FIXATION AND FIXATIVES. Types and functions.ppt
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About This Presentation
FIXATION AND FIXATIVES. Types and functions.ppt
Slide Content
FIXATION AND FIXATIVES:
DR. M.A. SEIDU/CECILIA KRAMPAH
DR. M.A. SEIDU/CECILIA KRAMPAH
INTRODUCTION
•Histopathology is a comparative science in
which:
Normal tissues of a particular area is compared
with tissues from the area for abnormalities
Abnormal tissues are compared with other
abnormal tissues from the same area for
similarities
•Histopathology is a comparative science in
which:
Normal tissues of a particular area is compared
with tissues from the area for abnormalities
Abnormal tissues are compared with other
abnormal tissues from the same area for
similarities
INTRODUCTION
•To this effect certain preparations are
necessary to ensure that there are no
misleading occurrences
•It is essential that tissues are maintained in
the same nature that they were before they
were removed from the body
•It is essential that at every stage of handling
tissues for histopathology, the preparation
must be reproducible.
•To this effect certain preparations are
necessary to ensure that there are no
misleading occurrences
•It is essential that tissues are maintained in
the same nature that they were before they
were removed from the body
•It is essential that at every stage of handling
tissues for histopathology, the preparation
must be reproducible.
CHALLENGES TO MAINTENANCE OF
TISSUES AFTER REMOVAL
•Two phenomena occur when tissues are
removed from the body or after death:
•Autolysis
•Putrefaction
TISSUES AFTER REMOVAL
•Two phenomena occur when tissues are
removed from the body or after death:
•Autolysis
•Putrefaction
AUTOLYSIS
•This is the process of self-destruction initiated soon
after cell death by the action of intracellular
enzymes located in lysosomes – Autolysis
•This results in breakdown of protein and the final
liquefaction of the cell
•Autolysis:
–is more rapid in tissues rich in enzymes such as the liver,
kidney and brain
–less so in tissues such as fibrous tissue
•This is the process of self-destruction initiated soon
after cell death by the action of intracellular
enzymes located in lysosomes – Autolysis
•This results in breakdown of protein and the final
liquefaction of the cell
•Autolysis:
–is more rapid in tissues rich in enzymes such as the liver,
kidney and brain
–less so in tissues such as fibrous tissue
Putrefaction
•This occurs as a result of bacterial decomposition
(putrefaction) producing changes in tissues that
mimic autolysis
–These changes are produced by bacterial proliferation
in the dead tissues
–The bacteria may be derived from the body’s normal
flora or may be present in infected tissues at the time
of death
•This occurs as a result of bacterial decomposition
(putrefaction) producing changes in tissues that
mimic autolysis
–These changes are produced by bacterial proliferation
in the dead tissues
–The bacteria may be derived from the body’s normal
flora or may be present in infected tissues at the time
of death
FIXATION
•FIXATION: The process by which tissues are
preserved so that they will withstand subsequent
treatment with other reagents without loss, distortion
or decomposition.
–The cells and extra-cellular materials must be preserved
in such a way that there will be as little alteration as
possible to their structure and chemical composition.
–The constituents of the tissue must be rendered insoluble
in all the reagents to which they will subsequently be
exposed
•FIXATION: The process by which tissues are
preserved so that they will withstand subsequent
treatment with other reagents without loss, distortion
or decomposition.
–The cells and extra-cellular materials must be preserved
in such a way that there will be as little alteration as
possible to their structure and chemical composition.
–The constituents of the tissue must be rendered insoluble
in all the reagents to which they will subsequently be
exposed
FIXATION
•Fixation is therefore:
–The first step in histopathological
examination
–And represents the foundation for
subsequent stages in the preparation of
tissue for microscopic examination.
–The chemicals and physical agents used in
fixation are called FIXATIVES
•Fixation is therefore:
–The first step in histopathological
examination
–And represents the foundation for
subsequent stages in the preparation of
tissue for microscopic examination.
–The chemicals and physical agents used in
fixation are called FIXATIVES
AIMS OF FIXATION
Preserve cells and tissue constituents in as close to
the living state as possible
Prevent the process of autolysis and putrefaction
Allow fixed tissues to undergo further procedures
without alteration in shape or volume and no loss of
small molecules
Leave tissues in a condition which subsequently
allows staining.
