Coding deficits in hidden hearing loss induced by noise: the nature and impacts.

Hidden hearing refers to the functional deficits in hearing without deterioration in hearing sensitivity. This concept is proposed based upon recent finding of massive noise-induced damage on ribbon synapse between inner hair cells (IHCs) and spiral ganglion neurons (SGNs) in the cochlea without significant permanent threshold shifts (PTS). Presumably, such damage may cause coding deficits in auditory nerve fibers (ANFs). However, such deficits had not been detailed except that a selective loss of ANFs with low spontaneous rate (SR) was reported. In the present study, we investigated the dynamic changes of ribbon synapses and the coding function of ANF single units in one month after a brief noise exposure that caused a massive damage of ribbon synapses but no PTS. The synapse count and functional response measures indicates a large portion of the disrupted synapses were re-connected. This is consistent with the fact that the change of SR distribution due to the initial loss of low SR units is recovered quickly. However, ANF coding deficits were developed later with the re-establishment of the synapses. The deficits were found in both intensity and temporal processing, revealing the nature of synaptopathy in hidden hearing loss.

Comparison of sodium dodecyl sulfate depletion techniques for proteome analysis by mass spectrometry.

In proteomics, sodium dodecyl sulfate (SDS) is favored for protein solubilization and mass-based separation (e.g. GELFrEE or SDS PAGE). Numerous SDS depletion techniques are available to purify proteins ahead of mass spectrometry. The effectiveness of the purification has a controlling influence on the success of the analysis. Here we quantitatively assess eight approaches to SDS depletion: in-gel digestion; protein precipitation in acetone or with TCA; detergent precipitation with KCl; strong cation exchange; protein level and peptide level purification with Pierce detergent removal cartridges; and FASP II. Considering protein purity, FASP II showed the highest degree of SDS removal, matching that of in-gel digestion (over 99.99% depleted). Other methods (acetone, strong cation exchange, Pierce cartridges) also deplete SDS to levels amenable to LC-MS (>99%). Accounting for protein recovery, FASP II revealed significant sample loss (<40% yield); other approaches show even greater protein loss. We further assessed acetone precipitation, having the highest protein recovery relative to FASP II, to process GELFrEE fractionated Escherichia coli ahead of bottom-up mass spectrometry. Acetone precipitation yielded a 17% average increase in identified proteins, and 40% increase in peptides, indicating this approach as a favored strategy for SDS depletion in a proteomics workflow.