Neuropathology and muscle biopsy techniques


Acknowledgments

Thanks to Sebastian Brandner for providing us with his protocol for methylene blue-azure II-basic fuchsin staining and to Patrick Elliott of the Medical Illustration Department, Royal Hallamshire Hospital, Sheffield, for his illustration depicted in Fig. 18.1 . We are grateful to Dr Gabriele De Luca for advice regarding applying the Palmgren method to cryostat sections, and to the neuropathology laboratories of the John Radcliffe Infirmary (Oxford), Hull Royal Infirmary and Royal Hallamshire Hospital (Sheffield) for various muscle techniques.

Introduction

In neuropathology, as in most other areas of histological practice, hematoxylin and eosin (H&E) remains the most useful and commonly used stain, as it demonstrates most cell types well with good detail. As with other histological disciplines, neuropathology relies more on immunohistochemistry and cytogenetics and less on the more capricious and obscure preparations of the past. Nonetheless, a number of reliable and useful tinctorial and metal-based stains remain in common usage.

Neuropathological practice increasingly stresses the importance of molecular and cytogenetic aspects of disease ( ). This is most clearly illustrated by the ‘layered’ approach to diagnosis in the recent WHO tumor classification ( ) whereby morphological, immunohistochemical and cytogenetic data are built up into a final ‘integrated’ diagnosis. Such genetic techniques include in situ hybridization, Sanger and pyrosequencing and ‘next generation’ sequencing ( ). Currently, many of these are performed in supra-regional cytogenetics laboratories but, as these methods increase in number and importance, it is essential that histology staff become conversant with them.

Muscle biopsy techniques are included in this chapter as these methods tend to be performed in the areas of the laboratory designated for neuropathology.

The components of the normal central nervous system

The nervous system can be subdivided into the central, peripheral and autonomic nervous systems. This chapter will concern itself principally with the central nervous system and secondarily with the peripheral nervous system and muscle. The principal components of the central nervous system are:

  • Neurons

  • Glial cells

  • Meninges

  • Blood vessels.

The neuron is an excitable cell which is responsible for processing and transmitting information. Neurons communicate with each other via intercellular interfaces called synapses. At the synapse, an electrical impulse in the presynaptic neuron causes it to release a chemical transmitter which diffuses across a narrow gap to influence the electrical activity of the postsynaptic target neuron. Neurons have several components ( Fig. 18.1 ):

  • The cell body (or ‘soma’), containing various subcellular organelles responsible for the metabolic upkeep of the cell.

  • The nucleus, which resides in the cell body and is the site of storage of the cell’s genetic code in DNA.

  • The dendritic tree, a complex of cell processes responsible for receiving synaptic inputs from other neurons.

  • The axon, an elongated fiber which transmits electrical impulses away from the soma to synapses with either other neurons or muscle fibers. This may be a meter or more in length in the case of the lower motor neurons which reside in the lower (lumbar) spinal cord and innervate the muscles of the lower leg.

Fig. 18.1, Diagram showing a neuron with its component parts together with other cells of the central nervous system.

Two naturally occurring pigments may be observed to accumulate in the brain with age, lipofuscin and neuromelanin. Both are believed to represent cellular waste products. Lipofuscin is a yellow-brown, autofluorescent, granular substance composed of peroxidized protein and lipids. It is seen in larger neurons, such as the lower motor neurons of the spinal cord and pyramidal cells of the hippocampus in Alzheimer pathology. Large amounts of lipofuscin-like pigment also accumulates in inherited neuronal ceroid lipofuscinoses, of which Batten’s disease is the most common ( ). Neuromelanin is most commonly seen in the cytoplasm of neurons of the substantia nigra and the locus ceruleus. It is the cause of the macroscopic pigmentation of these structures. Under the microscope, it is a dark brown, granular material which is believed to be the by-product of oxidative metabolism of catecholamines ( ).

Glial cells are the support cells of the nervous system. They are diverse in nature, and the principal types and their functions follow.

  • Astrocytes have a number of functions. Firstly, they maintain the extracellular ion and neurotransmitter balance. Secondly, they are involved in repair and scarring responses to brain damage and finally astrocytes form part of the blood–brain barrier, protecting the brain from harmful blood-borne substances.

  • Oligodendroglia form myelin, a phospholipid sheath around nerve axons which enhances the speed of conduction of impulses.

  • Ependymal cells line the ventricles of the brain and central canal of the spinal cord.

  • Microglia are the native immune cell of the nervous system of monocyte/macrophage lineage.

Neuropil is a term used to denote the feltwork of neuronal processes in which neuron cell bodies reside. Central nervous system tissue is classically subdivided into gray matter, containing the majority of neuronal cell bodies and little myelin, and white matter, which is predominantly formed of myelinated axons and few neurons.

The meninges form three layers of protective covering over the brain. The outer layer, beneath the skull, is the dura mater; a tough, fibrous membrane. The arachnoid mater is a more delicate, fibrillary covering which lies inside the dura mater and is more closely adherent to the brain surface, but it does not invaginate into the surface infoldings of the brain (or sulci). The pia mater is the most delicate covering. It is closely apposed to the brain surface, following its contours down into the depths of sulci.

