Tissue Fixation Histopathology

Tissue fixation Noor Ullah Lecturer MLT, STMU 5/10/2017 1

Micro techniques Micro technique deals with the preparation of tissues for microscopic examination. It is the study of procedures to reach the final stained slide of the specimen.

Stages in Histopathology Documentation Fixation Gross examination Decalcification Tissue processing Embedding Sectioning Staining Mounting

Type of material obtained in laboratory The human tissue comes from the surgery (Biopsy) and/or from the dissection room (Autopsy). From surgery two types of biopsy could be obtained : Incisional Biopsy : A small piece of lesions or tumor is removed and sent for diagnosis before final removal of the lesion or tumor . Excisional Biopsy: whole tumor or lesion is removed for examination.

Excision Cell Death Fixation Embedding Dehydration Examination and Diagnosis Ancillary Studies T i m e { Nucleases Proteases Lipases Saccharidases The time between excision and fixation can vary widely, as can the conditions of fixation. Tissue Processes in Pathology

Proteases Destroy protein antigens Not all protein antigens are destroyed at the same rate Nucleases Destroy nucleic acids RNA destroyed much more quickly than DNA Found in different levels in different tissues. For example, pancreas and eosinophils have extremely high levels of ribonucleases

Stability In general DNA>Protein>RNA Some proteins are essentially as stable as DNA, however. Fixation Stops degradation of cellular components by enzymes Preserves cellular morphology

Definition of fixation Process by which the constituents of the cells and therefore of the tissues are fixed in a physical, partly also in a chemical state so that they will withstand the subsequent treatment with various reagents with minimal loss , distortion or decomposition . Fixation is the foundation for the subsequent stages in the preparation of the sections

Why fixation is done? If a fresh tissue is kept at room temperature it will become liquefied with a foul odor mainly due to action of bacteria i.e. putrefaction and autolysis so the first and fore most aim of fixation is To preserve the tissue in as life like manner as possible. To prevent postmortem changes like autolysis and putrefaction. Autolysis :is the lysis or dissolution of cells by its own enzyme action probably as a result of rupture of lysosomes. Putrefaction: The breakdown of tissue by bacterial action often with formation of gas.

Why fixation is done? 3. Preservation of chemical compounds and micro anatomic constituents so that further histochemistry is possible. 4. Hardening : the hardening effect allows easy manipulation of soft tissue like brain, intestines etc. 5. Solidification: Converts the normal semifluid consistency of cells (gel)to an irreversible semisolid consistency (solid). 6. Optical differentiation : Fixatives alter to varying degrees the refractive indices of the various components of cells and tissues and thus increase its optical differentiation. 6. Effects of staining : Certain fixatives like formaldehyde intensifies the staining character of tissue especially with haematoxylin .

Properties of an Ideal Fixative Prevents autolysis and bacterial decomposition. Preserves tissue in their natural state and fix all components. Make the cellular components insoluble to reagent used in tissue processing. Preserves tissue volume. Avoid excessive hardness of tissue. Allows enhanced staining of tissue. Should be non-toxic and non-allergic and non corrosive for user. Should not be very expensive. It must penetrate the tissue rapidly and evenly It must be simple to prepare and economical to use

Reaction Of Fixatives Proteins: Cross links are formed between proteins. Soluble proteins are fixed to structural proteins-insoluble-mechanical strength-allowing subsequent manipulations on tissues Formaldehyde -reversible. Glutaraldehyde -rapid & irreversible. React with basic amino-acid residues

Reaction Of Fixatives Nucleic acid: Fixation brings a change in the physical & chemical state of RNA & DNA. Uncoiling of DNA & RNA occurs with formalin when heated to 45˚C & 65˚C respectively.

3. Lipids: Phospholipids are fixed by aldehydes. Formaldehyde reacts with unsaturated fatty acids hence less lipid can be demonstrated in tissue stored in it for a long time. Mercuric chloride reacts with lipids to form complexes. Ultrastructural demonstration of lipids – post fixing in imidazole-osmium tetroxide.

