Chromatolysis

Last updated
This drawing compares a normal neuron to one undergoing chromatolysis after axonal injury. Regeneration after axonal injury may occur. Neuron undergoing chromatolysis.jpg
This drawing compares a normal neuron to one undergoing chromatolysis after axonal injury. Regeneration after axonal injury may occur.

In cellular neuroscience, chromatolysis is the dissolution of the Nissl bodies in the cell body of a neuron. It is an induced response of the cell usually triggered by axotomy, ischemia, toxicity to the cell, cell exhaustion, virus infections, and hibernation in lower vertebrates. Neuronal recovery through regeneration can occur after chromatolysis, but most often it is a precursor of apoptosis. The event of chromatolysis is also characterized by a prominent migration of the nucleus towards the periphery of the cell and an increase in the size of the nucleolus, nucleus, and cell body. [1] The term "chromatolysis" was initially used in the 1940s to describe the observed form of cell death characterized by the gradual disintegration of nuclear components; a process which is now called apoptosis. [2] Chromatolysis is still used as a term to distinguish the particular apoptotic process in the neuronal cells, where Nissl substance disintegrates.

Contents

History

In 1885, researcher Walther Flemming described dying cells in degenerating mammalian ovarian follicles. The cells showed variable stages of pyknotic chromatin. These stages included chromatin condensation, which Flemming described as "half-moon" shaped and appearing as "chromatin balls," or structures resembling large, smooth, and round electron-dense chromatin masses. Other stages included cell fractionation into smaller bodies. Flemming named this degenerative process "chromatolysis" to describe the gradual disintegration of nuclear components. The process he described now fits with the relatively new term, apoptosis, to describe cell death. [2]

Around the same time of Flemming's research, chromatolysis was also studied in the lactating mammary glands and in breast cancer cells. From observing the regression of ovarian follicles in mammals, it was argued that a necessary cellular process existed to counterbalance the proliferation of cells by mitosis. At this time, chromatolysis was proposed to play a major role in this physiological process. Chromatolysis was also thought to be responsible for necessary cell elimination in various organs during development. Again, these expanded definitions of chromatolysis are consistent with what we now term apoptosis.

In 1952, research further supported the role of chromatolysis in changing the physiology of cells during cell death processes in embryo development. It was also observed that the integrity of mitochondria is maintained during chromatolysis.

By the 1970s, the conserved structural features of chromatolysis were identified. The consistent features of chromatolysis included the condensation of the cytoplasm and chromatin, cell shrinkage, formation of "chromatin balls," intact normal organelles, and fragmentation of cells observed by the budding of fragments enclosed in the cell membrane. These budding fragments were termed "apoptotic bodies," thus coining the name "apoptosis" to describe this form of cell death. The authors of these studies, most likely unfamiliar with older publications on chromatolysis, were essentially describing apoptosis as a process identical to chromatolysis. [2]

Types of chromatolysis

A high magnification micrograph of the anterior horn of the spinal cord showing motoneurons with central chromatolysis visualized using hematoxylin and eosin staining. The chromatolytic cells in the image are those that appear swollen and are missing dark purple substance in the interior. Central chromatolysis - intermed mag - cropped.jpg
A high magnification micrograph of the anterior horn of the spinal cord showing motoneurons with central chromatolysis visualized using hematoxylin and eosin staining. The chromatolytic cells in the image are those that appear swollen and are missing dark purple substance in the interior.

Central chromatolysis

Central chromatolysis is the most common form of chromatolysis and is characterized by the loss or dispersion of the Nissl bodies starting near the nucleus at the center of the neuron, and then extending peripherally towards the plasma membrane. Also characteristic of central chromatolysis is the displacement of the nucleus towards the periphery of the perikaryon. [3] [4] [5] Other cellular changes are observed during the process of the central chromatolysis. The process of Nissl dissolution is less apparent toward periphery of the cell body of the neuron, where normal-looking Nissl bodies may be present. [1] Hyperplasia of neurofilaments is frequently observed, however the extent varies. The number of autophagic vacuoles and lysosomal structures often increase during central chromatolysis. Changes can also occur in other organelles such as the Golgi apparatus and neurotubules. However, the exact significance of these changes is currently unknown. In neurons receiving axonal transection, central chromatolysis is observed in the area between the nucleus and the axon hillock following....... [6]

