Breathing, emotion and evolution:
Gespeichert in:
| Weitere Verfasser: | |
|---|---|
| Format: | Buch |
| Sprache: | English |
| Veröffentlicht: |
Amsterdam [u.a.]
Elsevier
2014
|
| Ausgabe: | 1. ed. |
| Schriftenreihe: | Progress in brain research
212 |
| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | Comprend des références bibliographiques et un index |
| Beschreibung: | XXII, 399 S. Ill., zahlr. graph. Darst. 24 cm |
| ISBN: | 9780444634887 0444634886 |
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| adam_text | Titel: Breathing, emotion and evolution
Autor: Holstege, Gert
Jahr: 2014
Contents
Contributors...............................................................................................................v
Preface......................................................................................................................xi
CHAPTER 1 Physiological and Pathophysiological
Interactions Between the Respiratory
Central Pattern Generator and the
Sympathetic Nervous System...............................................1
Yaroslav I. Molkov, Daniel B. Zoccal, David M. Baekey,
Ana P.L. Abdala, Benedito H. Machado, Thomas E. Dick,
Julian F.R. Pa ton, llya A. Rybak
1. Introduction.....................................................................................2
2. Respiratory Modulation of Sympathetic Activity..........................2
3. Respiratory Baroreflex....................................................................5
4. Respiratory-sympathetic Chemoreflex..........................................8
5. Chronic Intermittent Hypoxia.......................................................11
6. Unified Theoretical Framework for Respiratory-Sympathetic
Coupling: Limitations and Perspectives.......................................15
Acknowledgments........................................................................18
References.....................................................................................18
CHAPTER 2 Coupling of Respiratory and Sympathetic
Activities in Rats Submitted to Chronic
Intermittent Hypoxia...............................................................25
Davi J.A. Moraes, Benedito H. Machado,
Daniel B. Zoccal
1. Sympathetic Nervous System and Its Interaction
with the Respiratory Network......................................................25
2. Central Mechanisms Underlying Respiratory-Sympathetic
Coupling........................................................................................28
3. Relevance of Respiratory-Sympathetic Coupling
Dysfunctions to the Development of Systemic
Hypertension.................................................................................31
4. Perspectives...................................................................................34
Acknowledgments........................................................................34
References.....................................................................................35
xiv Contents
CHAPTER 3 Function and Modulation of Premotor Brainstem
Parasympathetic Cardiac Neurons that Control
Heart Rate by Hypoxia-, Sleep-, and Sleep-Related
Diseases Including Obstructive Sleep Apnea...............39
Olga Dergacheva, Letitia A. Weigand, Jhansi Dyavanapalli,
Jacquelyn Mares, Xin Wang, David Mendelowitz
1. Introduction...................................................................................40
2. Autonomic Control of Cardiac Function......................................40
3. Responses to Hypoxia...................................................................41
4. Cardiovascular Regulation During Sleep.....................................44
5. Cardiovascular Changes with Sleep-Related Diseases
such as OS A..................................................................................49
6. Conclusions...................................................................................50
Acknowledgments........................................................................50
References.....................................................................................50
CHAPTER 4 Discharge Properties of Upper Airway Motor
Units During Wakefulness and Sleep..............................59
John Trinder, Amy S. Jordan, Christian L. Nicholas
t. Introduction and Background.......................................................60
2. Upper Airway Muscle Recording and Analysis
Techniques....................................................................................61
3. Upper Airway Motor Unit Discharge Patterns............................62
4. Manipulations of Sleep-Wake State and Respiratory
Drive..............................................................................................64
5. Overview.......................................................................................71
References.....................................................................................73
CHAPTER 5 Effects of Calcium (Ca2+) Extrusion Mechanisms
on Electrophysiological Properties in a
Hypoglossal Motoneuron: Insight from a
Mathematical Model..............................................................77
Kyle G. Horn, Irene C. Solomon
1. Introduction...................................................................................78
2. Methods.........................................................................................80
3. Results...........................................................................................83
3.1. Ca2+ Extrusion Mechanisms.................................................83
3.2. Addition of BK Channels—Type I Firing...........................84
3.3. Addition of Ca2+ Buffering—Type D Firing.......................85
3.4. Combining BK Channels and Ca2+ Buffering.....................88
3.5. Ca2+Diffusion......................................................................88
Contents
4. Discussion.....................................................................................91
4.1. Ca2+Extrusion Mechanisms.................................................92
4.2. Stable Modification to Firing Frequency.............................93
4.3. Type I and D Firing Behaviors............................................93