4. Carbohydrates: Carbohydrates are more water soluble- difficulty in total preservation They bind with fixed protein So the fixatives which are used for proteins, can be used for carbohydrate preservation. Fixed protein traps carbohydrates. Glycogen not bound to protein- fixed protein form lattice around glycogen to preserve it Glycogen are more demonstrable in liver cells

Fixation artifacts Fixation is associated with some artifacts: Formaldehyde fixatives give brown pigmentation to tissues Mercuric chloride fixatives leave a black precipitate in tissues Some fixatives produce shrinkage in tissues while some others cause swelling. Due to poor penetration of fixatives macromolecules like glycogen diffuse from unfixed parts giving false localization or loss. This is termed streaming artifact and mostly seen in case of glycogen.

Factors affecting fixation Buffers & hydrogen ion concentration: Best fixation occurs between pH 6-8 Buffers used – phosphate, s- collidine , bicarbonate, Temperature: Most tissues fixed– room temp Electron microscopy & histochemistry: 0-4˚C Penetration of tissues: Blocks should be small or thin to ensure adequate penetration.

Factors affecting fixation Volume changes: Due to inhibition of respiration, membrane permeability changes, changes in ion transport through membrane. Tissues fixed in formaldehyde & embedded in paraffin shrink by 33% Osmolality of fixative: Hypertonic solutions – cell shrinkage hypotonic solutions – swelling of cells & poor fixation. Best – slightly hypertonic solutions.

Substances to vehicle: Adding substances to fulfill certain functions. Denaturing effects, some stabilize proteins. Eg . Sodium chloride & sodium sulphate used with mercuric chloride. Tannic acid enhances fixation of lipids & proteins in EM Concentration of fixatives : Different concentrations have different effects on morphology. Effects subsequent staining

Duration of fixation: Formalin – 2-6hours Electron microscopy – 3 hours Formaldehyde – prolonged fixation – shrinkage & hardening of tissue. Gluteraldehyde – prolonged fixation – advantageous. Long fixation in aldehydes - inhibits enzyme activity. Long fixation in oxidizing fixatives – degrade the tissue.

General classification of fixatives Aldehydes: formaldehyde, glutaraldehyde, acrolein Oxidizing agents: osmium tetroxide, potassium permanganate, potassium dichromate Protein denaturing agents: acetic acid, methyl alcohol, ethyl alcohol Other cross linking agents : carbodiimides Physical agents: heat, microwave, Freeze drying Unknown mechanism: mercuric chloride, picric acid HOPE fixatives: formalin like morphology, good protein antigenicity for enzyme histochemistry, good for RNA & DNA yeilds

Baker classification Coagulant fixatives includes: Formaldehyde Gluteraldehyde Osmium Tetroxide Potassium Dichromate Acetic Acid Non-Coagulant fixatives includes: Alcohol Zinc salts Mercuric chloride Chromium trioxide Picric Acid

Classification-based on structure Micro-anatomical fixatives: When anatomy of tissues with correct relationship of tissue layers & large aggregate of cells is to be preserved. Cytological fixatives: To preserve constituent elements of cells. Elements being preserved at the expense of penetration, ease of cutting & loss of other cell structures. Histochemical fixatives: Used when histochemical tests are to be applied ( IHC)

Micro anatomical fixatives Routine formalin fixatives: 10% Formol -Saline : 10% formalin in 0.9% sodium chloride. Layer of marble chips/calcium carbonate added to neutralize formic acid production. Buffered Formalin: Formalin – 10ml Acid sodium phosphate monohydrate 0.4g Anhydrous disodium phosphate 0.65g Water to 100ml

Micro anatomical fixatives Formol Calcium(Baker) Formalin – 10ml Calcium chloride – 2g Water – 100ml Chloride preserves phospholipids Formol Calcium(Lillie) Acetate instead of chloride Easily prepared Widely used for routine fixation.

