Project description:Brain and Genetic Predictors of Placebo Analgesia

Project description:For over a millennium, mind-body interactions have fascinated scientists and doctors for their abilities to shape human perceptions of the external world 1,2. Placebo effects are striking demonstrations of mind-body interactions in which, in the absence of any treatment, a positive expectation of pain relief can reduce or even abolish the experience of pain 3–6. However, despite widespread recognition of the strength of placebo effects and their impact on everyday human experience and clinical trials for new analgesics, the neural circuit basis of the placebo effect has remained a mystery. Here, we show that analgesia from the expectation of pain relief is mediated by a distinct population of rostral anterior cingulate cortex (rACC) neurons that project to the pontine nuclei (rACC→Pn), a pair of brainstem pre-cerebellar nuclei with no established function in pain processing. To do this, we created a behavioral assay that models placebo analgesia by conditioning mice to expect pain relief when moving from a chamber with a heated floor to a second chamber. In this assay, an expectation of pain relief induces an analgesic effect that, like placebo analgesia in humans, is mediated by endogenous opioids. Calcium imaging of neural activity in freely moving mice and electrophysiological studies in cingulate cortical brain slices showed that expectations of pain relief boost the activity of rACC→Pn neurons and potentiate neurotransmission in this pathway. Transcriptomic studies of Pn neurons revealed an unusual abundance of opioid receptors in these cells, further suggesting a role in pain modulation. Selective inhibition of either the rACC→Pn pathway or of opioid-receptor-expressing Pn neurons disrupted placebo analgesia and decreased pain thresholds. Finally, a subset of cerebellar Purkinje cells exhibits activity patterns resembling those of rACC→Pn neurons during pain relief expectation, providing cellular-level evidence of a role for the cerebellum in cognitive pain modulation. Altogether, these findings elucidate longstanding mysteries surrounding the placebo effect by identifying a specific neural pathway that mediates expectation-based pain relief. This discovery opens the possibility of targeting this novel pathway with drugs or neurostimulation methods to treat pain. More broadly, our studies provide a framework for investigating the neural circuit basis of other mind-body interactions beyond those involving pain, and point to prefrontocortical-cerebellar communication as a potential basis for such effects.

Project description:For over a millennium, mind-body interactions have fascinated scientists and doctors for their abilities to shape human perceptions of the external world 1,2. Placebo effects are striking demonstrations of mind-body interactions in which, in the absence of any treatment, a positive expectation of pain relief can reduce or even abolish the experience of pain 3–6. However, despite widespread recognition of the strength of placebo effects and their impact on everyday human experience and clinical trials for new analgesics, the neural circuit basis of the placebo effect has remained a mystery. Here, we show that analgesia from the expectation of pain relief is mediated by a distinct population of rostral anterior cingulate cortex (rACC) neurons that project to the pontine nuclei (rACC→Pn), a pair of brainstem pre-cerebellar nuclei with no established function in pain processing. To do this, we created a behavioral assay that models placebo analgesia by conditioning mice to expect pain relief when moving from a chamber with a heated floor to a second chamber. In this assay, an expectation of pain relief induces an analgesic effect that, like placebo analgesia in humans, is mediated by endogenous opioids. Calcium imaging of neural activity in freely moving mice and electrophysiological studies in cingulate cortical brain slices showed that expectations of pain relief boost the activity of rACC→Pn neurons and potentiate neurotransmission in this pathway. Transcriptomic studies of Pn neurons revealed an unusual abundance of opioid receptors in these cells, further suggesting a role in pain modulation. Selective inhibition of either the rACC→Pn pathway or of opioid-receptor-expressing Pn neurons disrupted placebo analgesia and decreased pain thresholds. Finally, a subset of cerebellar Purkinje cells exhibits activity patterns resembling those of rACC→Pn neurons during pain relief expectation, providing cellular-level evidence of a role for the cerebellum in cognitive pain modulation. Altogether, these findings elucidate longstanding mysteries surrounding the placebo effect by identifying a specific neural pathway that mediates expectation-based pain relief. This discovery opens the possibility of targeting this novel pathway with drugs or neurostimulation methods to treat pain. More broadly, our studies provide a framework for investigating the neural circuit basis of other mind-body interactions beyond those involving pain, and point to prefrontocortical-cerebellar communication as a potential basis for such effects.

