Your search keyword '"Bridget Matikainen-Ankney"' showing total 7 results

1. Ventral arkypallidal neurons inhibit accumbal firing to promote reward consumption

Author

Claire E. Le Pichon, Olivia Uddin, Kavitha Abiraman, Hanna Silberberg, Eric Casey, Jessica R. Tooley, Bridget Matikainen-Ankney, Leana M. Ramos, Elizabeth Godynyuk, Lauren Marconi, Yvan M. Vachez, Tom Earnest, and Meaghan C. Creed

Subjects

0301 basic medicine, Male, Basal Forebrain, Action Potentials, Drinking Behavior, Biology, Nucleus accumbens, Nucleus Accumbens, Article, Feedback, Ventral pallidum, Reward processing, 03 medical and health sciences, Mice, 0302 clinical medicine, Reward, Neural Pathways, Biological neural network, Animals, Palatability, Consumption (economics), Neurons, Extramural, General Neuroscience, Neural Inhibition, 030104 developmental biology, nervous system, Taste, Calcium, Female, Neuroscience, 030217 neurology & neurosurgery, psychological phenomena and processes

Abstract

The nucleus accumbens shell (NAcSh) and the ventral pallidum (VP) are critical for reward processing, although the question of how coordinated activity within these nuclei orchestrates reward valuation and consumption remains unclear. Inhibition of NAcSh firing is necessary for reward consumption, but the source of this inhibition remains unknown. Here, we report that a subpopulation of VP neurons, the ventral arkypallidal (vArky) neurons, project back to the NAcSh, where they inhibit NAcSh neurons in vivo in mice. Consistent with this pathway driving reward consumption via inhibition of the NAcSh, calcium activity of vArky neurons scaled with reward palatability (which was dissociable from reward seeking) and predicted the subsequent drinking behavior during a free-access paradigm. Activation of the VP–NAcSh pathway increased ongoing reward consumption while amplifying hedonic reactions to reward. These results establish a pivotal role for vArky neurons in the promotion of reward consumption through modulation of NAcSh firing in a value-dependent manner. Inhibition of nucleus accumbens neurons is crucial for reward consumption. Vachez, Tooley et al. characterize arkypallidal neurons in the ventral pallidum that inhibit accumbal neurons to sustain reward consumption in a value-dependent manner.

Published

2021

2. An open-source device for measuring food intake and operant behavior in rodent home-cages

Author

Alexander Reichenbach, Laura B. Murdaugh, Kia M. Barclay, Matthew W. Buczynski, Alexxai V. Kravitz, Mohamed A. Ali, Katrina P. Nguyen, Alex A. Legaria, Amy K. Sutton, Michael J. Krashes, Ream Al-Hasani, Makenzie R Norris, Victor A. Cazares, Rachel E. Clarke, Eric Casey, Bridget Matikainen-Ankney, Eric Lin, Romana Stark, Jordan G. McCall, Justin Wang, Filipe Carvalho, Zane B. Andrews, Thomas Earnest, Meaghan C. Creed, Yu-Hsuan Chang, and Sineadh M. Conway

Subjects

Male, 0301 basic medicine, Food intake, QH301-705.5, Science, Applied psychology, Rodentia, Anorexia nervosa, Monitoring food intake, General Biochemistry, Genetics and Molecular Biology, Eating, Mice, 03 medical and health sciences, 0302 clinical medicine, Intervention (counseling), self-stimulation, medicine, Animals, Food pellet, Animal Husbandry, Biology (General), open-source, Meal patterns, General Immunology and Microbiology, General Neuroscience, digestive, oral, and skin physiology, operant behavior, Equipment Design, Feeding Behavior, General Medicine, medicine.disease, Housing, Animal, 030104 developmental biology, Open source, circadian, Conditioning, Operant, Medicine, Female, Psychology, 030217 neurology & neurosurgery, feeding

