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Building on previous work (Makin et al., 2013), we show that the brains of individuals born without a hand adaptively change to compensate for their disability.

Aberrant ERK/MAPK signaling in cortical pyramidal neurons leads to selective disruption of layer 5 circuit development and generalized changes in neuronal excitability.

In models of chronic migraine, neuronal complexity is diminished in head-pain processing regions but restored through HDAC6 inhibition, which increases tubulin acetylation and cytoskeletal flexibility, and CGRP receptor blockade.

Spinal excitatory interneurons trigger persistent neural activity in spinal network to generate muscle spasms after spinal cord injury.

Ampakines demonstrate efficacy in enhancing bladder function in animal models of spinal cord injury, presenting promising prospects for innovative pharmacotherapy to alleviate post-injury bladder dysfunction.

A signal amplifier network that transmits mechanical pain is delineated through characterising an excitatory interneuron population in the spinal cord dorsal horn and defining the postsynaptic populations they regulate.

The mTOR downstream effector eukaryotic initiation factor 4E-binding protein 1 (4E-BP1) regulates mechanical nociception via translational control of synaptic transmission in the spinal cord.

Quantitative super-resolution correlative light and electron microscopy reveals a constant glycine receptor density at native spinal cord synapses that is maintained in the oscillator mouse model of human hyperekplexia.

Neural populations in PPC dynamically represent motor-like and then sensory-like aspects of brain–computer interface finger movements with a representational structure that matches able-bodied individuals.

No single molecular change is uniquely necessary to cause neuropathic changes in primary afferent excitability; multiple different changes are sufficient.