Peripheral chromatolysis

Peripheral chromatolysis is much less common, but has been reported to occur after axotomy and ischemia in certain species. Peripheral chromatolysis is essentially the reverse of central chromatolysis, in which the disintegration of Nissl bodies is initiated at the periphery of the neuron and extends inwards towards the nucleus of the cell. Peripheral chromatolysis has been observed to occur in lithium-induced chromatolysis and it could be useful in investigating and countering the hypothesis that waves of enzymatic activity always progress from the perinuclear area, or the area situated around the nucleus, to the peripheral of the cell. [7]

Causes

An image of an axotomized spinal motor neuron with Nissl bodies and lipofuscin. The pink structures are Nissl bodies and the blue and yellow structures are the lipofuscin granules. In chromatolysis of motor neurons, these pink structures dissolve. Lipofuscin neuro.jpg
An image of an axotomized spinal motor neuron with Nissl bodies and lipofuscin. The pink structures are Nissl bodies and the blue and yellow structures are the lipofuscin granules. In chromatolysis of motor neurons, these pink structures dissolve.

Axotomy

When an axon is injured, the whole neuron reacts to provide increased metabolic activity that is necessary for regeneration of the axon. Part of this reaction includes structural alternations caused by the chromatolysis event. [9] The enlargement of nuclear components due to axotomy can be explained by the alteration of the cell's cytoskeleton. The cytoskeleton maintains the nuclear components of a cell and the size of the cell body in neurons. The increase in protein within the neuron leads to this change in the cytoskeleton. For example, there is an increase in phosphorylated neurofilament proteins and cytoskeletal components, tubulin and actin, in neurons undergoing chromatolysis. [4] The increase in protein can be explained by the increase in cytoskeleton size. Changes in the cell body cytoskeleton seem to be responsible for enhanced nuclear eccentricity following axonal injury. [1] [3]

One hypothesis behind the incidence of chromatolysis following axotomy is that the shortening of the axon prevents the incorporation of the axonal cytoskeleton that undergoes formation in the injured neuron. Nuclear eccentricity can be attributed to the presence of excess axonal cytoskeleton between the nucleus and axon hillock, which causes chromatolysis. A second hypothesis proposes that blockage of axonal cytoskeletal proteins causes chromatolysis. [8]

Axotomy also induces the loss of basophilic staining in the event of central chromatolysis of the neuronal cell. The loss of staining begins near the nucleus and spreads toward the axon hillock. The basophilic rim is formed as chromatolysis compresses the cytoplasmic skeleton. [8]

Acrylamide intoxication

Acrylamide intoxication has been shown to be an agent for the induction of chromatolysis. In one study groups of rats were injected with acrylamide for 3, 6, and 12 days and the A- and B-cell perikarya of their L5 dorsal root ganglion were examined. There was no morphological change in the B-cell perikarya, the A-cell perikarya however exhibited chromatolysis in 11% and 23% of the population, for the 6 and 12 days groups respectively. For the purposes of the study A-cells were defined as ganglia neurons whose nucleolus was large and centrally placed in the nucleus, while B-cells had many nucleoli distributed along the periphery of their nucleus. Acrylamide intoxication resembles neural axotomy histologically and mechanically. In each case the neuron undergoes chromatolysis and atrophy of the cell body and axon. Also both seem to be mechanically related to a disruption of the delivery of neurofilament to the axon due to a decreased transport of a trophic factor from the axon to the cell body. [10]

Lithium

Exposure to lithium has also been used as a method to induce chromatolysis in rats. The study involved the injection of large doses of lithium chloride into female Lewis rats over several day periods. Examination of the trigeminal and dorsal root ganglia revealed peripheral chromatolysis in these cells. The cells exhibited decreased numbers of Nissl bodies throughout the cell, especially at the peripheral cytoplasm were the Nissl bodies were completely absent. Using lithium as a method to induce peripheral chromatolysis could be useful for future study of chromatolysis due to its simplicity and the fact it does not cause nuclear displacement. [7]

Associated diseases

Amyotrophic lateral sclerosis (ALS)