4.4. Context-Dependent Properties..............................................93
4.5. Putative Mechanistic Explanations of Behavior..................94
4.6. Long-Term Linear Decay of Frequency..............................94
4.7. Conclusion............................................................................94
Acknowledgment..........................................................................95
References.....................................................................................95
CHAPTER 6 Using a Computational Model to Analyze the
Effects of Firing Frequency on Synchrony of a
Network of Gap Junction-Coupled Hypoglossal
Motoneurons.............................................................................99
Heraldo Memelli, Kyle G. Horn, Larry D. Wittie,
Irene C. Solomon
1. Introduction.................................................................................100
2. Methods and Simulation Details................................................101
2.1. Simulations with Different Levels of
Gap-Junction Coupling Strength........................................103
3. Results.........................................................................................104
3.1. Influence of Changes in SK Conductance and
Input Current on Firing Frequency....................................104
3.2. Influence of Firing Frequency on Network
Synchrony...........................................................................106
3.3. Influence of Coupling Strength Extremes
on Synchrony......................................................................108
4. Discussion...................................................................................108
References...................................................................................110
CHAPTER 7 The Physiological Significance of Postinspiration
in Respiratory Control..........................................................113
Mathias Dutschmann, Sarah E. Jones, Hari H. Subramanian,
Davor Stanic, Tara G. Bautista
1. Introduction.................................................................................114
2. Postinspiration During Eupnea...................................................115
2.1. A General Definition of Postinspiration
in Mammals........................................................................115
2.2. Laryngeal Adductor Muscle Activation in
Postinspiration Brakes Expiratory Airflow........................116
xvi Contents
2.3. Postinspiratory Activity in the Crural Diaphragm.............116
2.4. State Dependency and Variable Expression of Eupneic
Postinspiratory Laryngeal Adduction.................................118
3. Postinspiratory Activity During Breath-Holding
and Expulsive Reflexes that Protect the Respiratory Tract.......118
4. Postinspiratory Activity During Nonventilatory Behavior........119
4.1. Vocal Fold Tensioning is Essential for Vocalization........119
4.2. Swallowing is Associated with the
Postinspiratoiy Phase..........................................................119
4.3. Postinspiration During Defecation, Retching,
and Vomiting......................................................................120
5. Central Origins of Postinspiratory Motor Activity....................120
5.1. Reflections on the Role of Postinspiratory
Neurons in Respiratory Rhythm and
Pattern Formation...............................................................121
6. Clinical Implications of Disturbances
to Postinspiratory Control...........................................................122
7. Concluding Remarks and Outlook.............................................123
References...................................................................................124
CHAPTER 8 Expiration: Breathing s Other Face................................131
Sarah E.M. Jenkin, William K. Milsom
1. How Air Breathing Evolved is Still Debated.............................132
2. The Evolution of the Aspiration Pump Began
with an Expiratory Pump............................................................132
3. In the Ancestral Breathing Cycle, Inspiration
Follows Expiration, Which is in Turn Followed
by Glottal Closure.......................................................................133
4. The End-Inspiratory Pause is a Major Controlled
Variable in the Cycle..................................................................134
5. The Phases of the Respiratory Cycle in Mammals
Appear to Be Homologous to Those in Reptiles.......................136
6. The Postinspiratory Pause is a Major Controlled
Variable in the Cycle..................................................................137
7. The Occurrence of Active Expiration in Mammals...................138
8. Control of Expiration..................................................................141
9. Presence of an Expiratory Rhythm Generator...........................141
10. Phylogeny of the Rhythm Generators........................................142
11. Summary.....................................................................................142
Acknowledgment........................................................................143
References...................................................................................143
Contents xvii
CHAPTER 9 The Effects of Head-Up and Head-Down Tilt
on Central Respiratory Chemoreflex Loop Gain
Tested by Hyperoxic Rebreathing...................................149
Rachel J. Skow, Michael M. Tymko, Christina M. MacKay,
Craig D. Steinback, Trevor A. Day
1. Introduction.................................................................................150
1.1. Respiratory Chemoreceptors..............................................150
1.2. Central Respiratory Chemoreceptors.................................151
1.3. Testing and Modeling the Central Chemoreflex...............151
1.4. Central Respiratory Chemoreflex Loop Gain....................153
1.5. Controller Gain...................................................................154
1.6. Mixing Gain........................................................................155
1.7. Plant Gain...........................................................................155
