The handbook of non-invasive transcranial brain stimulation in the cognitive domain : methods, psychophysiology, neuroenhancement and therapeutic applications / Edited by Vincent Van Waes [and 4 others]

Format:

Book

Contributor:

Van Waes, Vincent, editor.

Series:

Handbook of behavioral neuroscience ; v.Volume 34

Language:

English

Subjects (All):

Magnetic brain stimulation.

Brain stimulation.

Physical Description:

1 online resource (592 pages)

Place of Publication:

London : Academic Press, 2025.

Summary:

The Handbook of Non-Invasive Transcranial Brain Stimulation in the Cognitive Domain serves as an essential resource, capturing the latest advancements and scientific insights into non-invasive brain stimulation methods.

Contents:

Front Cover

THE HANDBOOK OF NONINVASIVE TRANSCRANIAL BRAIN STIMULATION IN THE COGNITIVE DOMAIN

Copyright

Contents

Contributors

Foreword

Preface

1 Methods

1 - The principles and methods of noninvasive transcranial brain stimulation

1. Principles and methods of transcranial magnetic stimulation (TMS)

2. Transcranial direct current stimulation

3. Transcranial alternating current stimulation

4. Summary

References

2 - How to design a NIBS study in the cognitive domain: Common pitfalls and recommendations

1. Introduction

1.1 The promise of causality in cognitive neuroscience

1.2 Challenges associated with the virtual lesion framework

1.3 NIBS effects depend on the interaction of external and internal factors

2. The power and versatility of NIBS

2.1 Let us discontinue the virtual lesion metaphor. NIBS means putting energy into state-dependent brain networks

2.2 Difference between behavioral and neurophysiological inhibition or facilitation

3. What to consider when designing cognitive studies

3.1 Spatial and temporal resolutions of NIBS

3.2 The relevance of electric field modeling for spatial distribution, targeting, and dosing

3.3 Control conditions in cognitive NIBS studies

3.4 Considerations on sham NIBS

4. Now what: Recommendations on how to design a good NIBS study

4.1 Hypothesis-driven research: Choose your experimental design and NIBS technique wisely

4.2 Which control conditions are needed depends on the intended claims

4.3 NIBS combined with EEG/fMRI in cognitive studies

5. Conclusion

2 Preclinic - psychophysiology

Animals

3 - Use of tDCS, rTMS, and TUS in rodents: Contributions to understanding the neurobiological mechanisms involved.

1. Introduction

2. Transcranial magnetic stimulation (TMS)

2.1 Developing experimental setups for small rodents

2.2 TMS application in behavioral neuroscience and neuroplasticity studies

2.3 TMS application in neurodevelopmental, psychiatric, and neurological disorders

2.3.1 Autism spectrum disorder (ASD)

2.3.2 Depression

2.3.3 Cognitive impairment

2.3.4 Stroke

2.3.5 Parkinson's disease

2.4 TMS molecular mechanism on the brain

2.5 Future directions

2.6 Conclusions

3. Transcranial direct current stimulation (tDCS)

3.1 Application of tDCS in small rodents

3.1.1 Mood and psychiatric disorders

3.1.2 Cognitive disorders

3.1.3 Neurological disorders

3.1.4 Pain modulation

3.2 tDCS mechanism in the brain

3.3 Conclusions

4. Transcranial ultrasound stimulation (TUS)

4.1 Principle of TUS

4.2 Methods of TUS in small rodents

4.3 Applications of TUS in small rodents

4.3.1 Cognitive enhancement

4.3.2 Neurological disorders

4.3.3 Neuroplasticity and synaptic plasticity

4.4 Mechanisms of action of TUS

4.5 Conclusions

5. General conclusion

4 - Use of tDCS, rTMS, and TUS in non-human primates: Contributions to understanding the neurobiological mechanisms ...

2. Stimulation parameters for eliciting neural activity

2.1 Transcranial direct current stimulation

2.2 Repetitive transcranial magnetic stimulation

2.3 Transcranial ultrasound stimulation

3. Physiology and state dependence

3.1 Overarching themes and findings

3.2 Results specific to each modality

3.2.1 tDCS

3.2.2 TMS

3.2.3 FUS

4. Behavior and cognition

4.1 Overall approaches

4.2 Results specific to each modality

4.2.1 tDCS

4.2.2 TMS

4.2.3 FUS

5. Conclusions

Acknowledgments

References.