Techniques for staining neurons

Tinctorial stains for Nissl substance

Hematoxylin and eosin (H&E) preparations demonstrate the most important features of neurons. However, Nissl preparations are also popular for examining the basic architecture of neural tissue and its components. These are often combined with the luxol fast blue myelin stain. Granules of Nissl substance are found in the cell body ( Fig. 18.1 ) and correspond to rough endoplasmic reticulum. They are basophilic due to the associated nucleic acid ( ). Many basic dyes e.g. neutral red, methylene blue, azure, pyronin, thionin, toluidine blue and cresyl fast violet stain Nissl substance. Variation in the stain used, pH and degree of differentiation allow preparations to label either Nissl substance alone, or Nissl substance in combination with cell nuclei.

Motor neurons generally have coarse (‘tigroid’) Nissl substance, and regions such as the anterior horns of the spinal cord, where these cells are abundant, are good tissues to use when learning these stains ( Fig. 18.2 ). For paraffin wax-embedded sections of formalin-fixed tissue, the cresyl fast violet stain is reliable and relatively straightforward. As such it is by far the most commonly used Nissl preparation. Toluidine blue may also be used, whilst Einarson’s gallocyanin method, being more suited to alcohol-fixed tissue, is largely unused ( ).

Cresyl fast violet (Nissl) stain for paraffin wax sections

Fixation

Alcohol, Carnoy’s or formalin.

Sections

Paraffin wax, 7–10 μm or 25 μm (see Note b).

Preparation of stain

Cresyl fast violet 0.5 g
Distilled water 100 ml

Differentiation solution

Glacial acetic acid 250 μl
Alcohol 100 ml

Method

  • 1.

    Dewax sections and bring to water.

  • 2.

    Cover with filtered cresyl fast violet, stain for 10–20 minutes.

  • 3.

    Rinse briefly in distilled water.

  • 4.

    Differentiate in 0.25% acetic alcohol until most of the stain has been removed (4–8 seconds).

  • 5.

    Briefly pass through absolute alcohol into xylene and check microscopically.

  • 6.

    Repeat steps 4 and 5 if necessary, giving less differentiation when repeating.

  • 7.

    Rinse well in xylene and mount in DPX.

Results

Nissl substance purple/dark blue
Neurons pale purple/blue
Cell nuclei purple-blue

Notes

  • a.

    If only Nissl substance is required to be demonstrated, the stain is acidified with 0.25% acetic acid.

  • b.

    Estimation of cortical neuronal density is made on 25 μm thick sections.

  • c.

    The cresyl violet method can be used as a counterstain when demonstrating myelin with the Kluver and Barrera method (page 312).

Fig. 18.2, Anterior horn cells in spinal cord. Notice their large size and the prominent nucleolus. Paraffin section, stained with toluidine blue. Similar results can be obtained with cresyl fast violet.

Immunohistochemistry of neurons

The protein targets of antibodies used in immunohistochemical (IHC) preparations for the demonstration of neuronal elements can be classified into four main groups:

  • 1.

    Neuronal cytoskeletal proteins . Neurofilaments (NF) are intermediate filaments expressed by mature neurons. They are composed of protein subunits and are classified by molecular weight (light, medium and heavy) into NF-L, NF-M and NF-H which may be variably phosphorylated ( ). Antisera raised against different neurofilament proteins in different states of phosphorylation are available. NF-H in particular, and NF-M to a lesser extent, are normally unphosphorylated in the neuronal cell body, but become phosphorylated in the axons. Thus, antibodies to phosphorylated NF-H mark axons but not cell bodies in normal nervous system tissues. Antibodies to non-phosphorylated neurofilament will label neuronal somata ( ). Microtubule-associated protein 2 (MAP-2) is a protein involved with microtubule assembly and is expressed by neurons in dendrites and cell bodies ( ). It is often used as a marker of neuroepithelial differentiation ( ).

  • 2.

    Cytoplasmic proteins . PGP9.5 and neuron-specific enolase (NSE) are strongly expressed in neurons and can reliably be labeled by commercially available antisera. Unfortunately, they are not specific for neuronal cells, making interpretation tricky. In truth, many pathologists find them of little use.

  • 3.

    Neuronal nuclear proteins . NeuN is a neuron-specific DNA binding protein, which starts to be expressed around the time of initiation of terminal differentiation of the neuron ( ). Antibodies to NeuN label neuronal nuclei and neuronal components of other tumors ( ). In the context of neuro-oncology however, NeuN, lacks specificity, being expressed to a variable degree in a diverse range of primary brain tumors. Therefore, NeuN is best used as part of a panel of antibodies in the investigation of clear cell primary brain tumors, but is of limited use for other tumors ( ).

  • 4.

    Proteins associated with neurosecretory granules . Antisera to these proteins can be useful to establish neuronal and neuroendocrine differentiation ( ). Synaptophysin is a membrane glycoprotein component of presynaptic neurosecretory vesicles. The cell body of normal neurons is usually unstained by synaptophysin ( Fig. 18.3 ), resulting in early claims that cell body labeling was a feature of neoplastic neuronal cells which differentiated them from native neurons ( ). However, it is now evident that a population of normal neurons also show cell body labeling which detracts from the use of this feature as a diagnostic marker ( ). Synaptophysin is a useful marker of neuroendocrine differentiation and so also stains cells in metastatic neuroendocrine tumors ( ). Chromogranin A is a protein of the dense core matrix of neurosecretory granules, and antibodies to it can be used to identify cells containing dense core vesicles ( ). It is used predominantly to elucidate neuroendocrine differentiation in tumors.