1.8. Tilt and Pulmonary Mechanics..........................................155
1.9. Aim and Hypothesis...........................................................156
2. Methods.......................................................................................156
2.1. Subject Recruitment and Inclusion Criteria.......................156
2.2. Subject Instrumentation and Data Collection....................157
2.3. Experimental Protocol........................................................157
2.4. Data Analysis and Statistics...............................................157
3. Results.........................................................................................159
3.1. Baseline Measurements......................................................160
3.2. Respiratory Variables During Tilt and Hyperoxic
Rebreathing.........................................................................161
4. Discussion...................................................................................161
4.1. Baseline Measures..............................................................162
4.2. Body Position and Central Chemoreflex Loop Gain.........162
4.3. Critique of Methods............................................................163
4.4. Isolation of Plant Gain.......................................................165
4.5. Loop Gain Terminology.....................................................165
5. Conclusion...................................................................................167
Acknowledgments......................................................................167
References...................................................................................167
CHAPTER 10 The Challenges of Respiratory Motor System
Recovery Following Cervical Spinal Cord Injury.......173
Philippa M. Warren, Warren J. Alilain
1. Cervical Spinal Cord Injury and the Deficit
in Respiratory Motor Function...................................................175
2. Organization of the Respiratory Motor Circuitry
and the Crossed Phrenic Phenomenon.......................................176
xviii
Contents
3. Modeling Respiratory Motor Function Following
Cervical Spinal Cord Injury.......................................................178
3.1. Cervical Spinal Cord Injury...............................................178
3.2. Acute Models of Cervical SCI and the Effect
upon the Respiratory Motor System..................................179
3.3. Contusion and Chronic Models of Cervical SCI
and the Affect upon the Respiratory Motor System..........180
3.4. Endogenous Respiratory Motor System Recoveiy
Following Subacute/Chronic Cervical Spinal
Cord Injury..........................................................................182
3.5. The Limitations of Spinal Cord Injury Models.................183
4. Intrinsic Factors Controlling Respiratory Motor
Recovery Following Cervical SCI.............................................183
4.1. Adenosine A1 and cAMP...................................................183
4.2. Gq Protein Signaling Cascades: Intermittent
Hypoxia, 5-HT2, and Phrenic LTF.....................................184
4.3. Gs Protein Signaling Cascade: Adenosine
and 5-HT7...........................................................................188
4.4. Cytogenetics.......................................................................189
5. Extrinsic Factors Controlling Respiratory Motor
Recovery Following Cervical SCI.............................................189
5.1. Inflammation.......................................................................189
5.2. Grafting Tissue...................................................................191
5.3. Reduction of the Glial Scar................................................192
6. Future Directions: Integration of Treatment Strategies
and Outcome Measures...............................................................194
6.1. Integration of Treatment Strategies....................................194
6.2. Assessment of Treatment Strategies Currently
Overlooked in the Respiratory Motor System Model.......196
6.3. Assessment of Multiple Outcome Measures......................197
7. Concluding Remarks...................................................................197
Acknowledgments......................................................................198
References...................................................................................198
CHAPTER 11 Intermittent Hypoxia-Inducer! Respiratory
Long-Term Facilitation is Dominated by Enhanced
Burst Frequency, not Amplitude, in Spontaneously
Breathing Urethane-Anesthetized Neonatal Rats.......221
Inefta M. Reid, Irene C. Solomon
1. Introduction.................................................................................222
2. Methods.......................................................................................223
2.1. Animals...............................................................................223
Contents
2.2. Experimental Protocol........................................................223
2.3. Data Acquisition and Analysis...........................................223
3. Results.........................................................................................224
3.1. Characteristics of EMGdja Activity Under BL
Conditions and During Exposure to C02
and a Single Bout of Acute Hypoxia.................................224
3.2. Response to AIH Trials......................................................225
3.3. Response Following AIH Trials.........................................226
4. Discussion...................................................................................230
References...................................................................................233
CHAPTER 12 Chronic Nitric Oxide Synthase Inhibition Does
Not Impair Upper Airway Muscle Adaptation
to Chronic Intermittent Hypoxia in the Rat..................237
Fiona B. McDonald, Deirdre Edge, Ken D. 0 Halloran
1. Introduction.................................................................................238
2. Methods.......................................................................................239