Central chromatolysis has been observed in spinal anterior horn and motor neurons of patients with amyotrophic lateral sclerosis (ALS). [11] Patients with ALS appear to have significant alterations that occur within the chromatolyzed neuronal cells. [12] [13] These alterations include dense conglomerates of aggregated dark mitochondria and presynaptic vesicles, bundles of neurofilaments, and a marked increase of presynaptic vesicles. Changes to the function of the motor neurons have also been observed. The most typical functional change in chromatolytic motor neurons is the significant reduction in size of the monosynaptic excitatory postsynaptic potentials (EPSPs). These monosynaptic EPSPs also seem to be prolonged in the chromatolyzed cells of ALS patients. This functional change to the anterior horn neurons could result in the elimination of certain excitatory synaptic inputs and thus give rise to the clinical motor function impairment that is characteristic of the ALS disease. [13]

Alzheimer's disease and Pick's disease

Alzheimer's disease is a major neurodegenerative disease that involves the dying off of neurons and synapses. Chromatolysis has been observed in neurons from Alzheimer's patients, often as a precursor to apoptosis. Chromatolytic cells have also been observed in a pathologically similar disease known as Pick's disease. [14] Most recent studies have observed chromatolysis in cells from rats that have been subjected to either copper or aluminum toxication, which are both hypothesized to be involved in the pathogenesis of Alzheimer's disease. [15] [16]

Idiopathic brainstem neuronal chromatolysis

Severe neuronal chromatolysis has been detected in the brainstems of adult cattle with the neurodegenerative condition known as idiopathic brainstem neuronal chromatolysis (IBNC). The symptoms of IBNC in cattle are clinically similar to those characterized by bovine spongiform encephalopathy, otherwise known as mad-cow disease. These symptoms included tremor, lack of muscle movement coordination, anxiety and weight loss. [17] At the cellular level, IBNC is marked by the degeneration of neurons and axons within the brainstem and cranial nerves. The disease also has a significant correlation with abnormal labeling for prion protein (PrP) in the brain. IBNC has been characterized by severe neuronal, axonal, and myelin degradation, accompanied by non-supportive inflammation and changes in spongiform of various regions of grey matter. A significant loss of neurons due to hippocampal degeneration has also been observed. The degenerate chromatolysis neurons seldom showed intracytoplasmic labeling for PrP. [18]

Alcoholic encephalopathy

Chromatolysis has been reported in patients with alcoholic encephalopathies. Central chromatolysis was observed mainly among neurons in the brainstem, particularly in the pontine nuclei and the cerebellar dentate nuclei. Nuclei of cranial nerves, arcuate nuclei, and posterior horn cells were also affected. Studies examining patients with alcoholic encephalopathies give evidence of central chromatolysis. Mild to severe degeneration of spinal cord tracks has been observed in patients with Marchiafava–Bignami disease and Wernicke–Korsakoff syndrome, both forms of encephalopathy linked to alcohol. [19]

Future research

The mechanisms and signals for chromatolysis were first researched in depth in the 1960s and still merit further investigation. [9] [20] It is clear that axotomy is one of the most direct inducers of chromatolysis and if further research were put into elucidating the specific pathways which associate axonal damage to chromatolysis, then potential therapies could be developed for halting the chromatolytic response of neurons and ameliorating the detrimental effects of degenerative diseases, such as Alzheimer's and ALS. [20]

Related Research Articles

<span class="mw-page-title-main">Axon</span> Long projection on a neuron that conducts signals to other neurons

An axon or nerve fiber is a long, slender projection of a nerve cell, or neuron, in vertebrates, that typically conducts electrical impulses known as action potentials away from the nerve cell body. The function of the axon is to transmit information to different neurons, muscles, and glands. In certain sensory neurons, such as those for touch and warmth, the axons are called afferent nerve fibers and the electrical impulse travels along these from the periphery to the cell body and from the cell body to the spinal cord along another branch of the same axon. Axon dysfunction can be the cause of many inherited and acquired neurological disorders that affect both the peripheral and central neurons. Nerve fibers are classed into three types – group A nerve fibers, group B nerve fibers, and group C nerve fibers. Groups A and B are myelinated, and group C are unmyelinated. These groups include both sensory fibers and motor fibers. Another classification groups only the sensory fibers as Type I, Type II, Type III, and Type IV.