    Fig. 18.3, Large neuron from an area of cortical dysplasia stained with synaptophysin. Note intense staining within the neuropil and weak cytoplasmic staining.

Techniques for staining axons and neuronal processes

Immunohistochemistry has largely replaced the old silver preparations for the demonstration of axons as it is reliable and produces adequate results for diagnostic neuropathology with ease. However, for formal quantitation of axons, many still find that Palmgren’s method is superior to neurofilament IHC ( ). This technique has classically been used for staining axons of the peripheral nervous system, but it is also excellent for staining central nervous system axons. Palmgren’s method uses potassium nitrate to suppress reticulin staining. It is considered that using the Palmgren method, cresyl violet preparations and IHC for neurofilament and MAP-2, there is no longer a requirement for the older silver preparations, e.g. Bielschowsky ( ) and Marsland ( ).

Silver techniques require great care and attention to detail such as clean glassware and pure distilled water for a successful outcome. Stock solutions should be well maintained and not more than a few months old, in some cases less than a week.

Modified Palmgren’s method for nerve fibers in paraffin wax-embedded material ( )

Fixation

Formalin fixed tissue.

Sections

Paraffin wax sections 6–10 μm. Sections should be on coated slides.

Preparation of solutions

Acid formalin

Concentrated formaldehyde (40% w/v) 25 ml
Distilled water 75 ml
1% nitric acid 0.2 ml

Silver solution

30% silver nitrate 25 ml
20% potassium nitrate 25 ml
5% glycine 0.5 ml

Reducer

Pyrogallol 10 g
Distilled water 450 ml
Absolute ethanol 550 ml
1% nitric acid 2 ml

Fixing bath

5% sodium thiosulfate.

Method

  • 1.

    Take sections to distilled water.

  • 2.

    Treat with acid formalin for 5 minutes.

  • 3.

    Wash in three changes of distilled water for 5 minutes.

  • 4.

    Leave in filtered silver solution for 15 minutes at room temperature.

  • 5.

    Without rinsing, drain the slide and flood the section with reducer which has been heated to 40–45 ° C. Rock the slide gently and add fresh reducer. Leave for 1 minute. A beaker placed on a hot plate is useful for this stage.

  • 6.

    Wash in three changes of distilled water. Examine microscopically and, if necessary, repeat from step 4, reducing the time in the silver solution and decreasing the temperature of the reducer to 30 ° C.

  • 7.

    Wash in distilled water.

  • 8.

    Fix in 5% sodium thiosulfate for 5 minutes.

  • 9.

    Wash in tap water.

  • 10.

    Dehydrate in alcohol. Clear and mount in DPX.

Result

Nerve fibers brown or black

Notes

  • a.

    In the original method the silver solution contained 5% acetic acid rather than 5% glycine. Glycine must be made up fresh prior to use as it is only stable for approximately one week. However, the Palmgren silver solution, once made up, is stable for several weeks.

  • b.

    The silver incubation time may need to be increased for tissues which have had a short formalin fixation time, you should see a slight yellow tinge to the tissues when the optimum time has been reached. The reducer keeps for several months.

  • c.

    The original method stated that the reducer had to stand for 24 hours before use, but this is not the case. The reducer will darken with time, changing from pale yellow to dark amber. It is important that at the reduction step the slides are gently agitated to ensure an even reduction of the tissue; if the sections are not dark enough, they can be rinsed in distilled water and steps 4–6 repeated but with a shorter time in the silver solution.

  • d.

    The hotter the reducer, the faster the reduction will take place and it may well be uneven, leading to suboptimal preparations. Sections can be toned using gold chloride prior to fixing, which is an optional step.

  • e.

    The original method used an intensifying step prior to fixing using aniline. Some have found this to be of little value. The method was originally designed for use with paraffin wax sections. However, it can be applied to cryostat sections which have been pretreated with 20% chloral hydrate overnight prior to carrying out the Palmgren method.

Examination of axons in peripheral nerves in diagnostic neuropathology now relies largely on toluidine blue stained, semi-thin resin-embedded tissue. Capricious techniques such as Eager’s method for detecting degenerating axons are no longer in use ( ).

The Golgi preparation and its variants are excellent for the visualization of the three-dimensional nature of the neuron and its dendritic processes, but modern diagnostic neuropathology practice has no requirement for these. Golgi techniques are occasionally used in research (e.g. ), although new antisera are increasingly allowing IHC indices of these aspects of cell morphology. It is suggested that the interested reader consider the Pugh and Rossi modification for use on paraffin wax-embedded tissue ( ) if a Golgi stain is to be attempted.

Myelin

Myelin forms an electrically insulating sheath around axons. It is approximately 80% lipid and 20% protein and is formed from sheet-like processes of glial cells concentrically wrapped multiple times around the axon. This greatly improves the speed and efficiency of impulse conduction along the axon. Myelin is formed by oligodendrocytes in the central nervous system and Schwann cells in the peripheral nervous system. A single oligodendrocyte may myelinate multiple axons in its vicinity, whereas a single Schwann cell only myelinates a single segment of a single axon. Loss of myelin, as is seen in multiple sclerosis in the central nervous system or in Guillain-Barré syndrome in the peripheral nervous system, can be severely debilitating.