2.1. Chronic Intermittent Hypoxia............................................239
2.2. Experimental Procedure.....................................................240
2.3. Protocol...............................................................................240
2.4. MHC Fiber Typing.............................................................241
2.5. Image Capture and Analysis..............................................241
2.6. Data Analysis......................................................................242
3. Results.........................................................................................242
3.1. Body Mass and Hematocrit................................................242
3.2. Peak Force..........................................................................242
3.3. Force-Frequency Relationship...........................................242
3.4. Fatigue Index......................................................................243
3.5. MHC Fiber Type................................................................243
4. Discussion...................................................................................244
Acknowledgment........................................................................248
References...................................................................................248
CHAPTER 13 The Generation of Pharyngeal Phase of Swallow
and its Coordination with Breathing: Interaction
Between the Swallow and Respiratory Central
Pattern Generators................................................................253
Tara G. Bautista, Qi-Jian Sun, Paul M. Pilowsky
1. Introduction.................................................................................254
1.1. Definition of Swallow........................................................254
1.2. Experimental Provocation of Swallow...............................255
1.3. The Swallow CPG..............................................................255
2. Swallow and Breathing Coordination: Safe Swallows ...........258
Contents
2.1. Swallow Initiation in Specific Phases
of the Respiratory Cycle.....................................................258
2.2. Arrest of Respiratory Airflow During Swallow:
Swallow-Apnea ..............................................................259
2.3. Expiration and Phase Resetting Following Swallow.........259
3. Interaction Between Swallow and Respiratory CPGs
Enabling Swallowing and Breathing Coordination....................260
3.1. Gating of Swallow Initiation in Specific Phases
of the Respiratory Cycle.....................................................262
3.2. Laryngeal Adduction During Swallow..............................264
3.3. Minimized Breathing Movements During Swallow:
Swallow-Breath ..............................................................264
3.4. Respiratory Phase Resetting Following Swallows.............266
4. Summary and Perspectives.........................................................267
References...................................................................................269
CHAPTER 14 Control of Coughing by Medullary Raphe.....................211
Ivan Poliacek, Jan Jakus, Michal Simera, Marcel Veternik,
Jana Plevkova
1. Introduction.................................................................................277
2. Raphe Neurons and Respiratory Control...................................279
3. Raphe Neurons Control of Coughing
and Other Reflex Behaviors.......................................................280
3.1. Resume................................................................................280
3.2. Methodology.......................................................................282
3.3. Reflex Responses Strength Control...................................283
3.4. Motor Pattern of Reflex Response.....................................286
4. Concluding Remarks...................................................................288
Acknowledgment........................................................................289
References...................................................................................289
CHAPTER 15 The Respiratory-Vocal System of Songbirds:
Anatomy, Physiology, and Neural Control....................297
Marc F. Schmidt, J. Martin Wild
1. Introduction.................................................................................298
2. Peripheral Mechanics of Breathing in (Song)Birds...................299
2.1. Lungs...................................................................................299
2.2. Air Sacs and Respiratory Muscles.....................................301
2.3. Syrinx..................................................................................304
2.4. Upper Vocal Tract..............................................................307
2.5. Chemoreceptors..................................................................308
3. Central Organization of Respiratory-Related Neurons..............308
3.1. Respiratory Muscle Motoneurons......................................308
Contents
3.2. Organization of Respiratory-Related Neurons
in the Brainstem..................................................................309
3.3. Respiratory-Vocal Circuitry...............................................311
3.4. Physiological Properties of Hindbrain Respiratory
Neurons in Songbirds.........................................................312
4. Linking the Song System to the Vocal-Respiratory
Hindbrain.....................................................................................315
4.1. Functional Organization of the Song Motor Pathway.......315
4.2. A Sparse Neural Code for Song.........................................317
4.3. HVC and Its Control of Respiratory Timing
During Song........................................................................319
4.4. The Song System Provides Direct Drive
to the Respiratory System..................................................320
5. Song Production and the Respiratory-Thalamo-Cortical
Pathway.......................................................................................321
5.1. The Respiratory-Thalamic Pathway is Necessary
for Song..............................................................................321
