Seth H. Walters scite author profile

In vivo fast-scan cyclic voltammetry provides high-fidelity recordings of electrically evoked dopamine release in the rat striatum. The evoked responses are suitable targets for numerical modeling because the frequency and duration of the stimulus are exactly known. Responses recorded in the dorsal and ventral striatum of the rat do not bear out the predictions of a numerical model that assumes the presence of a diffusion gap interposed between the recording electrode and nearby dopamine terminals. Recent findings, however, suggest that dopamine may be subject to restricted diffusion processes in brain extracellular space. A numerical model cast to account for restricted diffusion produces excellent agreement between simulated and observed responses recorded under a broad range of anatomical, stimulus, and pharmacological conditions. The numerical model requires four, and in some cases only three, adjustable parameters and produces meaningful kinetic parameter values.

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Modeling the Kinetic Diversity of Dopamine in the Dorsal Striatum

Walters

Robbins

Michael

2015

ACS Chem. Neurosci.

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Dopamine is an important neurotransmitter that exhibits numerous functions in the healthy, injured, and diseased brain. Fast scan cyclic voltammetry paired with electrical stimulation of dopamine axons is a popular and powerful method for investigating the dynamics of dopamine in the extracellular space. Evidence now suggests that the heterogeneity of electrically evoked dopamine responses reflects the inherent kinetic diversity of dopamine systems, which might contribute to their diversity of physiological function. Dopamine measurements by fast scan cyclic voltammetry are affected by the adsorption of dopamine to carbon fiber electrodes. The temporal distortion caused by dopamine adsorption is correctable by a straightforward mathematical procedure. The corrected responses exhibit excellent agreement with a dopamine kinetic model cast to provide a generic description of restricted diffusion, short-term plasticity of dopamine release, and first-order dopamine clearance. The new DA kinetic model brings to light the rich kinetic information content of electrically evoked dopamine responses recorded via fast scan cyclic voltammetry in the rat dorsal striatum.

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Kinetic diversity of dopamine transmission in the dorsal striatum

Taylor

Nesbitt

Walters

et al. 2015

Journal of Neurochemistry

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Dopamine (DA), a highly significant neurotransmitter in the mammalian central nervous system, operates on multiple time scales to affect a diverse array of physiological functions. The significance of DA in human health is heightened by its role in a variety of pathologies. Voltammetric measurements of electrically evoked dopamine release have brought to light the existence of a patchwork of DA kinetic domains in the dorsal striatum of the rat. Thus, it becomes necessary to consider how these domains might be related to specific aspects of DA's functions. Responses evoked in the fast and slow domains are distinct in both amplitude and temporal profile. Herein we report that responses evoked in fast domains can be further classified into four distinct types, types 1-4. The dorsal striatum, therefore, exhibits a total of at least five distinct evoked responses (4 fast types and 1 slow type). All five response types conform to kinetic models based entirely on first order rate expressions, which indicates that the heterogeneity among the response types arises from kinetic diversity within the dorsal striatum terminal field. We report also that functionally distinct sub-regions of the dorsal striatum express DA kinetic diversity in a selective manner. Thus, this study documents five response types, provides a thorough kinetic explanation for each of them, and confirms their differential association with functionally distinct sub-regions of this key DA terminal field.

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Region‐ and domain‐dependent action of nomifensine

Zhan

Taylor

Walters

et al. 2014

Eur J of Neuroscience

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The dopamine (DA) terminal fields in the rat dorsal striatum (DS) and nucleus accumbens core (NAcc) are organized as patchworks of domains that exhibit distinct kinetics of DA release and clearance. The present study used fast-scan cyclic voltammetry recordings of electrically evoked DA overflow to test the hypothesis that nomifensine might exhibit domain-dependent actions within the NAcc, as we previously found to be the case within the DS. Within the NAcc, nomifensine preferentially enhanced evoked dopamine overflow in the slow compared to the fast domains. To seek a kinetic explanation for nomifensine’s selective actions, we quantified the apparent KM of DA clearance by numerically evaluating the derivative of the descending phase of the DA signal after the end of the stimulus. For comparison, we likewise quantified apparent KM in the domains of the DS. As expected because it is a competitive inhibitor, nomifensine significantly increased the apparent KM in both the fast and slow domains of both the NAcc and DS. However, our analysis also leads to the novel finding that nomifensine preferentially increases the apparent KM in the NAcc compared to the DS: apparent KM increased by ~500% in the NAcc and ~200% in the DS.

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Kinetic Diversity of Striatal Dopamine: Evidence from a Novel Protocol for Voltammetry

Walters

Robbins

Michael

2016

ACS Chem. Neurosci.

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In vivo voltammetry reveals substantial diversity of dopamine kinetics in the rat striatum. To substantiate this kinetic diversity, we evaluate the temporal distortion of dopamine measurements arising from the diffusion-limited adsorption of dopamine to voltammetric microelectrodes. We validate two mathematical procedures for correcting adsorptive distortion, both of which substantiate that dopamine's apparent kinetic diversity is not an adsorption artifact.

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Seth H. Walters

A Novel Restricted Diffusion Model of Evoked Dopamine

Modeling the Kinetic Diversity of Dopamine in the Dorsal Striatum

Kinetic diversity of dopamine transmission in the dorsal striatum

Region‐ and domain‐dependent action of nomifensine

Kinetic Diversity of Striatal Dopamine: Evidence from a Novel Protocol for Voltammetry

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