Modern tinctorial stains for myelin are simple and reliable and can be performed on formalin-fixed paraffin wax-processed tissue. Many can be combined with a Nissl stain to demonstrate neuronal localization. We also find that the myelin staining is more intense and satisfactory when combined with Nissl staining than without. Older methods may give more even and consistent staining, but are considerably more time consuming and have fallen from use ( ). Luxol fast blue, solochrome cyanine and IHC preparations are now favored. Many antisera are used as markers of myelination, the most useful being myelin basic protein, proteolipid protein and myelin associated glycoprotein ( ). Given the reliability and simplicity of the tinctorial stains, IHC myelin markers are rarely used in routine diagnostic neuropathology and remain the preserve of research laboratories. Immunohistochemistry for S-100 is useful in the diagnosis of tumors derived from Schwann cells both in the central nervous system and peripherally ( ).

Luxol fast blue is a copper phthalocyanine dye which is employed in myelin staining of paraffin wax-processed tissue ( ). This can be combined with cresyl violet or hematoxylin to outline cellular architecture ( Fig. 18.4 ) or with periodic acid-Schiff (PAS) to demonstrate myelin degradation products in demyelinating disease in central nervous system tissue only.

Luxol fast blue stain for myelin with cresyl violet counterstain ( )

Fixation

Formalin.

Sections

Paraffin, 10–15 μm.

Preparation of solutions

Luxol fast blue

Luxol fast blue 1 g
Methanol (absolute) 1000 ml
10% acetic acid 5 ml

Mix reagents and filter.

Cresyl violet stock solution

Cresyl violet 0.5 g
Distilled water 100 ml

Acidified cresyl violet solution

Cresyl violet stock solution 100 ml
10% acetic acid 0.8 ml

Filter before use.

Method

  • 1.

    Take sections on slides to 95% alcohol ( not water).

  • 2.

    Stain in luxol fast blue solution for 2 hours at 60 ° C, or 37 ° C overnight.

  • 3.

    Wash in 70% alcohol.

  • 4.

    Wash in tap water.

  • 5.

    Differentiate in 0.1% lithium carbonate solution until the gray and white matter are distinguished. This may be more easily controlled by using 0.05% lithium carbonate followed by 70–95% alcohol instead.

  • 6.

    Wash in tap water.

  • 7.

    Check differentiation under the microscope. Repeat step 5 if necessary.

  • 8.

    Stain in cresyl violet solution for 10–20 minutes.

  • 9.

    Drain sections and transfer to 70% alcohol. Avoid placing the section in water at this stage as the cresyl violet staining loses some of its intensity. Gently agitate the sections; the cresyl violet dye will flood out. The 70% alcohol differentiates the cresyl violet stain. Optimally, the cresyl violet should be removed, leaving the cell bodies and Nissl clearly visible. Do not over-differentiate; the 70% alcohol will take out the cresyl violet and to a certain extent the luxol fast blue. The cresyl violet counterstain will deepen the color of the luxol fast blue-stained myelin from turquoise to a deep blue.

  • 10.

    Dehydrate, clear in xylene and mount in DPX.

Result

Myelin blue
Nuclei and Nissl substance violet/pink

Notes

  • a.

    If the section is over-differentiated with lithium carbonate/alcohol, the section can be restained with the luxol fast blue and then differentiated to obtain the optimum staining result. This may apply to tissues which have very low amounts of myelin e.g. baby/neonatal brains. These tissues can be very challenging in achieving optimum staining. Unfortunately, once the cresyl violet counterstain has been applied the over-differentiation cannot be rectified.

  • b.

    Some histologists prefer to differentiate the cresyl violet using 0.25% acetic acid in 100% alcohol.

  • c.

    The use of thick sections is important for the visualization of myelin tracts.

  • d.

    Other counterstains may be used such as neutral red. This will result in the myelin appearing purple/blue due to a slightly different color balance, and is a matter of personal preference. The solochrome cyanine stain is a simple and rapid technique for demonstration of myelin in both the central and peripheral nervous systems.

Solochrome cyanine technique for myelin in paraffin wax sections ( )

Fixation

Formalin.

Sections

Paraffin wax, 6–10 μm. Cryostat section, 10 μm.

Preparation of solution

Solochrome cyanine RS 0.2 g
Distilled water 96 ml
10% iron alum 4 ml
Concentrated sulfuric acid 0.5 ml

Method

  • 1.

    Take sections to water.

  • 2.

    Stain for 10–20 minutes at room temperature.

  • 3.

    Wash in running water.

  • 4.

    Differentiate in 5% iron alum until all the nuclei are unstained. Wash frequently in distilled water, and examine microscopically.

  • 5.

    Wash in running tap water.

  • 6.

    Counterstain if desired.

  • 7.

    Dehydrate, clear and mount.

Result

Myelin sheaths blue

Notes

  • a.

    The staining solution keeps well.

  • b.

    Neutral red, neutral fast red, or van Gieson can be used for counterstaining.

