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Epidural optogenetics for controlled analgesia.

Molecular pain (2016-04-01)
Robert P Bonin, Feng Wang, Mireille Desrochers-Couture, Alicja Ga Secka, Marie-Eve Boulanger, Daniel C Côté, Yves De Koninck
ABSTRACT

Optogenetic tools enable cell selective and temporally precise control of neuronal activity; yet, difficulties in delivering sufficient light to the spinal cord of freely behaving animals have hampered the use of spinal optogenetic approaches to produce analgesia. We describe an epidural optic fiber designed for chronic spinal optogenetics that enables the precise delivery of light at multiple wavelengths to the spinal cord dorsal horn and sensory afferents. The epidural delivery of light enabled the optogenetic modulation of nociceptive processes at the spinal level. The acute and repeated activation of channelrhodopsin-2 expressing nociceptive afferents produced robust nocifensive behavior and mechanical sensitization in freely behaving mice, respectively. The optogenetic inhibition of GABAergic interneurons in the spinal cord dorsal horn through the activation of archaerhodopsin also produced a transient, but selective induction of mechanical hypersensitivity. Finally, we demonstrate the capacity of optogenetics to produce analgesia in freely behaving mice through the inhibition of nociceptive afferents via archaerhodopsin. Epidural optogenetics provides a robust and powerful solution for activation of both excitatory and inhibitory opsins in sensory processing pathways. Our results demonstrate the potential of spinal optogenetics to modulate sensory behavior and produce analgesia in freely behaving animals.

MATERIALS
Product Number
Brand
Product Description

Sigma-Aldrich
Anti-Calcitonin Gene Related Peptide antibody produced in rabbit, whole antiserum
Sigma-Aldrich
Anti-NeuN Antibody, clone A60, clone A60, Chemicon®, from mouse