Mechanisms underlying neuropathic pain His most cited publications are two articles in the scientific journal
Nature – together these two publications were cited over 1600 times in 2015. In a 2003
Nature publication, De Koninck and his team showed that pain hypersensitivity in people suffering from
neuropathic pain could be due to a reversal of the mechanisms that suppress pain signals in the
spinal cord. The discovery of this mechanism explaining neuropathic pain was highlighted as one of the top 10 discoveries of 2003 by the magazine Québec Science. Jeffrey Coull, first author of the publication, received the Brain Star of the year award for his work from the
Canadian Institutes of Health Research – Institute of Neuroscience, Mental Health & Addiction. The discovery that the protein called
brain-derived neurotrophic factor (BDNF) is involved in the neuroimmune interactions underlying
chronic pain is listed as one of the milestones in Canadian Health Research by the Canadian Institutes of Health Research. This work was published in
Nature in 2005. In 2013, the De Koninck team reported the identification of a compound that restored the function of a protein called
KCC2, and alleviated pain hypersensitivity in an experimental model of neuropathic pain, suggesting compounds of the kind could be used as novel therapeutics for chronic pain and other neurological diseases in which KCC2 function is disrupted, including
epilepsy,
motor spasticity,
stress,
anxiety,
schizophrenia, and
morphine-induced
hyperalgesia. Marc Bergeron received a CIHR Brain Star Award for this publication. Another study, published in the journal
Brain in 2013 further highlighted the importance of the KCC2 protein in neuropathic pain, as blocking this protein replicated the effect of nerve injury and reduced the threshold for transmission of painful stimuli, a hallmark of
allodynia. Restoring KCC2 function in experimental models with nerve injury conversely restored the threshold. Guillaume Lavertu, first author of this publication, received an Étudiant-chercheur étoile award for this work. Also in 2013 work from the De Koninck laboratory showed mechanisms similar to those involved in neuropathic pain signaling could be involved in morphine-induced hyperalgesia. This research explained why morphine can paradoxically cause pain, and showed that the mechanisms underlying pain hypersensitivity are distinct from those causing morphine
tolerance. This discovery was highlighted as one of the top ten discoveries of 2013 by Québec Science Magazine, and co-first authors Francesco Ferrini and Tuan Trang received 2013 CIHR Brain Star awards for this publication. In 2014, a study published in
Nature Neuroscience showed that pain hypersensitivity could be reversed after being reactivated, in a process similar to
memory reconsolidation. Robert Bonin was named étudiant chercheur étoile of the month of March 2015 for this publication, and received the CIHR-INMHA Brain Star of the year Award for this publication.
Development of optogenetic tools to study neurons The development of a novel probe, capable of recording neuron activity, but also of emitting light to activate cells using
optogenetic approaches was highlighted as one of the discoveries of the year for 2011 by Québec Science.
Neuronal changes associated with aging Work done by Cyril Bories, in the De Koninck laboratory, revealed neurobiological differences in the balance of excitatory and inhibitory signals in the brains of aging rats that could be correlated to alterations in cognitive functions. Cyril Bories received an Age Plus Prize from the Canadian Institutes of Health Research institute of Aging for this publication. ==Awards==