Fig. 18.4, Macro section of a human hippocampus demonstrating geographical variation in myelin content, stained with luxol fast blue.

Myelin loss may occur in a region of brain damaged by any of a number of processes, e.g. trauma, neoplasia, multiple sclerosis or toxic insult. It may also occur secondary to the loss of axons emanating from any damaged brain region. In modern practice, degeneration of myelinated tracts is most commonly demonstrated by showing loss of normal myelin staining by either luxol fast blue or solochrome cyanine preparations, or by showing a microglial reaction using CD68 IHC ( ).

The neuroglia

This term refers to the supporting cells of the central nervous system and comprises ependymal cells, astrocytes, oligodendrocytes and microglia. As is becoming a recurrent theme, IHC is increasingly replacing tinctorial stains for their identification.

Ependymal cells

These cells are epithelioid and line the ventricles of the brain and the central canal of the spinal cord. They are easily located with conventional stains such as H&E and IHC for glial fibrillary acid protein (GFAP), vimentin and S-100. Immunohistochemistry for epithelial membrane antigen ( ) labels both normal and neoplastic ependymal cells, whilst cytokeratin markers are negative.

Astrocytes

These cells have multiple, fine processes and in their reactive state are ‘star-shaped’, hence the name. On standard H&E sections, only the nucleus of resting astrocytes is distinct, as the cell body cannot be discerned from background neuropil. These nuclei are slightly larger with more open granular chromatin than those of the more compact oligodendrocyte. Modern neuropathology relies most heavily on GFAP ( Fig. 18.5 ) IHC for the demonstration of astrocytes, although antibodies to S-100, αB-crystallin and glutamine synthetase may also be used.

Fig. 18.5, Reactive astrocytes in white matter, stained by anti-GFAP IHC technique with a hematoxylin nuclear counterstain. Fine GFAP-containing processes form a felt-like mat in which the stellate cell bodies are evident.

Astrocytes are principally classified into protoplasmic and fibrous forms. These are similar in function, but protoplasmic astrocytes have shorter, thicker, highly branched processes and are generally found in the gray matter; fibrous astrocytes have longer, thinner, less-branched processes and usually reside in the white matter. Astrocytic reactions in the cerebellum are characterized by Bergmann or radial astroglia which have processes running radially from the Purkinje cell layer of the cortex to the pial surface.

In response to injury of the brain parenchyma, astrocytes react by increasing in size with a more prominent, eosinophilic cytoplasm. The nucleus moves from a central to a more eccentric position within the cell cytoplasm and processes become more prominent. Astrocytic gliosis is a response to permanent injury, whereby astrocytes proliferate to fill tissue defects with a fibrous glial scar.

In neuro-oncology, astrocytic differentiation is best demonstrated by GFAP IHC. GFAP immunoreactivity is also seen in other tumors including ependymoma, oligodendroglial tumors and choroid plexus tumors ( ). Astrocytic tumors also label with vimentin and S-100, but these are also seen in many other tumor types, rendering them of little use for differential diagnoses. Astrocytes occasionally show cross-reactivity as seen for the pan cytokeratin AE1/AE3 ( ); it is expedient to use other cytokeratin markers such as CAM5.2 or MNF116 to exclude the diagnosis of epithelial tumors.

The proliferation marker Ki-67 (MIB-1) is often used as an aid to grading tumors and to help differentiate reactive from neoplastic astrocytic populations. The latter will tend to have a higher number of nuclei labeled with this marker.

A recently introduced tool for the diagnosis of diffuse oligodendroglial and astrocytic neoplasms is the use of antibodies to isocitrate dehydrogenase 1 (IDH1) carrying the R132H mutation. Approximately 74% of mid-grade (WHO grade II and III) diffuse astrocytomas and oligodendrogliomas have mutations of either IDH1 or IDH2 . Tumours with IDH mutations have a better prognosis than those without. The R132H mutation in IDH1 accounts for 90% of such mutations ( ). Commercially available antisera to this mutant protein may be used to differentiate astrocytomas and oligodendrogliomas from their mimics as well as to provide some prognostic prediction ( ).

Oligodendrocytes

These glial cells form the myelin of the central nervous system and are present in both gray and white matter. As noted above, a single oligodendrocyte may myelinate axons from multiple neurons. In H&E and cresyl violet preparations, oligodendrocytes have small (7 μm) round to oval nuclei with compact chromatin. The cytoplasm is indistinct from the surrounding neuropil, although oligodendroglial tumors may show artifactual perinuclear halos in paraffin wax sections. Myelin epitopes for which antisera are commercially available are not expressed by oligodendroglial tumors ( ). Olig2 is a transcription factor which regulates oligodendroglial development and is expressed by the nuclei of oligodendrocytes and oligodendroglial tumors ( ). Sadly, it is not specific for oligodendrogliomas as it labels other morphologically similar tumors ( ) and is also expressed by astrocytomas ( ). The authors also find it difficult to use in tissue which has been processed to paraffin wax.

Finally, deletion of chromosomes 1p and 19q (most commonly investigated by fluorescence in situ hybridization) is a well-recognized molecular feature of oligodendrogliomas and appears to be associated with a better prognosis and response to treatment. In the most recent WHO classification of CNS tumors, this co-deletion is considered the defining feature of an oligodendroglioma irrespective of the histomorphological appearance ( ).