Preserve cells and tissue constituents in as close to
the living state as possible
Prevent the process of autolysis and putrefaction
Allow fixed tissues to undergo further procedures
without alteration in shape or volume and no loss of
small molecules
Leave tissues in a condition which subsequently
allows staining.
•TISSUE CONTITUENTS INVOLVED IN
FIXATION
Protein is the most important tissue constituent as
far as fixation is concerned.
•This is because the structure of any animal
tissue is determined largely by the configuration
of its proteins
•Other tissue components to be preserved in
fixation are:
–Nucleic acids
–Carbohydrates
–Lipids,
FIXATION
Protein is the most important tissue constituent as
far as fixation is concerned.
•This is because the structure of any animal
tissue is determined largely by the configuration
of its proteins
•Other tissue components to be preserved in
fixation are:
–Nucleic acids
–Carbohydrates
–Lipids,
CLASSIFICATION OF FIXATIVES
•CHEMICAL AGENTS
Aldehydes
Oxidising agents
Protein-denaturing agents
Miscellaneous chemical agents
•PHYSICAL AGENTS
Heat, microwave
Freezing
•CHEMICAL AGENTS
Aldehydes
Oxidising agents
Protein-denaturing agents
Miscellaneous chemical agents
•PHYSICAL AGENTS
Heat, microwave
Freezing
CHEMICAL FIXATIVES
Aldehydes:
–Formaldehyde, glutaraldehyde, glyoxal.
Oxidising agents
–Osmium tetroxide, potassium permanganate, potassium
dichromate
Protein-denaturing agents
–Acetic acid, methanol, ethanol
Miscellaneous chemical agents
–Mercuric chloride, picric acid
Aldehydes:
–Formaldehyde, glutaraldehyde, glyoxal.
Oxidising agents
–Osmium tetroxide, potassium permanganate, potassium
dichromate
Protein-denaturing agents
–Acetic acid, methanol, ethanol
Miscellaneous chemical agents
–Mercuric chloride, picric acid
•PHYSICAL METHODS
Heat,
-Microwave,
-Boiling
Freezing
–Frozen sections
–Freeze-drying: Rapidly freezing of fresh tissue at -160
o
C
and subsequently removing water molecules by
sublimation in a vacuum.
–Freeze substitution: Rapidly freezing of tissue and the
substitution of the ice removed by a dehydrating solution
Heat,
-Microwave,
-Boiling
Freezing
–Frozen sections
–Freeze-drying: Rapidly freezing of fresh tissue at -160
o
C
and subsequently removing water molecules by
sublimation in a vacuum.
–Freeze substitution: Rapidly freezing of tissue and the
substitution of the ice removed by a dehydrating solution
MECHANISMS OF FIXATION
REACTION OF FIXATIVES WITH PROTEINS
• Probably the most well known in fixation
•Fixatives form cross-links between proteins.
•Increasing polymerization m.w. resulting in
increased viscosity and formation of a gel
•Soluble proteins are rendered insoluble by being
fixed to structural proteins.
REACTION OF FIXATIVES WITH PROTEINS
• Probably the most well known in fixation
•Fixatives form cross-links between proteins.
•Increasing polymerization m.w. resulting in
increased viscosity and formation of a gel
•Soluble proteins are rendered insoluble by being
fixed to structural proteins.
Aldehydes
•Aldehydes form cross-linkages
•The reaction with formaldehyde is reversible by an
excess of water
•Glutaraldehyde is most effective at cross-linking
and the reaction is rapid and irreversible.
Oxidizing Agents
•Mechanism of reaction with proteins by oxidizing
agents is not known.
•Osmium tetroxide forms cross-links with proteins.
•Potassium permanganate and dichromate are less
reactive towards proteins.
•Aldehydes form cross-linkages
•The reaction with formaldehyde is reversible by an
excess of water
•Glutaraldehyde is most effective at cross-linking
and the reaction is rapid and irreversible.
Oxidizing Agents
•Mechanism of reaction with proteins by oxidizing
agents is not known.
•Osmium tetroxide forms cross-links with proteins.
•Potassium permanganate and dichromate are less
reactive towards proteins.
Mercuric chloride
•The chemistry of fixation by HgCl
2 is poorly
understood.
Heat/Microwave irradiation
•Application of heat results in the coagulation of
proteins.
•Externally applied heat acts first on the superficial
layers but heat delivered by microwaves is absorbed
at all depths within a specimen.