<span class="mw-page-title-main">Myelin</span> Fatty substance that surrounds nerve cell axons to insulate them and increase transmission speed

Myelin is a lipid-rich material that surrounds nerve cell axons to insulate them and increase the rate at which electrical impulses pass along the axon. The myelinated axon can be likened to an electrical wire with insulating material (myelin) around it. However, unlike the plastic covering on an electrical wire, myelin does not form a single long sheath over the entire length of the axon. Rather, myelin ensheaths the axon segmentally: in general, each axon is encased in multiple long sheaths with short gaps between, called nodes of Ranvier. At the nodes of Ranvier, which are approximately one thousandth of a mm in length, the axon's membrane is bare of myelin.

<span class="mw-page-title-main">Neuron</span> Electrically excitable cell found in the nervous system of animals

Within a nervous system, a neuron, neurone, or nerve cell is an electrically excitable cell that fires electric signals called action potentials across a neural network. Neurons communicate with other cells via synapses, which are specialized connections that commonly use minute amounts of chemical neurotransmitters to pass the electric signal from the presynaptic neuron to the target cell through the synaptic gap.

<span class="mw-page-title-main">Wallerian degeneration</span> Biological process of axonal degeneration

Wallerian degeneration is an active process of degeneration that results when a nerve fiber is cut or crushed and the part of the axon distal to the injury degenerates. A related process of dying back or retrograde degeneration known as 'Wallerian-like degeneration' occurs in many neurodegenerative diseases, especially those where axonal transport is impaired such as ALS and Alzheimer's disease. Primary culture studies suggest that a failure to deliver sufficient quantities of the essential axonal protein NMNAT2 is a key initiating event.

<span class="mw-page-title-main">Diffuse axonal injury</span> Medical condition

Diffuse axonal injury (DAI) is a brain injury in which scattered lesions occur over a widespread area in white matter tracts as well as grey matter. DAI is one of the most common and devastating types of traumatic brain injury and is a major cause of unconsciousness and persistent vegetative state after severe head trauma. It occurs in about half of all cases of severe head trauma and may be the primary damage that occurs in concussion. The outcome is frequently coma, with over 90% of patients with severe DAI never regaining consciousness. Those who awaken from the coma often remain significantly impaired.

<span class="mw-page-title-main">Peripherin</span> Protein-coding gene in the species Homo sapiens

Peripherin is a type III intermediate filament protein expressed mainly in neurons of the peripheral nervous system. It is also found in neurons of the central nervous system that have projections toward peripheral structures, such as spinal motor neurons. Its size, structure, and sequence/location of protein motifs is similar to other type III intermediate filament proteins such as desmin, vimentin and glial fibrillary acidic protein. Like these proteins, peripherin can self-assemble to form homopolymeric filamentous networks, but it can also heteropolymerize with neurofilaments in several neuronal types. This protein in humans is encoded by the PRPH gene. Peripherin is thought to play a role in neurite elongation during development and axonal regeneration after injury, but its exact function is unknown. It is also associated with some of the major neuropathologies that characterize amyotropic lateral sclerosis (ALS), but despite extensive research into how neurofilaments and peripherin contribute to ALS, their role in this disease is still unidentified.

Neurofilaments (NF) are classed as type IV intermediate filaments found in the cytoplasm of neurons. They are protein polymers measuring 10 nm in diameter and many micrometers in length. Together with microtubules (~25 nm) and microfilaments (7 nm), they form the neuronal cytoskeleton. They are believed to function primarily to provide structural support for axons and to regulate axon diameter, which influences nerve conduction velocity. The proteins that form neurofilaments are members of the intermediate filament protein family, which is divided into six types based on their gene organization and protein structure. Types I and II are the keratins which are expressed in epithelia. Type III contains the proteins vimentin, desmin, peripherin and glial fibrillary acidic protein (GFAP). Type IV consists of the neurofilament proteins NF-L, NF-M, NF-H and α-internexin. Type V consists of the nuclear lamins, and type VI consists of the protein nestin. The type IV intermediate filament genes all share two unique introns not found in other intermediate filament gene sequences, suggesting a common evolutionary origin from one primitive type IV gene.