Microglia

These are believed to originate from blood-derived monocytes which move into the brain during embryonic development. They serve as the resident innate immune system and, under certain pathological conditions, may develop into full-blown macrophages. They are involved in most, if not all, known forms of CNS pathology and have a multitude of different behaviors which vary within the pathological and physiological context ( ). Microglia are subclassified morpholigcally into resting, activated and ‘amoeboid’ forms. Resting microglia are classically ramified in morphology, whilst activated microglia are rod-shaped and amoeboid are (as the name suggests) amoeboid.

A number of established IHC markers for microglia are available, including CD68 (PGM1), human alveolar macrophage 56 (HAM-56), class II major histocompatibility complex (MHC; particularly in inflammatory states) and HLA-DR-II antibodies. Although these do not label other glial cells, they do label infiltrating macrophages from the circulation.

Neurodegeneration

Neurodegenerative conditions are largely diseases of old age. As the population ages, these conditions place an increasing burden on health and social care systems. This, together with the escalation in research into neurodegeneration in recent years, has resulted in an increasing workload on neuropathology units.

It is often the case that a definitive diagnosis of any neurodegenerative condition cannot be made until autopsy. In most studies, the accuracy of clinical diagnosis of the cause of a dementing illness is in the order of 75%. A neuropathological autopsy does not benefit the deceased, but does have wider benefits, namely:

  • It can yield data and tissue to assist research.

  • It provides epidemiological data, allowing the prevalence of different neurodegenerative diseases to be monitored.

  • Autopsy findings are often of considerable educational benefit for both senior and junior clinicians as well as pathologists.

  • An increasing number of neurodegenerative conditions are familial, often with known causative mutations. Accurate neuropathological characterization can therefore guide genetic counseling.

The pathological characterization of neurodegenerative disease is a staged process. The first step is removal of the brain, sometimes with the spinal cord. Following formalin fixation, the brain is examined macroscopically both intact and after slicing (usually coronally). Appropriate blocks of tissue are taken, processed and paraffin wax embedded for microscopy.

In the majority of cases, neuropathological assessment of neurodegeneration tends to broadly focus on dementing illnesses and motor degeneration, with considerable overlap between the two. Investi-gations of dementia commonly uncover one, or a combination of, three types of pathology, namely: Alzheimer’s disease, vascular dementia or dementia with Lewy bodies. A small number of dementia cases show frontotemporal lobar degeneration (FTLD). The neurodegenerative diseases of the motor system which are diagnosed at autopsy tend to focus on motor neuron disease (also known as amyotrophic lateral sclerosis) and conditions which cause Parkinsonian clinical features. Other neurodegenerative diseases of the motor system e.g. Huntington’s disease, spinocerebellar ataxia and Friedreich’s ataxia tend to be diagnosed by genetic tests.

The microscopic examination of the brain for neurodegeneration is often an iterative process, whereby an initial examination is performed using fairly standard preparations, most favoring H&E. After this, more specialist preparations, usually IHC, are performed ( ).

Many neurodegenerative diseases are characterized by accumulations (or inclusions) of protein, and for the majority there are now commercially available antisera. These diseases are often classified by the particular protein which forms the pathological aggregates characterizing the disorders and these inclusion bodies are detailed in Table 18.1 . These categories are:

  • The tauopathies , e.g. Alzheimer’s disease, Pick’s disease, supranuclear palsy, corticobasal degeneration and argyrophilic grain disease.

  • The synucleinopathies , Parkinson’s disease, dementia with Lewy bodies and multiple system atrophy.

  • Prion disorders and TDP-43 proteinopathies , motor neuron disease, frontotemporal lobar degeneration with TDP-43.

Table 18.1
Inclusion body immunostaining
Inclusion Disease Immunohistochemistry
Neurofibrillary tangle ( Fig. 18.6a, b ) Alzheimer’s disease Tau protein, ubiquitin/p62
Lewy body ( Fig. 18.7a ) Parkinson’s disease α-Synuclein, ubiquitin/p62
Cortical Lewy body ( Fig. 18.7b ) Dementia with Lewy bodies α-Synuclein, ubiquitin/p62
Motor neuron disease/FTLD inclusion ( Fig. 18.8 ) Motor neuron disease, some forms Some forms of FTLD Ubiquitin/p62, TDP-43
Glial cytoplasmic inclusion Multiple system atrophy α-Synuclein, ubiquitin, p62
Glial cytoplasmic inclusion Progressive supranuclear palsy Corticobasal degeneration Tau, ubiquitin/p62
Pick body Pick’s disease Tau protein, ubiquitin/p62

Fig. 18.10, ( a ) In a normal muscle, dystrophin is localized beneath the cell membrane of muscle fibers. ( b ) In Duchenne muscular dystrophy, this staining pattern is absent.

Ubiquitin is a small regulatory protein which binds misfolded or other aberrant proteins, and labels them for destruction by the proteasome. Many dementing illnesses are characterized by accumulations of ubiquitylated protein; the location and form of these accumulations can provide valuable diagnostic clues. Therefore, IHC for ubiquitylated proteins is often a useful early step in neuropathological diagnosis and we favor antibodies to p62. This protein binds ubiquitylated proteins and shuttles them to the proteasome ( ). Antibodies to p62 can be used to label pathological, ubiquitylated aggregates of tau, α-synuclein and TDP-43 ( ). Further, p62 IHC has greater specificity for pathological aggregates than ubiquitin IHC, leaving non-pathological features unlabeled.