Project description:In this proof-of-concept study, we tested whether placebo effects can be monitored and predicted by plasma proteins. In a randomized controlled design, 90 participants were exposed to a nauseating stimulus on two separate days and were randomly allocated to placebo treatment or no treatment on the second day. Significant placebo effects on nausea, motion sickness, and gastric activity could be verified. Using state-of-the-art proteomics, 74 differentially regulated proteins were identified as correlates of the placebo effect. Gene ontology (GO) enrichment analyses identified acute-phase proteins and microinflammatory proteins to be involved, and the identified GO signatures predicted day-adjusted scores of nausea indices in the placebo group. We also performed GO enrichment analyses of specific plasma proteins predictable by the experimental factors or their interactions and identified ‘grooming behavior’ as a prominent hit. Finally, Receiver Operator Characteristics allowed to identify plasma proteins differentiating placebo responders from non-responders, comprising immunoglobulins and proteins involved in oxidation reduction processes and complement activation. Plasma proteomics are a promising tool to identify molecular correlates and predictors of the placebo effect in humans.

Project description:Genetic Predictors of Polybrominated biphenyl (PBB) Elimination

Project description:Genetic Predictors of Polybrominated biphenyl (PBB) Elimination

Project description:Personality traits have been shown to interact with environmental cues to modulate biological responses including treatment responses, and potentially having a role in the formation of placebo effects. Here, we assessed psychological traits in 50 healthy controls as to their capacity to predict placebo analgesic effects, placebo-induced activation of ?-opioid neurotransmission and changes in cortisol plasma levels during a sustained experimental pain challenge (hypertonic saline infused in the masseter muscle) with and without placebo administration. Statistical analyses showed that an aggregate of scores from Ego-Resiliency, NEO Altruism, NEO Straightforwardness (positive predictors) and NEO Angry Hostility (negative predictor) scales accounted for 25% of the variance in placebo analgesic responses. Molecular imaging showed that subjects scoring above the median in a composite of those trait measures also presented greater placebo-induced activation of ?-opioid neurotransmission in the subgenual and dorsal anterior cingulate cortex (ACC), orbitofrontal cortex, insula, nucleus accumbens, amygdala and periaqueductal gray (PAG). Endogenous opioid release in the dorsal ACC and PAG was positively correlated with placebo-induced reductions in pain ratings. Significant reductions in cortisol levels were observed during placebo administration and were positively correlated with decreases in pain ratings, ?-opioid system activation in the dorsal ACC and PAG, and as a trend, negatively with NEO Angry Hostility scores. Our results show that personality traits explain a substantial proportion of the variance in placebo analgesic responses and are further associated with activations in endogenous opioid neurotransmission, and as a trend cortisol plasma levels. This initial data, if replicated in larger sample, suggest that simple trait measures easily deployable in the field could be utilized to reduce variability in clinical trials, but may also point to measures of individual resiliency in the face of aversive stimuli such as persistent pain and potentially other stressors.

Project description:Mimicking opioid analgesia in cortical pain circuits

Project description:Sickle cell disease is the most common genetic disorder in African-Americans. The opioid analgesic, morphine, has long been the treatment for the severe pain associated with this disease. Here we reveal that the opioid antagonist, naloxone, possesses potent analgesic activity in two strains of sickle cell mice (NY1DD and hBERK1) and not in their respective controls (ICR-CD1 and C57BL/6J) when administered by three parenteral routes. In the NY1DD sickle mice, naloxone (i.c.v.) possessed ~300-fold greater potency than morphine (i.c.v.). Other opioid antagonists (naltrexone, norbinaltorphimine, naltrindole) were substantially less effective in producing analgesia. Naloxone and morphine were synergistic in NY1DD mice, suggesting that analgesia was mediated via different receptor systems. Since microarray analysis suggested naloxone-induced down-regulation of the CCR5 chemokine receptor in NY1DD mice but not in control mice, the role of its endogenous ligand, CCL5 (RANTES), was investigated. Keywords: Comparison of drug induced gene expression

Project description:Sickle cell disease is the most common genetic disorder in African-Americans. The opioid analgesic, morphine, has long been the treatment for the severe pain associated with this disease. Here we reveal that the opioid antagonist, naloxone, possesses potent analgesic activity in two strains of sickle cell mice (NY1DD and hBERK1) and not in their respective controls (ICR-CD1 and C57BL/6J) when administered by three parenteral routes. In the NY1DD sickle mice, naloxone (i.c.v.) possessed ~300-fold greater potency than morphine (i.c.v.). Other opioid antagonists (naltrexone, norbinaltorphimine, naltrindole) were substantially less effective in producing analgesia. Naloxone and morphine were synergistic in NY1DD mice, suggesting that analgesia was mediated via different receptor systems. Since microarray analysis suggested naloxone-induced down-regulation of the CCR5 chemokine receptor in NY1DD mice but not in control mice, the role of its endogenous ligand, CCL5 (RANTES), was investigated. Keywords: Comparison of drug induced gene expression