5.2. A Role for the Respiratory System in Hemispheric
Coordination.......................................................................323
5.3. Neural Properties of the Respiratory-Thalamic Pathway ..323
5.4. Integrating the Respiratory System with Song Control.....324
6. Concluding Remarks...................................................................327
Acknowledgments......................................................................327
References...................................................................................327
CHAPTER 16 The Lamprey Blueprint of the Mammalian
Nervous System.....................................................................337
Brita Robertson, Andreas Kardamakis, Lorenza Capantini,
Juan Perez-Fernandez, Shreyas M. Suryanarayana,
Peter Wallen, Marcus Stephenson-Jones, Sten Grillner
1. The Motor Infrastructure............................................................338
1.1. The Brainstem-Spinal Cord Control of Locomotion........338
1.2. Respiratory Control............................................................338
1.3. The Control of Eye, Orienting, and Evasive Motor
Behavior in the Optic Tectum/Superior Colliculus...........340
1.4. General Comments on the Motor Infrastructure................340
2. The Forebrain Control of the Brainstem-Spinal
Cord Motor Programs.................................................................340
2.1. The Control of Dopamine Neurons from
the Lateral Habenulae.........................................................344
2.2. Pallium and the Layered Neocortex...................................345
3. Conclusion...................................................................................346
xxii
Contents
Acknowledgments......................................................................346
References...................................................................................346
CHAPTER 17 The Midbrain Periaqueductal Gray Changes the
Eupneic Respiratory Rhythm into a Breathing
Pattern Necessary for Survival of the Individual
and of the Species................................................................351
Hari H. Subramanian, Gert Holstege
1. Introduction.................................................................................352
2. Functional Segregation Within the PAG....................................353
3. The PAG Connectome................................................................354
4. PAG integrates Respiratory Responses......................................357
5. PAG-induced Respiratory Patterning.........................................357
5.1. PAGdm Generates Slow and Deep Breathing...................360
5.2. PAGdl Generates Tachypnea.............................................361
5.3. PAG1 Generates Inspiratory Apneusis...............................361
5.4. PAGvl Generates Breath Hold...........................................361
5.5. PAGvl Generates Irregular Breathing and Apnea.............363
6. Vocalization: A Modified Form of Breathing...........................364
7. PAG Control of the Crural and Costal Diaphragm....................366
8. PAG Control of Intra-abdominal Pressure.................................366
9. PAG Control of Medullary Respiratory Neurons......................368
9.1. PAG Modulates the Activity of Medullary Late-I
and Post-I Neurons.............................................................368
9.2. PAG Modulates the Pre-I Neurons in the Pre-Botzinger
Complex Phasically and Tonically, As Well As
Silences Them When Required..........................................370
10. Hypothalamic Mediation of Dorsal PAG-induced
Respiratory Effect.......................................................................371
11. Pharmacology of P AG-Induced Respiratory Modulation..........372
12. PAG, Serotonin, and Level-Setting Systems.............................372
13. Chemosensory, Upper Airway, and Pulmonary
Afferent Information to the PAG...............................................374
14. Amygdala-PAG Interactions......................................................375
15. Breathing and the PAG: Therapeutic Targets
for the Treatment of Emotional and Psychiatric Disorders.......376
16. Conclusion...................................................................................376
Acknowledgment........................................................................378
References...................................................................................378
Index.......................................................................................................................385
Other volumes in PROGRESS IN BRAIN RESEARCH
397
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| record_format | marc |
| series | Progress in brain research |
| series2 | Progress in brain research |
| spelling | Breathing, emotion and evolution ed. by Gert Holstege ... 1. ed. Amsterdam [u.a.] Elsevier 2014 XXII, 399 S. Ill., zahlr. graph. Darst. 24 cm txt rdacontent n rdamedia nc rdacarrier Progress in brain research 212 Comprend des références bibliographiques et un index (DE-588)1071861417 Konferenzschrift gnd-content Holstege, Gert edt Progress in brain research 212 (DE-604)BV008000363 212 HBZ Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=027621029&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | Breathing, emotion and evolution Progress in brain research |
| subject_GND | (DE-588)1071861417 |
| title | Breathing, emotion and evolution |
| title_auth | Breathing, emotion and evolution |
| title_exact_search | Breathing, emotion and evolution |
| title_full | Breathing, emotion and evolution ed. by Gert Holstege ... |
| title_fullStr | Breathing, emotion and evolution ed. by Gert Holstege ... |
| title_full_unstemmed | Breathing, emotion and evolution ed. by Gert Holstege ... |
| title_short | Breathing, emotion and evolution |
| title_sort | breathing emotion and evolution |
| topic_facet | Konferenzschrift |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=027621029&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
| volume_link | (DE-604)BV008000363 |
| work_keys_str_mv | AT holstegegert breathingemotionandevolution |