As noted above, autopsies in neurodegeneration principally concern dementia and motor system degenerative diseases, many of which overlap. Of the dementing illnesses, the vast majority are diagnosed as Alzheimer’s disease, vascular dementia, dementia with Lewy bodies and FTLD. However, given the considerable public health concerns surrounding prion diseases, cases will also occasionally be assessed for this diagnosis.

Alzheimer’s disease is characterized by ubiquitylated accumulations of tau and β-amyloid. Hyperphosphorylated tau forms flame-shaped neuronal intracytoplasmic inclusions known as neurofibrillary tangles, and neuritic fibrillary deposits known as neuropil threads. β-Amyloid is formed from aggregates of peptides generated by the cleavage of amyloid precursor protein (a membrane-associated protein of unknown function) by β- and γ-secretases. Deposits of β-amyloid become surrounded by dilated and distorted neuronal processes to form senile plaques. Senile plaques and neurofibrillary tangles are the histological hallmarks of Alzheimer’s disease ( Figs. 18.6 and 18.9 ).

Fig. 18.6, ( a ) Tangles in neurons stained by the Gallyas silver technique. ( b ) Tangles in neurons stained by IHC for phosphorylated tau (AT8). In the background large numbers of neuropil threads can be seen.

Fig. 18.7, ( a ) H&E staining of substantia nigra from a patient with Parkinson’s disease. The brown color is normal neuromelanin. Two neurons contain Lewy bodies, rounded eosinophilic inclusions with a pale ‘halo’ around them. ( b ) Immunohistochemistry for α-synuclein showing Lewy bodies and Lewy neurites in the amygdala of a case of dementia with Lewy bodies.

Fig. 18.8, Motor neuron disease (amyotrophic lateral sclerosis). ( a ) p62 IHC showing a skein-like cytoplasmic inclusion in a lower motor neuron. ( b ) TDP-43 IHC showing two motor neurons with ‘compact’ cytoplasmic inclusions.

Fig. 18.9, Methenamine silver ( a ) and IHC for β-amyloid ( b ), showing senile plaques in cerebral cortex from cases of Alzheimer’s disease.

Vascular dementia is an umbrella term for a variety of conditions characterized either by multiple large or small regions of infarction throughout the brain, or by smaller numbers of infarcts in functionally important structures such as the thalamus or hippocampus ( ). The picture is somewhat complicated by the fact that many cases with a heavy burden of vascular pathology will additionally have a coexistent burden of Alzheimer or Lewy body-type pathology.

Dementia with Lewy bodies is characterized by neocortical and limbic neuronal cytoplasmic inclusions of α-synuclein i.e. the Lewy bodies which give this condition the name. Lewy bodies were first described in Parkinson’s disease, where they are visible as round, intensely eosinophilic, hyaline intracytoplasmic neuronal inclusions in the substantia nigra and locus ceruleus of the midbrain and brainstem. They are composed of ubiquitylated α-synuclein and can therefore be detected by IHC for antisera to these proteins or p62 ( ).

Frontotemporal lobar degeneration (FTLD) is an umbrella term for a number of neuropathological entities, all of which predominantly manifest clinically as frontotemporal dementia. The different forms of FTLD are classified by the immunoreactivity of their characteristic proteinaceous intracytoplasmic inclusions ( ). However, this is a complex and constantly evolving field and classifications tend to rapidly become outdated in their finer details. In essence, the majority of cases are classified as tauopathies due to their accumulations of intracytoplasmic tau. Of the non-tauopathies, most cases show intracytoplasmic inclusions of ubiquitylated, phosphorylated TDP-43 (designated FTLD-TDP), and a few are characterized by inclusions of FUS/TLS or neurofilament. A small residuum is characterized by intracytoplasmic inclusions with immunoreactivity to p62 and ubiquitin alone (FTLD-UPS), or no observable reactivity at all, so-called ‘dementia lacking distinctive histology’.

The prion diseases are rare neurodegenerative disorders. They are of considerable interest due to the inherited nature of some forms; the tragic and rapid progression of these conditions; the public health monitoring necessary because of their transmissible nature, and similarly the risk to laboratory staff.

The normal function of prion protein is unclear, and yet it is a normal constituent of cell membranes and most highly expressed in neurons. When misfolded, it is capable of causing disease. In humans, most cases are sporadic, largely Creutzfeldt-Jakob disease (CJD); approximately 10% of cases are familial, and a few have been caused by medical intervention. Prion disease due to the consumption of matter containing misfolded prion proteins is implicated in variant CJD (vCJD) and (historically) kuru ( ).

Clinically, sporadic CJD is characterized by a rapidly progressive multifocal neurological dysfunction, sleep disturbance, myoclonic jerks, ataxia and a terminal severe globalized cognitive impairment. Death occurs after approximately 8 months ( ).

