Book contents
- Frontmatter
- Contents
- Contributors
- Part I General Principles of Cell Death
- Part II Cell Death in Tissues and Organs
- 11 Cell Death in Nervous System Development and Neurological Disease
- 12 Role of Programmed Cell Death in Neurodegenerative Disease
- 13 Implications of Nitrosative Stress-Induced Protein Misfolding in Neurodegeneration
- 14 Mitochondrial Mechanisms of Neural Cell Death in Cerebral Ischemia
- 15 Cell Death in Spinal Cord Injury – An Evolving Taxonomy with Therapeutic Promise
- 16 Apoptosis and Homeostasis in the Eye
- 17 Cell Death in the Inner Ear
- 18 Cell Death in the Olfactory System
- 19 Contribution of Apoptosis to Physiologic Remodeling of the Endocrine Pancreas and Pathophysiology of Diabetes
- 20 Apoptosis in the Physiology and Diseases of the Respiratory Tract
- 21 Regulation of Cell Death in the Gastrointestinal Tract
- 22 Apoptosis in the Kidney
- 23 Physiologic and Pathological Cell Death in the Mammary Gland
- 24 Therapeutic Targeting Apoptosis in Female Reproductive Biology
- 25 Apoptotic Signaling in Male Germ Cells
- 26 Cell Death in the Cardiovascular System
- 27 Cell Death Regulation in Muscle
- 28 Cell Death in the Skin
- 29 Apoptosis and Cell Survival in the Immune System
- 30 Cell Death Regulation in the Hematopoietic System
- 31 Apoptotic Cell Death in Sepsis
- 32 Host–Pathogen Interactions
- Part III Cell Death in Nonmammalian Organisms
- Plate section
- References
17 - Cell Death in the Inner Ear
from Part II - Cell Death in Tissues and Organs
Published online by Cambridge University Press: 07 September 2011
- Frontmatter
- Contents
- Contributors
- Part I General Principles of Cell Death
- Part II Cell Death in Tissues and Organs
- 11 Cell Death in Nervous System Development and Neurological Disease
- 12 Role of Programmed Cell Death in Neurodegenerative Disease
- 13 Implications of Nitrosative Stress-Induced Protein Misfolding in Neurodegeneration
- 14 Mitochondrial Mechanisms of Neural Cell Death in Cerebral Ischemia
- 15 Cell Death in Spinal Cord Injury – An Evolving Taxonomy with Therapeutic Promise
- 16 Apoptosis and Homeostasis in the Eye
- 17 Cell Death in the Inner Ear
- 18 Cell Death in the Olfactory System
- 19 Contribution of Apoptosis to Physiologic Remodeling of the Endocrine Pancreas and Pathophysiology of Diabetes
- 20 Apoptosis in the Physiology and Diseases of the Respiratory Tract
- 21 Regulation of Cell Death in the Gastrointestinal Tract
- 22 Apoptosis in the Kidney
- 23 Physiologic and Pathological Cell Death in the Mammary Gland
- 24 Therapeutic Targeting Apoptosis in Female Reproductive Biology
- 25 Apoptotic Signaling in Male Germ Cells
- 26 Cell Death in the Cardiovascular System
- 27 Cell Death Regulation in Muscle
- 28 Cell Death in the Skin
- 29 Apoptosis and Cell Survival in the Immune System
- 30 Cell Death Regulation in the Hematopoietic System
- 31 Apoptotic Cell Death in Sepsis
- 32 Host–Pathogen Interactions
- Part III Cell Death in Nonmammalian Organisms
- Plate section
- References
Summary
The inner ear transduces sound energy and head motion into neural impulses. These signals are detected by six sensory patches in the fluid-filled spaces of the inner ear. The snail-shaped cochlea detects sound, whereas the vestibular system serves balance and gravity-detection functions. All six sensory patches in the inner ear use mechanosensory hair cells to transduce fluid motion signals into neurotransmitter release. These sensory cells are sensitive to death from noise trauma, aging, and certain therapeutic drugs. Hair cells in nonmammalian vertebrates are regenerated after they die, resulting in functional recovery of hearing and balance. In contrast, mammalian sensory hair cells are not regenerated, and their loss results in permanent hearing and/or balance disorders. Cochlear hair cells make synaptic connections with spiral ganglion neurons. Spiral ganglion neurons are bipolar cells with dendrites that synapse with the basal surfaces of hair cells and axons that comprise the eighth cranial nerve. Hair cells provide trophic support to spiral ganglion neurons. Therefore, death of hair cells is often followed by spiral ganglion neuron degeneration. Hearing loss is the most common sensory impairment in humans and is the sixth most common chronic health problem in the United States. This chapter addresses apoptotic death of sensory hair cells in response to ototoxic drugs and the subsequent death of spiral ganglion neurons (SGNs).
- Type
- Chapter
- Information
- ApoptosisPhysiology and Pathology, pp. 182 - 193Publisher: Cambridge University PressPrint publication year: 2011
References
- 3
- Cited by