Neuronal Activation in the Periaqueductal Gray Matter Upon Electrical Stimulation of the Bladder

Meriaux, Céline; Hohnen, Ramona; Schipper, Sandra; Zare, Aryo; Jahanshahi, Ali; Birder, Lori A.; Temel, Yasin; Koeveringe, Gommert van

doi:10.3389/fncel.2018.00133

Cited by 13 publications

(15 citation statements)

References 102 publications

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“…Animal studies, using tract tracing, electrical stimulation, lesioning, and neural recording techniques were instrumental in identifying key subcortical regions important for bladder control, including the PMC which represents the major outflow tract to initiate micturition (Loewy et al, 1979; Holstege et al, 1986; Blok and Holstege, 1997), the pontine continence center (Holstege et al, 1986; Griffiths et al, 1990), the PAG, which receives afferent information about bladder filling and may be significant in switching from storage to voiding mode (Noto et al, 1991; Blok et al, 1995; Liu et al, 2004), and the globus pallidus (Lewin and Porter, 1965; Porter et al, 1971), amongst many others. Of particular relevance to the ANS, the role of the locus coeruleus (LC) in bladder control has been demonstrated (Valentino et al, 1996); the LC is activated along with the PMC, by PAG stimulation (Meriaux et al, 2018) and displays neuronal activity that temporally correlates with the initiation of micturition (Manohar et al, 2017). More recently, newer techniques such as optogenetics and fiber photometry have built on earlier studies to deepen insights into the supraspinal pathways involved in bladder control.…”

Section: Supraspinal Organization Of Bladder Conrol and Overlap With mentioning

confidence: 99%

The Central Autonomic Network and Regulation of Bladder Function

Roy

Green

2019

Front. Neurosci.

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The autonomic nervous system (ANS) is involved in the regulation of physiologic and homeostatic parameters relating particularly to the visceral organs and the co-ordination of physiological responses to threat. Blood pressure and heart rate, respiration, pupillomotor reactivity, sexual function, gastrointestinal secretions and motility, and urine storage and micturition are all under a degree of ANS control. Furthermore, there is close integration between the ANS and other neural functions such as emotion and cognition, and thus brain regions that are known to be important for autonomic control are also implicated in emotional functions. In this review we explore the role of the central ANS in the control of the bladder, and the implications of this for bladder dysfunction in diseases of the ANS.

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Section: Supraspinal Organization Of Bladder Conrol and Overlap With mentioning

confidence: 99%

The Central Autonomic Network and Regulation of Bladder Function

Roy

Green

2019

Front. Neurosci.

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“…The PAG is centrally located in the hierarchical system of micturition control, and is assumed to serve as a relay station projecting afferent information from the bladder to cortical and subcortical brain areas and as a gatekeeper projecting efferent information from these higher areas to the pontine micturition center and ON 2‐4 . The PAG is organized in a symmetrical columnar fashion, and the ventrolateral PAG and dorsolateral PAG are indicated to be involved in the control of voiding and storage of urine respectively 5‐8 . Patients with selective lesions of the PAG are known to present with micturitional disturbances 9‐11 .…”

Section: Introductionmentioning

confidence: 99%

Parcellation of human periaqueductal gray at 7‐T fMRI in full and empty bladder state: The foundation to study dynamic connectivity changes related to lower urinary tract functioning

Rijk

Hurk²,

Rahnama’i

et al. 2021

Neurourology and Urodynamics

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The periaqueductal gray (PAG) is a brain stem area involved in processing signals related to urine storage and voiding. The PAG is proposed to be responsible for projecting afferent information from the bladder to cortical and subcortical brain areas and acts as a relay station projecting efferent information from cortical and subcortical areas to the pons and spinal cord. Here, we use 7-Tesla functional magnetic resonance imaging to parcellate the PAG into functionally distinct clusters during a bladder filling protocol. Methods: We assess the similarity between parcellation results in empty and full bladder states and show how these parcellations can be used to create dynamic response profiles of connectivity changes between clusters as a function of bladder sensations. Results: For each of our six healthy female participants, we found that the agreement between at least one of the clusters in both states resulting from the parcellation procedure was higher than could be expected based on chance (p ≤ .05), and observed that these clusters are significantly organized in a symmetrical lateralized fashion (p ≤ .05). Correlations between clusters change significantly as a function of experienced sensations during bladder filling (p ≤ .05). Conclusions: This opens new possibilities to investigate the effects of treatments of lower urinary tract symptoms on signal processing in the PAG, as well as the investigation of disease-specific bladder filling related dynamic signal processing in this small brain structure.

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“…PET imaging in humans has found that PAG activity correlates with bladder volume [26]. Histology in the rat has identified a subset of excitatory ventrolateral (vl)PAG neurons that are active in response to bladder stimulation [27,28]. These findings have been supported by single unit recordings in the PAG of anesthetized cats revealing two populations of neurons with tonic activity throughout the cycle, one predominating during urine storage and another with greater activity during discharge [29].…”

Section: Transmitting Bladder State To the Brainmentioning

confidence: 99%

“…Electrical stimulation of the bladder muscle also evokes neural activity in the locus coeruleus (LC) [28] (Figure 2b), and LC neurons have been shown to be activated during bladder distention [30]. LC activity is relevant because it houses neurons that release norepinephrine to promote alertness and arousal [31] which is often the perceptual brain state that occurs during the human experience of bladder fullness and urgency to void.…”

Section: Transmitting Bladder State To the Brainmentioning

confidence: 99%

Choosing to urinate. Circuits and mechanisms underlying voluntary urination

Mukhopadhyay

Stowers²

2020

Current Opinion in Neurobiology

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The decision to urinate is a social behavior that is calculated multiple times a day. Many animals perform urine scent-marking which broadcasts their pheromones to regulate the behavior of others and humans are trained at an early age to urinate only at a socially acceptable time and place. The inability to control when and where to void, incontinence, causes extreme social discomfort yet targeted therapeutics are lacking because little is known about the underlying circuits and mechanisms. The use of animal models, neurocircuit analysis, and functional manipulation is beginning to reveal basic logic of the circuit that modulates the decision of when and where to void.

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Neuronal Activation in the Periaqueductal Gray Matter Upon Electrical Stimulation of the Bladder

Cited by 13 publications

References 102 publications

The Central Autonomic Network and Regulation of Bladder Function

The Central Autonomic Network and Regulation of Bladder Function

Parcellation of human periaqueductal gray at 7‐T fMRI in full and empty bladder state: The foundation to study dynamic connectivity changes related to lower urinary tract functioning

Choosing to urinate. Circuits and mechanisms underlying voluntary urination

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