Estrogen-dependent visceral hypersensitivity following stress in rats

Hubbard, Catherine S.; Karpowicz, Jane M; Furman, Andrew J.; Silva, Joyce T. Da; Seminowicz, David A.; Traub, Richard J.

doi:10.1177/1744806916654145

Cited by 29 publications

(29 citation statements)

References 54 publications

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“…Several experimental studies found that estrogen has an activational effect on modulating visceral sensitivity, 20 which could acts at multiple sites in the nerve system and facilitate spinal or supraspinal processing of visceral nociception. 21,22 Through observing the changes of defecation in different periods after neonatal MS, we found that the fecal output pellets of MS rats were significantly different from NC rats on PND35 and PND56, which suggest that MS rats showed alternating diarrhea and constipation change from the prepubertal to the adult stage.…”

Section: Discussionmentioning

confidence: 91%

Maternal Separation Induced Visceral Hypersensitivity from Childhood to Adulthood

Zhang

Sun

et al. 2017

J Neurogastroenterol Motil

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Background/AimsEarly adverse life events (EALs) are relevant to irritable bowel syndrome in adulthood. Maternal separation (MS), as one of the EALs, has proved to induce visceral hypersensitivity in adult rats. However, the effect of MS on visceral hypersensitvity from the post-weaning period to adulthood remains unknown. MethodsOne hundred and ten neonatal Sprague-Dawley rats were randomly divided into 2 groups: rats in the MS group were exposed to 3 hours daily MS on postnatal day (PND) 2-14; the normal control (NC) group remained undisturbed. Visceral sensitivity was determined by measuring the visceromotor response to colorectal distention on PND21, 35, and 56. Anxiety-like behaviors were measured by the open field test. ResultsCompared with NC rats, MS rats showed significant visceral hypersensitivity from the post-weaning period to adult. The proportion of visceral hypersensitive rats decreased with age from 87.5% to 70.0% in the female MS group and from 90.0% to 66.7% in the male MS group. The relative VMR ratio of MS and NC on PND21 was higher than PND35 and PND56. MS rats showed decreased ability of movement and exploration to the novel environment in the post-weaning period, obesity in the prepubertal period, and more anxietylike behaviors in adulthood. ConclusionsMS can significantly affect visceral sensitivity and behaviors of rats in different age stages, especially in the post-weaning period. Visceral hypersensitivity of MS rats is more pronounced in the post-weaning period and slightly restored in adults. Thus, visceral hypersensitivity in the post-weaning period might play a more meaningful pathophysiologic role in the formation of adult irritable bowel syndrome.

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Section: Discussionmentioning

confidence: 91%

Maternal Separation Induced Visceral Hypersensitivity from Childhood to Adulthood

Zhang

Sun

et al. 2017

J Neurogastroenterol Motil

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“…However, to harness the true power of single-cell RNA-sequencing, it should be conducted on sensory neurones of known anatomical innervation, i.e., through use of retrograde labelling techniques, because this technique has been used to show that neurones innervating different tissues have distinct properties. For example, NaV1.7 is expressed in NaV1.8-positive colonic neurones and yet mice lacking NaV1.7 in NaV1.8-positive neurones although having diminished somatic pain, experience normal visceral pain [ 28 ]; articular neurones have smaller acid responses, but greater likelihood of responding to ATP than cutaneous neurones [ 29 ], and of all 6 ASIC subunits, ASIC3 mediates acid-excitation of dural, corneal, and cardiac afferents, possibly contributing to the pain of headache, corneal pathologies, and cardiac ischaemia, respectively [ 30 – 32 ].…”

Section: Nociceptors: Transducers Of Painmentioning

confidence: 99%

Advances in understanding nociception and neuropathic pain

Smith

2017

J Neurol

167

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Pain results from the activation of a subset of sensory neurones termed nociceptors and has evolved as a “detect and protect” mechanism. However, lesion or disease in the sensory system can result in neuropathic pain, which serves no protective function. Understanding how the sensory nervous system works and what changes occur in neuropathic pain are vital in identifying new therapeutic targets and developing novel analgesics. In recent years, technologies such as optogenetics and RNA-sequencing have been developed, which alongside the more traditional use of animal neuropathic pain models and insights from genetic variations in humans have enabled significant advances to be made in the mechanistic understanding of neuropathic pain.

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“…5,13,59,70 Six recent animal functional MRI (fMRI) studies have contributed to the field through the advantages of using longitudinal investigations paired with pharmacological and nonpharmacological interventions. 17,40,46,61,75,88 In addition, at the end of the imaging protocol, brain or other tissue of interest can be processed to further elucidate mechanisms and correlate changes in neuroimaging with molecular aspects of the tissue.…”

Section: Introductionmentioning

confidence: 99%

Neuroimaging of pain in animal models: a review of recent literature

Silva

Seminowicz

2019

PR9

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Neuroimaging of pain in animals allows us to better understand mechanisms of pain processing and modulation. In this review, we discuss recently published brain imaging studies in rats, mice, and monkeys, including functional magnetic resonance imaging (MRI), manganese-enhanced MRI, positron emission tomography, and electroencephalography. We provide an overview of innovations and limitations in neuroimaging techniques, as well as results of functional brain imaging studies of pain from January 1, 2016, to October 10, 2018. We then discuss how future investigations can address some bias and gaps in the field. Despite the limitations of neuroimaging techniques, the 28 studies reinforced that transition from acute to chronic pain entails considerable changes in brain function. Brain activations in acute pain were in areas more related to the sensory aspect of noxious stimulation, including primary somatosensory cortex, insula, cingulate cortex, thalamus, retrosplenial cortex, and periaqueductal gray. Pharmacological and nonpharmacological treatments modulated these brain regions in several pain models. On the other hand, in chronic pain models, brain activity was observed in regions commonly associated with emotion and motivation, including prefrontal cortex, anterior cingulate cortex, hippocampus, amygdala, basal ganglia, and nucleus accumbens. Neuroimaging of pain in animals holds great promise for advancing our knowledge of brain function and allowing us to expand human subject research. Additional research is needed to address effects of anesthesia, analysis approaches, sex bias and omission, and potential effects of development and aging.

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Estrogen-dependent visceral hypersensitivity following stress in rats

Cited by 29 publications

References 54 publications

Maternal Separation Induced Visceral Hypersensitivity from Childhood to Adulthood

Maternal Separation Induced Visceral Hypersensitivity from Childhood to Adulthood

Advances in understanding nociception and neuropathic pain

Neuroimaging of pain in animal models: a review of recent literature

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