Pathologically, CJD is characterized by neuronal loss, gliosis, spongiform change (giving them their alternative name of spongiform encephalopathies), and the deposition of protease-resistant prion protein. From a practical perspective, it should be noted that prion protein is a normal constituent of the nervous system. The pathological form is detected by first treating sections with a protease enzyme to eradicate immunoreactivity to normally folded, physiological prion protein. This leaves immunoreactivity only for pathological, misfolded, protease-resistant prion protein.

Parkinsonism is characterized by tremor, hypokinesia, rigidity and postural instability. It is most commonly caused by Parkinson’s disease, which is pathologically characterized by Lewy bodies in the brainstem and midbrain structures (see above and Fig. 18.7 ). Less common causes include progressive supranuclear palsy and corticobasal degeneration, which are both characterized by neuronal intracytoplasmic accumulations of hyperphosphorylated tau, and multiple system atrophy, which is characterized by glial cytoplasmic inclusions of α-synuclein.

Most cases of motor neuron disease , in common with FTLD-TDP, are characterized by neuronal and glial cytoplasmic accumulations of hyperphosphorylated, ubiquitylated TDP-43 ( Fig. 18.8 ).

Following consideration of the principal forms of dementia as described above, it will be apparent that in order to provide a full diagnostic service, a laboratory should have access to optimized IHC for hyperphosphorylated tau, β-amyloid, α-synuclein, p62 or ubiquitin (ideally the former), TDP-43, neurofilament and protease-resistant prion protein.

Stains for detection of the changes of Alzheimer’s disease

As noted above, there are two types of Alzheimer-type pathology. Firstly, features associated with hyperphosphorylated tau: neurofibrillary tangles and neuropil threads; and secondly, features associated with β-amyloid: neuritic plaques and congophilic amyloid angiopathy. The stains and IHC preparations used in the characterization of Alzheimer-type pathology reflect this dichotomy:

  • Silver techniques (e.g. ) have been replaced by IHC for hyperphosphorylated tau ( Fig. 18.6b ) in many, but not all centers.

  • β-amyloid has historically been demonstrated by methenamine silver (which will also stain a minority of tangles; Fig. 18.9a ) and thioflavine S. These have been replaced by IHC after formic acid pretreatment (e.g. BA4; Fig. 18.9b ).

  • Some preparations can be used to detect both forms of pathology, although these tend to be less sensitive than those preparations which focus on one pathology. Thus, the modified Bielschowsky technique underestimates the β-amyloid pathology load ( ).

Guidelines for the dissection and staining of specimens in order to accurately characterize Alzheimer-type pathology have been laid down ( ).

Gallyas method for tau pathology ( )

This method gives excellent staining of neurofibrillary tangles and the neuritic pathology surrounding plaques, although the amyloid component itself is unstained. It may also be used for a number of other neurodegenerative diseases, especially argyrophilic grain disease.

Fixation

Formalin-fixed tissues.

Sections

Paraffin wax-processed sections, 8 μm thick.

Solutions

5% periodic acid

Alkaline silver iodide solution

Sodium hydroxide 40 g
Potassium iodide 100 g
Distilled water 500 ml
1% silver nitrate 35 ml

Dissolve the sodium hydroxide in water, then add the potassium iodide and wait until dissolved. Slowly add the silver nitrate and stir vigorously until clear. Then add distilled water to give a final volume of 1000 ml.

0.5% acetic acid

Stock solution a

Sodium carbonate (anhydrous) 50 g
Distilled water 1000 ml

Stock solution b (dissolve consecutively)

Distilled water 1000 ml
Ammonium nitrate 2 g
Silver nitrate 2 g
Tungstosilicic acid 10 g

Stock solution c (dissolve consecutively)

Distilled water 1000 ml
Ammonium nitrate 2 g
Silver nitrate 2 g
Tungstosilicic acid 10 g
Formaldehyde (conc.) 7.3 ml

Developer working solution

Add 3 volumes of stock solution b to 10 volumes of stock solution a . Stir and add 7 volumes of stock solution c . Stir and wait to clear.

0.1% gold chloride

1% sodium thiosulfate (‘hypo’)

0.1% nuclear fast red in 2.5% aqueous aluminum sulfate

Method

  • 1.

    Take sections to distilled water.

  • 2.

    Place in 5% periodic acid for 5 minutes.

  • 3.

    Wash twice in distilled water for 5 minutes.

  • 4.

    Place in alkaline silver iodide solution for 1 minute.

  • 5.

    Wash in 0.5% acetic acid for 10 minutes.

  • 6.

    Place in developer working solution (prepare immediately before use) for 5–30 minutes.

  • 7.

    Wash in 0.5% acetic acid for 3 minutes.

  • 8.

    Wash in distilled water for 5 minutes.

  • 9.

    Place in 0.1% gold chloride for 5 minutes.

  • 10.

    Rinse in distilled water.

  • 11.

    Place in 1% sodium thiosulfate solution for 5 minutes.

  • 12.

    Wash in tap water.

  • 13.

    Counterstain in 0.1% nuclear fast red for 2 minutes.

  • 14.

    Wash in tap water.

  • 15.

    Dehydrate, clear and mount in DPX.

Results

Neurofibrillary tangles and plaque neurites black
Nuclei red

Methenamine silver method for senile plaques ( )

This preparation has largely been superseded by βA4 IHC. It stains amyloid plaques well, but detects only a subset of neurofibrillary tangles.

Fixation

Formalin fixed.

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