•Microwave energy interacts with dipolar molecules
causing their oscillation with a frequency of 2.5
GHz (billion cycles per second)
•The chemistry of fixation by HgCl
2 is poorly
understood.
Heat/Microwave irradiation
•Application of heat results in the coagulation of
proteins.
•Externally applied heat acts first on the superficial
layers but heat delivered by microwaves is absorbed
at all depths within a specimen.
•Microwave energy interacts with dipolar molecules
causing their oscillation with a frequency of 2.5
GHz (billion cycles per second)
Heat/Microwave irradiation
•Water molecules and polar side-chains of proteins
throughout the tissue have their thermal energy
increased with consequent heating of proteins
•There is no significant cross-linking of the protein
molecules, but proteins are stabilized through
denaturation.
•Water molecules and polar side-chains of proteins
throughout the tissue have their thermal energy
increased with consequent heating of proteins
•There is no significant cross-linking of the protein
molecules, but proteins are stabilized through
denaturation.
•Heat/Microwave irradiation
•When the specimen is already immersed in a
chemical fixative, microwave radiation:
–promotes diffusion of fixative into the tissue
–in formaldehyde-based fixatives, accelerates the cross-
linking of proteins
•When microwave radiation is the sole fixative agent,
cellular distortion occurs so that close resemblance
to the living state is lost.
•The practice is to heat the specimen, already
immersed in a chemical fixative
•When the specimen is already immersed in a
chemical fixative, microwave radiation:
–promotes diffusion of fixative into the tissue
–in formaldehyde-based fixatives, accelerates the cross-
linking of proteins
•When microwave radiation is the sole fixative agent,
cellular distortion occurs so that close resemblance
to the living state is lost.
•The practice is to heat the specimen, already
immersed in a chemical fixative
REACTION OF FIXATIVES WITH NUCLEIC ACIDS
•Not much is known about the reaction of nucleic
acids with fixatives.
•In their normal state, DNA and RNA do not react
with formaldehyde or glutaraldehyde.
•However, their association with protein
(nucleoprotein), allows cross-linkages of the
proteins to prevent their dissolution.
•Since there is little “fixation” of nucleic acids, their
retention in tissues must be due to entrapment by the
protein gel
•Not much is known about the reaction of nucleic
acids with fixatives.
•In their normal state, DNA and RNA do not react
with formaldehyde or glutaraldehyde.
•However, their association with protein
(nucleoprotein), allows cross-linkages of the
proteins to prevent their dissolution.
•Since there is little “fixation” of nucleic acids, their
retention in tissues must be due to entrapment by the
protein gel
REACTION OF FIXATIVES WITH LIPIDS
•In general, following aldehyde fixation, many
lipids are still labile.
•Phospholipids containing amino groups are fixed
by aldehydes
•The only chemical agents that truly fix lipids are
osmium tetroxide and chromic acid.
•In general, following aldehyde fixation, many
lipids are still labile.
•Phospholipids containing amino groups are fixed
by aldehydes
•The only chemical agents that truly fix lipids are
osmium tetroxide and chromic acid.
REACTION OF FIXATIVES WITH CARBOHYDRATES
•Two main carbohydrates are considered in tissue
carbohydrate demonstration, glycogen and mucins.
•Two schools of thought concerning glycogen
fixation:
–Removal of bound water molecules from glycogen by the
fixative decreases its solubility - equivalent to
denaturation
–Preservation is due to fixation of associated proteins
rather than glycogen itself or the result of trapping in a
matrix of fixed protein.
•Two main carbohydrates are considered in tissue
carbohydrate demonstration, glycogen and mucins.
•Two schools of thought concerning glycogen
fixation:
–Removal of bound water molecules from glycogen by the
fixative decreases its solubility - equivalent to
denaturation
–Preservation is due to fixation of associated proteins
rather than glycogen itself or the result of trapping in a
matrix of fixed protein.
•REACTION OF FIXATIVES WITH CARBOHYDRATES
•Alcoholic fixatives are preferred by some workers
for mucins
•Alcohols act partly by forming a meshwork of
denatured protein, and partly by precipitating the
carbohydrate moiety
•Procedures requiring long immersion in aqueous
solutions may lead to some loss of precipitated
mucins and glycogen.
•Alcoholic fixatives are preferred by some workers
for mucins
•Alcohols act partly by forming a meshwork of
denatured protein, and partly by precipitating the
carbohydrate moiety
•Procedures requiring long immersion in aqueous
solutions may lead to some loss of precipitated
mucins and glycogen.