<span class="mw-page-title-main">Soma (biology)</span> Portion of a brain cell containing its nucleus

In cellular neuroscience, the soma, perikaryon, neurocyton, or cell body is the bulbous, non-process portion of a neuron or other brain cell type, containing the cell nucleus. Although it is often used to refer to neurons, it can also refer to other cell types as well, including astrocytes, oligodendrocytes, and microglia. There are many different specialized types of neurons, and their sizes vary from as small as about 5 micrometres to over 10 millimetres for some of the smallest and largest neurons of invertebrates, respectively.

In cellular neuroscience, an axotomy is the cutting or otherwise severing of an axon. This type of denervation is often used in experimental studies on neuronal physiology and neuronal death or survival as a method to better understand nervous system diseases.

<span class="mw-page-title-main">Netrin</span> Class of proteins involved in axon guidance

Netrins are a class of proteins involved in axon guidance. They are named after the Sanskrit word "netr", which means "one who guides". Netrins are genetically conserved across nematode worms, fruit flies, frogs, mice, and humans. Structurally, netrin resembles the extracellular matrix protein laminin.

<span class="mw-page-title-main">Giant axonal neuropathy</span> Medical condition

Giant axonal neuropathy is a rare, autosomal recessive neurological disorder that causes disorganization of neurofilaments. Neurofilaments form a structural framework that helps to define the shape and size of neurons and are essential for normal nerve function. A distinguishing feature is its association with kinky, or curly, hair; in such cases it has been called Giant axonal neuropathy with curly hair.

<span class="mw-page-title-main">Axonal transport</span> Movement of organelles

Axonal transport, also called axoplasmic transport or axoplasmic flow, is a cellular process responsible for movement of mitochondria, lipids, synaptic vesicles, proteins, and other organelles to and from a neuron's cell body, through the cytoplasm of its axon called the axoplasm. Since some axons are on the order of meters long, neurons cannot rely on diffusion to carry products of the nucleus and organelles to the end of their axons. Axonal transport is also responsible for moving molecules destined for degradation from the axon back to the cell body, where they are broken down by lysosomes.

<span class="mw-page-title-main">Nissl body</span> Rough endoplasmic reticulum structure found in neurons

In cellular neuroscience, Nissl bodies are discrete granular structures in neurons that consist of rough endoplasmic reticulum, a collection of parallel, membrane-bound cisternae studded with ribosomes on the cytosolic surface of the membranes. Nissl bodies were named after Franz Nissl, a German neuropathologist who invented the staining method bearing his name. The term "Nissl bodies" generally refers to discrete clumps of rough endoplasmic reticulum and free ribosomes in nerve cells. Masses of rough endoplasmic reticulum also occur in some non-neuronal cells, where they are referred to as ergastoplasm, basophilic bodies, or chromophilic substance. While these organelles differ in some ways from Nissl bodies in neurons, large amounts of rough endoplasmic reticulum are generally linked to the copious production of proteins.

<span class="mw-page-title-main">Nerve injury</span> Damage to nervous tissue

Nerve injury is an injury to a nerve. There is no single classification system that can describe all the many variations of nerve injuries. In 1941, Seddon introduced a classification of nerve injuries based on three main types of nerve fiber injury and whether there is continuity of the nerve. Usually, however, nerve injuries are classified in five stages, based on the extent of damage to both the nerve and the surrounding connective tissue, since supporting glial cells may be involved.

Nerve tissue is a biological molecule related to the function and maintenance of normal nervous tissue. An example would include, for example, the generation of myelin which insulates and protects nerves. These are typically calcium-binding proteins.

<span class="mw-page-title-main">Cyclin-dependent kinase 5</span> Protein-coding gene in the species Homo sapiens

Cyclin-dependent kinase 5 is a protein, and more specifically an enzyme, that is encoded by the Cdk5 gene. It was discovered 15 years ago, and it is saliently expressed in post-mitotic central nervous system neurons (CNS).

<span class="mw-page-title-main">Dentatorubral–pallidoluysian atrophy</span> Congenital disorder of nervous system

Dentatorubral–pallidoluysian atrophy (DRPLA) is an autosomal dominant spinocerebellar degeneration caused by an expansion of a CAG repeat encoding a polyglutamine tract in the atrophin-1 protein. It is also known as Haw River Syndrome and Naito–Oyanagi disease. Although this condition was perhaps first described by Smith et al. in 1958, and several sporadic cases have been reported from Western countries, this disorder seems to be very rare except in Japan.