Abstract

Feeding is critical for survival, and disruption in the mechanisms that govern food intake underlies disorders such as obesity and anorexia nervosa. It is important to understand both food intake and food motivation to reveal mechanisms underlying feeding disorders. Operant behavioral testing can be used to measure the motivational component to feeding, but most food intake monitoring systems do not measure operant behavior. Here, we present a new solution for monitoring both food intake and motivation in rodent home-cages: the Feeding Experimentation Device version 3 (FED3). FED3 measures food intake and operant behavior in rodent home-cages, enabling longitudinal studies of feeding behavior with minimal experimenter intervention. It has a programmable output for synchronizing behavior with optogenetic stimulation or neural recordings. Finally, FED3 design files are open-source and freely available, allowing researchers to modify FED3 to suit their needs.Obesity and anorexia nervosa are two health conditions related to food intake. Researchers studying these disorders in animal models need to both measure food intake and assess behavioural factors: that is, why animals seek and consume food. Measuring an animal’s food intake is usually done by weighing food containers. However, this can be inaccurate due to the small amount of food that rodents eat. As for studying feeding motivation, this can involve calculating the number of times an animal presses a lever to receive a food pellet. These tests are typically conducted in hour-long sessions in temporary testing cages, called operant boxes. Yet, these tests only measure a brief period of a rodent's life. In addition, it takes rodents time to adjust to these foreign environments, which can introduce stress and may alter their feeding behaviour. To address this, Matikainen-Ankney, Earnest, Ali et al. developed a device for monitoring food intake and feeding behaviours around the clock in rodent home cages with minimal experimenter intervention. This ‘Feeding Experimentation Device’ (FED3) features a pellet dispenser and two ‘nose-poke’ sensors to measure total food intake, as well as motivation for and learning about food rewards. The battery-powered, wire-free device fits in standard home cages, enabling long-term studies of feeding behaviour with minimal intervention from investigators and less stress on the animals. This means researchers can relate data to circadian rhythms and meal patterns, as Matikainen-Ankney did here. Moreover, the device software is open-source so researchers can customise it to suit their experimental needs. It can also be programmed to synchronise with other instruments used in animal experiments, or across labs running the same behavioural tasks for multi-site studies. Used in this way, it could help improve reproducibility and reliability of results from such studies. In summary, Matikainen-Ankney et al. have presented a new practical solution for studying food-related behaviours in mice and rats. Not only could the device be useful to researchers, it may also be suitable to use in educational settings such as teaching labs and classrooms.

Published

2021

3. Optogenetically-inspired neuromodulation: Translating basic discoveries into therapeutic strategies

Author

Caitlin A. Murphy, Meaghan C. Creed, Yu-Hsuan Chang, Bryan A. Copits, and Bridget Matikainen-Ankney

Subjects

Deep brain stimulation, business.industry, medicine.medical_treatment, Synaptic plasticity, Biological neural network, Medicine, Channelrhodopsin, Context (language use), Optogenetics, business, Compulsive disorders, Neuroscience, Neuromodulation (medicine)

Abstract

Optogenetic tools allow for the selective activation, inhibition or modulation of genetically-defined neural circuits with incredible temporal precision. Over the past decade, application of these tools in preclinical models of psychiatric disease has advanced our understanding the neural circuit basis of maladaptive behaviors in these disorders. Despite their power as an investigational tool, optogenetics cannot yet be applied in the clinical for the treatment of neurological and psychiatric disorders. To date, deep brain stimulation (DBS) is the only clinical treatment that can be used to achieve circuit-specific neuromodulation in the context of psychiatric. Despite its increasing clinical indications, the mechanisms underlying the therapeutic effects of DBS for psychiatric disorders are poorly understood, which makes optimization difficult. We discuss the variety of optogenetic tools available for preclinical research, and how these tools have been leveraged to reverse-engineer the mechanisms underlying DBS for movement and compulsive disorders. We review studies that have used optogenetics to induce plasticity within defined basal ganglia circuits, to alter neural circuit function and evaluate the corresponding effects on motor and compulsive behaviors. While not immediately applicable to patient populations, the translational power of optogenetics is in inspiring novel DBS protocols by providing a rationale for targeting defined neural circuits to ameliorate specific behavioral symptoms, and by establishing optimal stimulation paradigms that could selectively compensate for pathological synaptic plasticity within these defined neural circuits.