5 - tDCS to treat psychiatric disorders: Insights from animal studies

2. tDCS to treat depression-related behavior

2.1 Antidepressant-like effect of tDCS in naive mice

2.2 Effects of tDCS in rodent models of depression

2.2.1 Behavioral outcomes

2.2.2 Potential mechanisms underlying the behavioral effects of tDCS in rodents

2.2.2.1 tDCS and inflammation

2.2.2.2 tDCS and neurogenesis

2.2.3 Antidepressant-like effects of tDCS in other pathological rodent models

3. tDCS to treat substance use disorders

3.1 tDCS to treat psychostimulant addiction

3.1.1 Nicotine

3.1.2 Cocaine

3.2 tDCS to treat alcohol addiction

3.3 Conclusion

4. tDCS to treat posttraumatic stress disorder

4.1 Treatments of PTSD in humans

4.2 tDCS in rodent models of PTSD

4.2.1 Fear conditioning and extinction as a model of PTSD in rodent

4.2.2 Behavioral effects of tDCS

5. tDCS to treat other neuropsychiatric disorders

5.1 tDCS for ADHD management

5.2 tDCS for Tourette's syndrome management

5.3 tDCS for schizophrenia management

5.4 tDCS for metabolic conditions-induced affective and cognitive disorders management

5.5 tDCS for neuropathic pain-induced sensory, affective and cognitive disorders management

5.6 tDCS for the management of cognitive deficit in vascular dementia and after traumatic brain injury

6. Limitations and opportunities of animal models and future directions

6 - tDCS to treat neurological disorders: Insights from animal studies

1. tDCS effects in experimental models of Alzheimer's disease and other dementias

2. tDCS effects in the modulation of cognitive and affective dimensions of pain

3. tDCS effects to treat cognitive impairments in stroke, traumatic brain injury, and Parkinson's disease

3.1 Stroke

3.2 Traumatic brain injury.

3.3 Parkinson's disease

4. Concluding remarks

7 - Implication of glial cells in the effects of tDCS in mice

1. Introduction: classical view of tDCS mechanism and synaptic plasticity

1.1 What is synaptic plasticity?

1.2 tDCS-induced synaptic plasticity

1.3 How extracellular electric field induce synaptic plasticity?

2. tDCS and subcortical neuromodulators

2.1 Dopamine

2.2 Noradrenaline

2.3 Serotonin

2.4 Acetylcholine

3. Glial cells and their role in the central nervous system

3.1 Astrocytes

3.2 IP3/Ca2+ signaling in astrocytes

3.3 Microglia

4. tDCS mechanisms and glial cells

4.1 tDCS and glial interactions

4.2 The role of glial cells in neuromodulation

4.3 Fighting neuroinflammation

4.4 Conclusion

5. Future perspective: tDCS effect on extracellular milieu (K+ and inflammation)

5.1 tDCS and glial cell interactions

5.2 Regulation of potassium ion dynamics

5.3 Long-term effects and therapeutic applications

5.4 Closing Remarks

8 - Accelerated rTMS in the canine species

1.1 The canine brain model

1.2 Validity of the canine brain model

1.2.1 Face validity

1.2.2 Construct validity

1.2.3 Predictive validity

2. The rTMS protocol and accelerated rTMS in dogs

3. Applicability and feasibility of rTMS in dogs: Optimization of the rTMS protocol

3.1 Anesthesia

3.2 TMS target localization: Neuronavigation

3.3 Cortical threshold determination

3.4 Coil type and coil-to-cortex distance

4. Effects of rTMS on neural activity and neurotransmitter systems in the healthy canine brain

4.1 Neural activity

4.2 Neurotransmitter systems

5. Durability of rTMS effects in the canine brain

5.1 Acute effects

5.2 Delayed effects

5.3 Long-term effects

6. Applications of rTMS in veterinary medicine.

6.1 Dogs with behavioral disorders

6.1.1 Measurements of dog behavior

6.1.2 Neurobiological impact of arTMS in dogs with behavioral disorders

6.1.3 Behavioral impact of arTMS in dogs with behavioral disorders

6.2 Dogs with neurological disorders

7. Conclusion and future directions

AI Disclosure

Healthy

9 - Noninvasive transcranial brain stimulation for the study of perception and attention

1. Introduction on visual perception and attention

1.1 Visual and attentional networks

1.2 Attention, visual performance and conscious perception

2. Spatio-temporal mapping of visual areas through NIBS

2.1 Phosphenes

2.2 Chronometry of bottom-up and feedback processes

3. Causal involvement of attentional networks in visual perception as tested by NIBS

3.1 Top-down influence of fronto-parietal networks on visual perception

3.2 The role of oscillations in attentional modulation of visual perception

4. Impact of NIBS on higher-level awareness: The case of bistable perception

5. Clinical applications of NIBS in the case of visuospatial neglect

5.1 Symptoms of visuospatial neglect and explanatory models

5.2 Alleviating neglect symptoms with NIBS

6. Conclusion

10 - Noninvasive transcranial brain stimulation for the study of decision-making

2. Decision-making as a cognitive process

3. Neural correlates of decision-making

4. Behavioral manifestations of impaired decision-making

5. Noninvasive brain stimulation (NIBS) in modulation of decision-making

6. Risky decision-making

7. Moral decision-making

8. Economic decision-making

9. Conclusion and future direction

11 - Noninvasive transcranial brain stimulation for the study of memory

1. Introduction.

1.1 The intersection of brain stimulation and memory.

Notes:

Description based on publisher supplied metadata and other sources.

Part of the metadata in this record was created by AI, based on the text of the resource.

ISBN:

0-443-26603-4

0-443-26602-6

9780443266034

OCLC:

1561173833