Transneuronal degeneration is the death of neurons resulting from the disruption of input from or output to other nearby neurons. It is an active excitotoxic process when a neuron is overstimulated by a neurotransmitter causing the dysfunction of that neuron which drives neighboring neurons into metabolic deficit, resulting in rapid, widespread loss of neurons. This can be either anterograde or retrograde, indicating the direction of the degeneration relative to the original site of damage. There are varying causes for transneuronal degeneration such as brain lesions, disconnection syndromes, respiratory chain deficient neuron interaction, and lobectomies. Although there are different causes, transneuronal degeneration generally results in the same effects to varying degrees. Transneuronal degeneration is thought to be linked to a number of diseases, most notably Huntington's disease and Alzheimer's disease, and researchers recently have been performing experiments with monkeys and rats, monitoring lesions in different parts of the body to study more closely how exactly the process works.

<span class="mw-page-title-main">Neuronal lineage marker</span> Endogenous tag expressed in different cells along neurogenesis and differentiated cells

A neuronal lineage marker is an endogenous tag that is expressed in different cells along neurogenesis and differentiated cells such as neurons. It allows detection and identification of cells by using different techniques. A neuronal lineage marker can be either DNA, mRNA or RNA expressed in a cell of interest. It can also be a protein tag, as a partial protein, a protein or an epitope that discriminates between different cell types or different states of a common cell. An ideal marker is specific to a given cell type in normal conditions and/or during injury. Cell markers are very valuable tools for examining the function of cells in normal conditions as well as during disease. The discovery of various proteins specific to certain cells led to the production of cell-type-specific antibodies that have been used to identify cells.

<span class="mw-page-title-main">Neurotubule</span>

Neurotubules are microtubules found in neurons in nervous tissues. Along with neurofilaments and microfilaments, they form the cytoskeleton of neurons. Neurotubules are undivided hollow cylinders that are made up of tubulin protein polymers and arrays parallel to the plasma membrane in neurons. Neurotubules have an outer diameter of about 23 nm and an inner diameter, also known as the central core, of about 12 nm. The wall of the neurotubules is about 5 nm in width. There is a non-opaque clear zone surrounding the neurotubule and it is about 40 nm in diameter. Like microtubules, neurotubules are greatly dynamic and the length of them can be adjusted by polymerization and depolymerization of tubulin.