Published

2021

4. Getting Excited About Learning

Author

Bridget Matikainen-Ankney

Subjects

Excited state, Atomic physics

Published

2021

5. Feeding Experimentation Device version 3 (FED3): An open-source home-cage compatible device for measuring food intake and operant behavior

Author

Romana Stark, Rachel E. Clarke, Alexxai V. Kravitz, Michael J. Krashes, Sineadh M. Conway, Ream Al-Hasani, Kia M. Barclay, Matthew W. Buczynski, Mohamed Ismail Mohamed Ali, Jordan G. McCall, Victor A. Cazares, Filipe Carvalho, Katrina P. Nguyen, Alex A. Legaria, Eric Casey, Bridget Matikainen-Ankney, Thomas Earnest, Yu-Hsuan Chang, Amy K. Sutton, Meaghan C. Creed, Zane B. Andrews, Alexander Reichenbach, Laura B. Murdaugh, Eric Lin, and Makenzie R Norris

Subjects

Food intake, Open source, Feeding behavior, Behavioral testing, Home cage, Food motivation, Operant conditioning, Feeding patterns, Psychology, Developmental psychology

Abstract

SummaryFeeding is critical for survival and disruption in the mechanisms that govern food intake underlie disorders such as obesity and anorexia nervosa. It is important to understand both food intake and food motivation to reveal mechanisms underlying feeding disorders. Operant behavioral testing can be used to measure the motivational component to feeding, but most food intake monitoring systems do not measure operant behavior. Here, we present a new solution for monitoring both food intake and motivation: The Feeding Experimentation Device version 3 (FED3). FED3 measures food intake and operant behavior in rodent home-cages, enabling longitudinal studies of feeding behavior with minimal experimenter intervention. It has a programmable output for synchronizing behavior with optogenetic stimulation or neural recordings. Finally, FED3 design files are open-source and freely available, allowing researchers to modify FED3 to suit their needs. In this paper we demonstrate the utility of FED3 in a range of experimental paradigms.In BriefUsing a novel, high-throughput home cage feeding platform, FED3, Matikainen-Ankney et al. quantify food intake and operant learning in groups of mice conducted at multiple institutions across the globe. Results include rates of operant efficiency, circadian feeding patterns, and operant optogenetic self-stimulation.HighlightsThe Feeding Experimentation Device version 3(FED3) records food intake and operant behavior in rodent home cages.Analysis of food intake includes total intake, meal pattern analysis, and circadian analysis of feeding patterns.FED3 also allows for operant behavioral assays to examine food learning and motivation.

Published

2020

6. Motor Control: Memory and Motor Control in the Dorsal Striatum

Author

Bridget Matikainen-Ankney and Alexxai V. Kravitz

Subjects

0301 basic medicine, Dorsum, Motor control, Striatum, Biology, General Biochemistry, Genetics and Molecular Biology, Procedural memory, Corpus Striatum, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Memory, Learning, General Agricultural and Biological Sciences, Control (linguistics), Neuroscience, 030217 neurology & neurosurgery

Abstract

The dorsal striatum is important for motor control. Yet whether that control encompasses procedural memories, kinematic refinement, or both is still debated. A recent study has shed new light on the role of the dorsal striatum in learned movement sequences and the effort required to refine them.

Published

2020

7. Orexin signaling in GABAergic lateral habenula neurons modulates aggressive behavior in male mice

Author

Meghan E, Flanigan, Hossein, Aleyasin, Long, Li, C Joseph, Burnett, Kenny L, Chan, Katherine B, LeClair, Elizabeth K, Lucas, Bridget, Matikainen-Ankney, Romain, Durand-de Cuttoli, Aki, Takahashi, Caroline, Menard, Madeline L, Pfau, Sam A, Golden, Sylvain, Bouchard, Erin S, Calipari, Eric J, Nestler, Ralph J, DiLeone, Akihiro, Yamanaka, George W, Huntley, Roger L, Clem, and Scott J, Russo

Subjects

Aggression, Male, Habenula, Mice, Orexins, Animals, GABAergic Neurons, Signal Transduction

Abstract

Heightened aggression is characteristic of multiple neuropsychiatric disorders and can have various negative effects on patients, their families and the public. Recent studies in humans and animals have implicated brain reward circuits in aggression and suggest that, in subsets of aggressive individuals, domination of subordinate social targets is reinforcing. In this study, we showed that, in male mice, orexin neurons in the lateral hypothalamus activated a small population of glutamic acid decarboxylase 2 (GAD2)-expressing neurons in the lateral habenula (LHb) via orexin receptor 2 (OxR2) and that activation of these GAD2 neurons promoted male-male aggression and conditioned place preference for aggression-paired contexts. Moreover, LHb GAD2 neurons were inhibitory within the LHb and dampened the activity of the LHb as a whole. These results suggest that the orexin system is important for the regulation of inter-male aggressive behavior and provide the first functional evidence of a local inhibitory circuit within the LHb.

Published

2018