed in freely oscillating bundles. To probe for signatures of the active process under natural loading and coupling conditions, we applied transient mechanical stimuli to the otolithic membrane. Following the pulses, the underlying bundles displayed active movement in the opposite direction, analogous to the twitches observed in individual cells. Tracking features in the otolithic membrane indicated that it moved in phase with the bundles. Hence, synchronous active motility evoked in the system of coupled hair bundles by external input is sufficient to displace large overlying structures

Frequency-Dependent Properties of a Fluid Jet Stimulus: Calibration, Modeling, and Application to Cochlear Hair Cell Bundles

The investigation of small physiological mechano-sensory systems, such as hair cells or their accessory structures in the inner ear or lateral line organ, requires mechanical stimulus equipment that allows spatial manipulation with micrometer precision and stimulation with amplitudes down to the nanometer scale. Here, we describe the calibration of a microfluid jet produced by a device that was designed to excite individual cochlear hair cell bundles or cupulae of the fish superficial lateral line system. The calibration involves a precise definition of the linearity and time- and frequency-dependent characteristics of the fluid jet as produced by a pressurized fluid-filled container combined with a glass pipette having a microscopically sized tip acting as an orifice. A procedure is described that can be applied during experiments to obtain a fluid jet’s frequency response, which may vary with each individual glass pipette. At small orifice diameters (<15 μm), the fluid velocity of the jet is proportional to the displacement of the piezoelectric actuator pressurizing the container’s volume and is suitable to stimulate the hair bundles of sensory hair cells. With increasing diameter, the fluid jet velocity becomes proportional to the actuator’s velocity. The experimentally observed characteristics can be described adequately by a dynamical model of damped fluid masses coupled by elastic components

Hair Cell Bundles: Flexoelectric Motors of the Inner Ear

Microvilli (stereocilia) projecting from the apex of hair cells in the inner ear are actively motile structures that feed energy into the vibration of the inner ear and enhance sensitivity to sound. The biophysical mechanism underlying the hair bundle motor is unknown. In this study, we examined a membrane flexoelectric origin for active movements in stereocilia and conclude that it is likely to be an important contributor to mechanical power output by hair bundles. We formulated a realistic biophysical model of stereocilia incorporating stereocilia dimensions, the known flexoelectric coefficient of lipid membranes, mechanical compliance, and fluid drag. Electrical power enters the stereocilia through displacement sensitive ion channels and, due to the small diameter of stereocilia, is converted to useful mechanical power output by flexoelectricity. This motor augments molecular motors associated with the mechanosensitive apparatus itself that have been described previously. The model reveals stereocilia to be highly efficient and fast flexoelectric motors that capture the energy in the extracellular electro-chemical potential of the inner ear to generate mechanical power output. The power analysis provides an explanation for the correlation between stereocilia height and the tonotopic organization of hearing organs. Further, results suggest that flexoelectricity may be essential to the exquisite sensitivity and frequency selectivity of non-mammalian hearing organs at high auditory frequencies, and may contribute to the “cochlear amplifier” in mammals

Transient overdrive pacing prevents orthostatic hypotension in elderly pacemaker patients with chronotropic incompetence

27th Annual Scientific Sessions of Heart Rhythm Society, Boston, Massachusetts, USA, 17–20 May 2006. In Heart Rhythm, 2006, v. 3 n. 5 Suppl., p. S246, abstract no. P4-8

Blood pressure response to transition from supine to standing posture using an orthostatic response algorithm

Upon standing from a supine position, the normal response is an increase in heart rate to maintain blood pressure (BP). In patients with chronotropic incompetence, heart rate may not increase upon standing, and they may experience orthostatic hypotension (OH). We evaluated a new orthostatic response (OSR) pacing algorithm that uses an accelerometer signal to detect sudden activity following prolonged rest to trigger a 2 minutes increase in pacing rate to 94 bpm. Ten recipients of DDDR pacemakers which contain the OSR compensation algorithm (mean age = 77 ± 9 years, 8 women) with sick sinus syndrome (n = 6) or atrioventricular block (n = 4) were studied. In all patients BP was measured before and 0.5, 1, 1.5, 2, and 3 minutes after standing at their programmed base rate. A 20 mmHg fall in systolic BP upon standing was observed in five patients (OH patients), while the other five were considered non-OH patients. The measurements were repeated with the OSR algorithm turned on. Mean BP was defined as 1/3 systolic BP + 2/3 diastolic BP. Baseline heart rate was significantly slower in OH patients (62 ± 2 bpm) than non-OH patients (71 ± 7 bpm, P < 0.05). In OH patients mean BP increased significantly upon standing (P < 0.05 for all comparisons) with the algorithm ON instead of decreasing with the algorithm OFF, at 1 minute (+3.4 vs -10.3 mmHg), 1.5 minutes (+7.0 vs -4.9 mmHg), 2 minutes (+1.6 vs -6.7 mmHg), and 3 minutes (+2.5 vs -8.5 mmHg). These preliminary results suggest that the OSR algorithm maintains BP upon standing in patients with OH.link_to_subscribed_fulltextCardiostim 2004 Meeting, Nice, France, 16-19 June 2004. In Pace - Pacing And Clinical Electrophysiology, 2005, v. 28 suppl. 1, p. S242-S24

