Hairy Cells and How Potassium Channels Help Encode Complex Sounds
In the depths of your inner ear, hair cells are busy converting sound vibrations into electrical signals that your brain can interpret. But how exactly do they manage to translate the cacophony of noises in our environment into discernible, meaningful sounds? New research has unveiled the surprising role of potassium channels in this intricate process.
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New Products
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Membrane Protein Immunodetection
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Anti-MMGT1 Antibody
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Reactivity: M, R, *H
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Anti-LRRK2 Antibody
Cat #: #ANR-102 Type: Polyclonal | Host: Rabbit | Applications: IF, IHC, WB, *ICC, *IFC, *IP |
Reactivity: H, M, R
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Antibodies for Live Cell Direct Flow Cytometry:
Ion Channel Pharmacology
Small Organic Molecules:
XEN907
Cat #: X-105 Type: Small Molecules | Source: Synthetic | MW: 351.1
Target: NaV1.7 channels
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VU0529331
Cat #: V-155 Type: Small Molecules | Source: Synthetic | MW: 384.4
Target: Kir3.2, Kir3.4 channels
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A 784168
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Target: TRPV1 channel
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Amentoflavone
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Target: GABA(A) receptors
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