A Neural Circuit for Gut-Induced Reward

Han, Wenfei; Téllez, Luis A.; Perkins, Matthew H.; Perez, Isaac O.; Qu, Taoran; Ferreira, Jozélia Gomes Pacheco; Ferreira, Tatiana Lima; Quinn, Danielle; Liu, Zhongwu; Gao, Xiao‐Bing; Kaelberer, Melanie M.; Bohórquez, Diego V.; Shammah‐Lagnado, Sara J.; Lartigue, Guillaume de; Araújo, Ivan E. de

doi:10.1016/j.cell.2018.10.018

Cited by 212 publications

(230 citation statements)

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“…In line with the hypothesized efferent effect, we found that taVNS alters a marker of energy homeostasis in humans. The observed taVNS-induced reduction in gastric frequency is well in line with previous findings linking VNS to altered energy homeostasis [13,14,17]. This efferent effect on gastric motility might be due to a taVNS-induced release of dopamine in the brain stem.…”

Section: Discussionsupporting

confidence: 91%

“…Such metabolic effects might be related to VNSinduced increases in the activity of brown adipose tissue, which in turn increased the basal metabolic rate [15]. Notably, dopamine has been suggested as a neuromodulator of energy homeostasis within the gut-brain axis [16,17]. Afferently, stimulation of the vagal sensory ganglion in mice was found to induce dopamine release in the substantia nigra [17].…”

Section: Introductionmentioning

confidence: 99%

“…Notably, dopamine has been suggested as a neuromodulator of energy homeostasis within the gut-brain axis [16,17]. Afferently, stimulation of the vagal sensory ganglion in mice was found to induce dopamine release in the substantia nigra [17]. Efferently, dopamine administration to the dorsal vagal complex in rats modulated the upper gastrointestinal tract by reducing gastric tone and motility via DA2 receptors in the dorsal motor nucleus of the vagus [18].…”

Section: Introductionmentioning

confidence: 99%

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Non-invasive stimulation of vagal afferents reduces gastric frequency

Teckentrup¹,

Neubert²,

Santiago³

et al. 2019

Preprint

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Section: Discussionsupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Non-invasive stimulation of vagal afferents reduces gastric frequency

Teckentrup¹,

Neubert²,

Santiago³

et al. 2019

Preprint

View full text Add to dashboard Cite

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“…We chose the 165-minute time-point given that transit time to the mouse stomach and small intestine is ∼1 hour (Padmanabhan et al, 2013; Wehner et al, 2014), both of which are heavily innervated by the vagus nerve (Wang and Powley, 2000), and that c-Fos immunoreactivity in the brain peaks between 1-2 hours (Nestler et al, 2001b; Jung et al, 2014). While the data herein does not necessarily suggest that all of these distributed areas are integral to the effects of the bacteria, it aligns with previous works outlining regions that receive direct or indirect projections from the vagus nerve (Groves and Brown, 2005; Han et al, 2018), and those that are affected by vagal nerve stimulation (VNS)—an approved therapy in the treatment of refractory depression (Naritoku et al, 1995; Chae et al, 2003; Nemeroff et al, 2006; Cunningham et al, 2008; Furmaga et al, 2012; Aaronson et al, 2017). This is particularly relevant given the critical role of the vagus in mediating the behavioural effects of this particular bacterial strain (Bravo et al, 2011; Perez-Burgos et al, 2014).…”

Section: Discussionsupporting

confidence: 86%

The vagus nerve is necessary for the rapid and widespread neuronal activation in the brain following oral administration of psychoactive bacteria

Bharwani

West

Champagne-Jorgensen

et al. 2019

Preprint

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AbstractThere is accumulating evidence that certain gut microbes modulate brain chemistry and have antidepressant-like behavioural effects. However, it is unclear which brain regions respond to bacteria-derived signals or how signals are transmitted to distinct regions. We investigated the role of the vagus in mediating neuronal activation following oral treatment with Lactobacillus rhamnosus (JB-1).Male Balb/c mice were orally administered a single dose of saline or a live or heat-killed preparation of a physiologically active bacterial strain, Lactobacillus rhamnosus (JB-1). 165 minutes later, c-Fos immunoreactivity in the brain was mapped, and mesenteric vagal afferent fibre firing was recorded. Mice also underwent sub-diaphragmatic vagotomy to investigate whether severing the vagus prevented JB-1-induced c-Fos expression. Finally, we examined the ΔFosB response following acute versus chronic bacterial treatment.While a single exposure to live and heat-killed bacteria altered vagal activity, only live treatment induced rapid neural activation in widespread but distinct brain regions, as assessed by c-Fos expression. Sub-diaphragmatic vagotomy abolished c-Fos immunoreactivity in most, but not all, previously responsive regions. Chronic, but not acute treatment induced a distinct pattern of ΔFosB expression, including in previously unresponsive brain regions.These data identify that specific brain regions respond rapidly to gut microbes via vagal-dependent and independent pathways, but suggest long-term exposure is required for the chronic brain activity associated with behavioural changes.

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“…Unveiling spike patterns of the vagus nerve is indispensable to further understand the communication between the brain and visceral organs such as the heart (Hayakawa et al, 2011), digestive organs (Campos et al, 2012;Czaja et al, 2006), and the lung (Han et al, 2018;Weijs et al, 2015). In previous studies, recordings of VN spikes have been performed in anesthetized rodent animals (Caravaca et al, 2017;Harreby et al, 2011;McCallum et al, 2017;Silverman et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

Vagus nerve spiking activity associated with locomotion and cortical arousal states in a freely moving rat

Shikano

Nishimura

Okonogi

et al. 2018

Eur J of Neuroscience

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The vagus nerve serves as a central pathway for communication between the central and peripheral organs. Despite traditional knowledge of vagus nerve functions, detailed neurophysiological dynamics of the vagus nerve in naïve behavior remain to be understood. In this study, we developed a new method to record spiking patterns from the cervical vagus nerve while simultaneously monitoring central and peripheral organ bioelectrical signals in a freely moving rat. When the rats transiently elevated locomotor activity, the frequency of vagus nerve spikes was correspondingly increased, and this activity was retained for several seconds after the increase in running speed terminated. Spike patterns of the vagus nerve were not robustly associated with which arms the animals entered on an elevated plus maze. During sniffing behavior, vagus nerve spikes were nearly absent. During stopping, the vagus nerve spike patterns differed considerably depending on external contexts and peripheral activity states associated with cortical arousal levels. Stimulation of the vagus nerve altered rat's running speed and cortical arousal states depending on running speed at the instant of stimulation. These observations are a new step for uncovering the physiological dynamics of the vagus nerve modulating the visceral organs such as cardiovascular, respiratory, and gastrointestinal systems.

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A Neural Circuit for Gut-Induced Reward

Cited by 212 publications

References 0 publications

Non-invasive stimulation of vagal afferents reduces gastric frequency

Non-invasive stimulation of vagal afferents reduces gastric frequency

The vagus nerve is necessary for the rapid and widespread neuronal activation in the brain following oral administration of psychoactive bacteria

Vagus nerve spiking activity associated with locomotion and cortical arousal states in a freely moving rat

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