References

  1. 1 2 3 Gersh, I.; IBodian, D. (1943). "Some chemical mechanisms in chromatolysis". Journal of Cellular and Comparative Physiology. 21 (3): 253–279. doi:10.1002/jcp.1030210305.
  2. 1 2 3 Stoica, Bogdan; Faden, Alan (2010). "Programmed Neuronal Cell Death Mechanisms in CNS Injury". Acute Neuronal Injury. Vol. 4. pp. 169–200. doi:10.1007/978-0-387-73226-8_12. ISBN   978-0-387-73225-1.
  3. 1 2 Rees, E. (1971). "Nucleolar displacement during chromatolysis. A quantitative study on the hypoglossal nucleus of the rate". J. Anat. 110 (Pt 3): 463–475. PMC   1271057 . PMID   5147307.
  4. 1 2 Goldstein, ME; Cooper, HS; Bruce, J; Carden, MJ; Lee, VM; Schlaepfer, WW (1987). "Phosphorylation of neurofilament proteins and chromatolysis following transection of rat sciatic nerve". Journal of Neuroscience. 7 (5): 1586–94. doi: 10.1523/JNEUROSCI.07-05-01586.1987 . PMC   6568824 . PMID   3106591.
  5. Chen, DH (1978). "Qualitative and quantitative study of synaptic displacement in chromatolyzed spinal motoneurons of the cat". Journal of Comparative Neurology. 177 (4): 635–64. doi:10.1002/cne.901770407. PMID   624794.
  6. Torvik, A. (1976). "Central Chromatolysis and the Axon Reaction: A Reappraisal". Neuropathology and Applied Neurobiology. 2 (6): 423–432. doi:10.1111/j.1365-2990.1976.tb00516.x.
  7. 1 2 Levine, Seymour; Saltzman, Arthur; Kumar, Asok R (2004). "A Method for Peripheral Chromatolysis in Neurons of Trigeminal and Dorsal Root Ganglia, Produced in Rats by Lithium". Journal of Neuroscience Methods. 132 (1): 1–7. doi:10.1016/j.jneumeth.2003.07.001. PMID   14687669.
  8. 1 2 3 McIlwain, David; Hoke, Victoria (2005). "The role of the cytoskeleton in cell body enlargement, increased nuclear eccentricity and chromatolysis in axotomized spinal motor neurons". BMC Neuroscience. 6: 16. doi: 10.1186/1471-2202-6-19 . PMC   1079867 . PMID   15774011.
  9. 1 2 Cragg, BG (1970). "What is the signal for chromatolysis?". Brain Research. 23 (1): 21. doi:10.1016/0006-8993(70)90345-8. PMID   4919474.
  10. Tandrup, T. (2002). "Chromatolysis of A- cells of dorsal root ganglia is a primary structural event in acute acrylamide intoxication". Journal of Neurocytology. 31: 73–78.
  11. Martin, LJ (1999). "Neuronal death in amyotrophic lateral sclerosis is apoptosis: possible contribution of a programmed cell death mechanism". Journal of Neuropathology and Experimental Neurology. 58 (5): 459–71. doi: 10.1097/00005072-199905000-00005 . PMID   10331434.
  12. Kusaka, H; Imai, T; Hashimoto, S; Yamamoto, T; Maya, K; Yamasaki, M (1988). "Ultrastructural study of chromatolytic neurons in an adult-onset sporadic case of amyotrophic lateral sclerosis". Acta Neuropathologica. 75 (5): 523–528. doi:10.1007/BF00687142.
  13. 1 2 Sasaki, Shoichi; Iwata, Makoto (1996). "Ultrastructural study of synapses in the anterior horn neurons of patients with amyotrophic lateral sclerosis". Neuroscience Letters. 204 (1–2): 53–56. doi:10.1016/0304-3940(96)12314-4. PMID   8929976.
  14. Ulrich, J; Probst, A; Langui, D; Anderton, BH; Brion, JP (1987). "Cytoskeletal immunohistochemistry of Alzheimer's dementia and related diseases. A study with monoclonal antibodies". Pathological and Immunopathological Research. 6 (4): 273–83. doi:10.1159/000157058. PMID   3129706.
  15. Tanridag, T; Coskun, T; Hurdag, C; Arbak, S; Aktan, S; Yegen, B (1999). "Motor neuron degeneration due to aluminium deposition in the spinal cord: a light microscopical study". Acta Histochemica. 101 (2): 193–201. doi:10.1016/s0065-1281(99)80018-x. PMID   10335362.
  16. Joseph, J; Alleyne, T; Adogwa, A (2007). "Marginally low copper causes lesions of the midbrain in animal models: the implications for man". West Indian Medical Journal. 56 (6): 481–6. PMID   18646489.
  17. Jeffrey, M; Wilesmith, JW (1992). "Idiopathic brainstem neuronal chromatolysis and hippocampal sclerosis: a novel encephalopathy in clinically suspect cases of bovine spongiform encephalopathy". Veterinary Record. 131: 359–362. doi:10.1136/vr.131.16.359.
  18. Jeffrey, Martin; Perez, Belinda; Terry, Linda; González, Lorenzo (2008). "Idiopathic Brainstem Neuronal Chromatolysis (IBNC): a novel prion protein related disorder of cattle?". BMC Veterinary Research. 4: 1–38. doi: 10.1186/1746-6148-4-38 . PMC   2569918 . PMID   18826563.
  19. Hauw, JJ; de Baecque, C; Hausser-Hauw, C; Serdaru, M (1988). "Chromatolysis in alcoholic encephalopathies. Pellagra-like changes in 22 cases". Brain. 111 (4): 843–857. doi: 10.1093/brain/111.4.843 . PMID   3401686.
  20. 1 2 Hanz, Shlomit; Fainzilber, Mike (2006). "Retrograde signaling in injured nerve-- the axon reaction revisited". Journal of Neurochemistry. 99 (1): 13–19. doi: 10.1111/j.1471-4159.2006.04089.x . PMID   16899067.