Mechanism of action: Aldehydes (cross linking agents)- act by creating covalent chemical bonds between proteins of tissues- anchor the insoluble compound to cytoskeleton-protect secondary as well as tertiary structure of protein-provide mechanical strength/ additional rigidity to tissue structure. Oxidizing agents- joins with various side chains of protein molecules & other biomolecules- allow formation of cross link- stabilizes tissue structure

Protein denaturing agents : reduce the solubility of protein without combining with it & disrupts the hydrophobic bonds which is needed for its tertiary structure to form. Mercurials (B5 fixatives ): it increases the staining brightness & give good nuclear detail. Good for reticulo -endothelial tissue & hematopoietic tissue. Picrates : binds with histone & basic proteins to form crystalline picrates with amino acid & precipitates protein.

FORMALDEHYDE Gas soluble in water up to 40% by wt. Available as 40% formaldehyde or formalin. Stabilizer – 10-14% methanol 10% formalin Acidic solution. On storage becomes acidic by formation of formic acid. Colourless . Turbid on keeping - paraformaldehyde. fixes protein, lipids well preserved. Favors staining of acidic structures like nuclei with basic dyes Diminishes effect of acid dyes on basic structures like cytoplasm .

Advantages: Formalin is cheap Easy to prepare Relatively stable Frozen sections can be prepared with ease. Staining of fat and tissue enzymes. Penetrates tissues well. Beneficial hardening with little shrinkage

Formaldehyde- Advantages Formalin is cheap Easy to prepare Relatively stable Frozen sections can be prepared with ease. Staining of fat and tissue enzymes. Penetrates tissues well. Beneficial hardening with little shrinkage Natural tissue colors are retained. Does not require washing before processing. Best fixative for nervous system

Formaldehyde- disadvantages unpleasant vapor irritation to eyes & respiratory epithelium Formalin dermatitis Brown, granular material, extracellular , birefringent Progressive in deposition Often seen after several days Action of acid formalin on blood Avoided by using buffered formalin . Removed – treatment with saturated alcoholic solution of picric acid for 20mins

Formaldehyde- disadvantages Pink disease Peculiar artifact seen in sections fixed in formal saline & stained with H&E . Complete or partial failure of nuclei to stain with haematoxylin – take up eosin – loss of nuclear margin distinction. Lymphoid & epithelial tissue – most distinct Patchy distribution Avoided by using - 2% acetic acid in 10% formalin When present – treat with 1% hydrochloric acid in absolute alcohol for 1 hour before staining with H&E.

GLUTERALDEHYDE Used for Electron Microscopy with osmium tetroxide Advantage: Most efficient cross linking agent for collagen More rapid fixation than formalin. Disadvantage : Poorer penetration False positivity with PAS More costly

MERCURIC CHLORIDE White crystalline substance. Powerful protein precipitant , fixes both nucleus & cytoplasm well favoring its staining. Conjunction with other fixatives . Advantages: Rapidly penetrates & hardens tissue, radio-opaque Disadvantages: Extremely poisonous & corrosive to metals . Intolerant fixative. Pollution to environment.

MERCURIC CHLORIDE Mercury pigment – brown to black granular deposit. Treatment- Place section in 0.5% iodine in 80% alcohol for 3mins Rinse in water Place in 3% aqueous sodium thiosulphate for 3mins Wash in running water for 1-2mins

PICRIC ACID Bright yellow crystalline substance. Damped with water because of explosive properties . Enhances cytoplasmic staining . Acts as mordant Much shrinkage but little hardening.

POTASSIUM DICHROMATE Orange crystalline substance Less acidic pH – fixes cytoplasm & mitochondria More acidic pH – fixes nucleus & cytoplasm Mordant Wash in running water after to prevent formation of insoluble precipitate. Prolonged exposure causes tissue to become brittle.