Transient overdrive pacing upon standing prevents orthostatic hypotension in elderly pacemaker patients with chronotropic incompetence

Background: Elderly pacemaker patients with chronotropic incompetence (CI) may experience orthostatic hypotension (OH) upon standing. The objective of this study was to determine whether a transient increase in heart rate (HR) by overdrive pacing upon standing prevents OH in elderly pacemaker patients. Methods: We studied the effect of transient overdrive pacing upon standing in mitigating the drop in blood pressure (BP) in 62 pacemaker patients (77 ± 6 years, 32 F) implanted with DDD pacemaker for sick sinus syndrome (n = 40) or atrioventricular block (n = 22). All patients underwent two standing procedures in random order: a control, with backup (60 bpm) pacing and another with overdrive DDD pacing (at 35 bpm above their baseline rate) for 2 minutes upon standing. Systolic (SBP) and diastolic blood pressure (DBP) and HR were measured while supine (baseline) and 1, 2, and 3 minutes after standing. OH was defined as a drop in SBP ≥20 mmHg or DBP ≥10 mmHg during standing. Chronotropic incompetence (CI) was defined as an absence of HR increase of ≥10 bpm during standing. Results: A total of 17 (27%) patients developed OH upon standing during backup pacing. Baseline clinical characteristics (age, sex, prevalence of diabetes, use of vasoactive medications, and sick sinus syndrome) were similar between patients with or without OH. In patients with or without OH, transient overdrive pacing upon standing increased HR and DBP as compared with baseline (P < 0.05). However, in patients with OH, transient overdrive pacing did not prevent decrease in SBP upon standing and avoided the development of OH in only 10/17 patients (59%). Among those patients with OH, 10/17 (59%) patients had CI. In OH patients with CI, transient overdrive pacing upon standing maintained SBP and DBP as compared to baseline and prevented OH in the majority of patients (80%). By contrast, transient overdrive pacing in OH patients without CI had no significant effect on the decrease in SBP upon standing and prevented OH in only 20% of patients. Conclusions: OH is common (27%) in the elderly pacemaker population. In a subgroup of these patients, CI may be responsible for the occurrence of OH, and OH can be prevented by transient overdrive pacing upon standing. © 2007, The Authors.link_to_subscribed_fulltex

Attenuation of Left Ventricular Adverse Remodeling With Epicardial Patching After Myocardial Infarction

Background: Previous studies suggested that epicardial patch applied to the infarcted site after acute myocardial infarction (MI) can alleviate left ventricular (LV) remodeling and improve cardiac performance; however, the effects of regional epicardial patch on chronic phase of LV remodeling remain unclear. Methods and Results: We studied 20 pigs with MI induced by distal embolization and impaired LV ejection fraction (LVEF .05). As determined by cardiac MRI, LV end-diastolic and end-systolic volumes increased at 20 weeks compared with 8 weeks in both groups (P < .05). However, the increase in LV end-diastolic volume (+14.1 ± 1.8% vs. +6.6 ± 2.1%, P = .015) and LV end-systolic volume (+12.1 ± 2.4% vs. -4.7 ± 3.7%, P = .0015) were significantly greater in the control group compared with the patch group. Furthermore, the percentage increase in LVEF (+17.3 ± 4.9% vs. +4.1 ± 3.9%, P = .048) from 8 to 20 weeks was significantly greater in the patch group compared with the control group. Histological examination showed that LV wall thickness at the infarct region and adjacent peri-infarct regions were significantly greater in the patch group compared with the control group (P < .05). Conclusion: Regional application of a simple, passive synthetic epicardial patch increased LV wall thickness at the infarct region, attenuated LV dilation, and improved LVEF and +dP/dt in a large animal model of MI. © 2010 Elsevier Inc. All rights reserved.link_to_subscribed_fulltex

Chick hair cells do not exhibit voltage-dependent somatic motility

It is generally believed that mechanical amplification by cochlear hair cells is necessary to enhance the sensitivity and frequency selectivity of hearing. In the mammalian ear, the basis of cochlear amplification is believed to be the voltage-dependent electromotility of outer hair cells (OHCs). The avian basilar papilla contains tall and short hair cells, with the former being comparable to inner hair cells, and the latter comparable to OHCs, based on their innervation patterns. In this study, we sought evidence for somatic electromotility by direct measurements of voltage-dependent length changes in both tall and short hair cells at nanometre resolution. Microchamber and whole-cell voltage-clamp techniques were used. Motility was measured with a photodiode-based measurement system. Non-linear capacitance, an electrical signature of somatic motility, was also measured to complement motility measurement. Significantly, chick hair cells did not exhibit somatic motility nor express non-linear capacitance. The lack of somatic motility suggests that in avian hair cells the active process resides elsewhere, most likely in the hair cell stereocilia