OSMIUM TETROXIDE Pale yellow. Demonstrates lipid like myelin. Excellent preservation of detail of single cells hence used for EM. Uneven penetration for pieces more than 2-3mm Storage in dark, cool place Vapour is irritating, causes conjunctivitis Uneven fixation

ACETIC ACID Colorless liquid with pungent odor. Used in compound fixatives Swells collagen fibres Precipitates nucleoproteins Solvent action on cytoplasmic granules.

ETHYL ALCOHOL Colorless. Powerful dehydrating agent. Causes shrinkage & hardening Coagulates protein but not nucleoprotein. Precipitates glycogen. Used in histochemical method for enzymes.

Fixatives for DNA, RNA, and protein analysis The compounds included the commercially available HOPE ( H epes -glutamic acid buffer mediated O rganic solvent P rotection E ffect) for the detection of nucleic acids, in addition to zinc-based fixatives. In contrast to other fixation methods HOPE does not completely denature or cross-link structural proteins, enzymes, and nucleic acids. They remain in an almost native state. This means that HOPE- fixed tissue can also include active viruses, prions, microorganisms etc.

Fixation for selected individual tissues Eyes: Eyes may be fixed in NBF, usually for 48 hours. After gross description, the anterior (iris) and posterior (e.g. optic nerve) are removed with a new, sharp razor blade and the components of the globe are fixed for an additional 48 hours, or more, in buffered formaldehyde, before being processed. Embedding may be in celloidin or paraffin .

Fixation for selected individual tissues Brain: The problem of fixing a whole brain is to render it firm enough to investigate the neuroanatomy and to produce sections to show histopathology and to respond to immunochemistry if required. Conventionally this fixation takes at least 2 weeks . Perfusion technique is used which allows to fix brain tissue and the report issued in 5–6 days. This method depends on the perfusion of the brain via the middle cerebral arteries. Fixatives may also be enhanced by the use of microwave technology. Alcoholic formalin should not be used for fixation if immunohistochemistry is to be performed using biotin-avidin (streptavidin) methods

Fixation for selected individual tissues Breast: Clinical samples should be fixed in 10% NBF for between a minimum of 6–8 hours and a maximum of 72 hours, and should be sliced at 5mm intervals after appropriate gross inspection and margins designation. Time from tissue acquisition to fixation should be as short as possible in order to prevent lysis of clinically important biomarkers, such as estrogen receptors, progesterone receptors and the human epidermal growth factor receptor-2 (HER2). They should be placed in a sufficient volume of NBF to allow adequate tissue penetration. If the tumor specimen has come from a remote geographical location, it should be bisected through the tumor on removal and sent to the laboratory immersed in a sufficient volume of NBF (Hammond et al., 2010).

Fixation for selected individual tissues Lungs: Lung biopsies are typically fixed in NBF . The lungs from autopsies may be inflated by and fixed in NBF via the trachea or major bronchi. Gross sections are fixed overnight and sections to be processed and cut the next day.

Fixation for selected individual tissues Lymphoid tissue: Special care should be taken with all lymphoid tissue, as many organisms (e.g. Mycobacterium tuberculosis and viruses) may sequester themselves in the lymphoid reticular system. The lymphoid tissue is usually sliced and a representative sample of fresh tissue taken for special studies (e.g. flow cytometry or molecular analysis). The rest of the lymph node is fixed in NBF, though some laboratories fix part of the tissue in B5 or zinc.

Fixation for selected individual tissues Testis: Biopsies of the testes are fixed routinely in NBF . Muscle biopsies: Biopsies of muscle are received fresh. A portion is separated for enzyme histochemistry. The tissue for routine histological assessment is fixed in NBF and embedded so the fibers of the specimens are viewed in cross-section and longitudinally.

Fixation for selected individual tissues Renal biopsies: Renal core biopsies should be subdivided into three and each piece should contain adequate numbers of glomeruli. Each portion is then preserved, depending upon the method to be used for analysis: NBF for routine histology Buffered glutaraldehyde (pH 7.3) for ultrastructural analysis Sudden frozen in isopentane and liquid nitrogen for immunofluorescence examination.

Tissue Fixation Histopathology

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