FIXATIVES
IDEAL FIXATIVE
•An ideal fixative should:
Penetrate a tissue quickly
Be rapid in action
Be isotonic
Cause a minimum loss and minimal physical and
chemical alteration of the cell and its components
Be affordable, stable and safe to handle
•These are not completely fulfilled by
any single fixative.
•An ideal fixative should:
Penetrate a tissue quickly
Be rapid in action
Be isotonic
Cause a minimum loss and minimal physical and
chemical alteration of the cell and its components
Be affordable, stable and safe to handle
•These are not completely fulfilled by
any single fixative.
FIXATIVES
•Fixatives are placed in two categories.
•Simple fixatives: Single chemicals acting as
fixatives
•Compound fixatives: Since no single chemical can
fulfil all the requirements of histopathology a
mixture of chemicals could carry some advantage
•Fixatives are placed in two categories.
•Simple fixatives: Single chemicals acting as
fixatives
•Compound fixatives: Since no single chemical can
fulfil all the requirements of histopathology a
mixture of chemicals could carry some advantage
FORMALDEHYDE (FORMALIN)
The most widely used fixative in histopathology,
either by itself or in combinations with other
chemicals.
It is a gas sold as a saturated solution of
formaldehyde (H.CHO) in water containing 40%
gas by weight.
For the purposes of determining strengths of diluted
solutions the 40% (saturated solution) is regarded
as 100% formalin.
The most widely used fixative in histopathology,
either by itself or in combinations with other
chemicals.
It is a gas sold as a saturated solution of
formaldehyde (H.CHO) in water containing 40%
gas by weight.
For the purposes of determining strengths of diluted
solutions the 40% (saturated solution) is regarded
as 100% formalin.
FORMALDEHYDE (FORMALIN)
Formalin fixatives become acidic when oxidised
which reduces its preserving capabilities.
When acidic Formalin solution is used on bloody
tissues, they produce brown pigments (formalin
pigments).
Buffering with NaH
2PO
4 and Na
2HPO
4 can
effectively neutralize formalin fixatives and prevent
the formation of the pigments.
CaCO
3 chips can also be used for neutralizing
formalin, but CaCO
3
can be deposited in tissues,
producing ‘pseudocalcification
Formalin fixatives become acidic when oxidised
which reduces its preserving capabilities.
When acidic Formalin solution is used on bloody
tissues, they produce brown pigments (formalin
pigments).
Buffering with NaH
2PO
4 and Na
2HPO
4 can
effectively neutralize formalin fixatives and prevent
the formation of the pigments.
CaCO
3 chips can also be used for neutralizing
formalin, but CaCO
3
can be deposited in tissues,
producing ‘pseudocalcification
TYPES OF FORMALDEHYDE FIXATIVES
10% Formalin
10% Buffered neutral formalin
10% Formal saline – 100ml 40% formaldehyde + 9
gm NaCl + 900ml distilled water.
Alcoholic formalin – 40% formaldehyde (100ml) +
95% alcohol (900ml) + 0.5 gm calcium acetate for
neutrality.
Formal calcium – 40% formaldehyde (100ml) +
distilled water (900ml) + 10% CaCl
2
(100ml).
10% Formalin
10% Buffered neutral formalin
10% Formal saline – 100ml 40% formaldehyde + 9
gm NaCl + 900ml distilled water.
Alcoholic formalin – 40% formaldehyde (100ml) +
95% alcohol (900ml) + 0.5 gm calcium acetate for
neutrality.
Formal calcium – 40% formaldehyde (100ml) +
distilled water (900ml) + 10% CaCl
2
(100ml).
•ADVANTAGES OF FORMALIN FIXATIVES
Cheap, easy to prepare and relatively stable,
especially if buffered
Allows subsequent application of many staining
techniques without special preliminary procedures.
Frozen sections can be prepared with ease from
formalin-fixed material.
Cheap, easy to prepare and relatively stable,
especially if buffered
Allows subsequent application of many staining
techniques without special preliminary procedures.
Frozen sections can be prepared with ease from
formalin-fixed material.
ADVANTAGES OF FORMALIN FIXATIVES
Staining for fat and some enzymes can easily be
carried out on tissues fixed in formalin
Penetrates tissue reasonably well (medium
speed fixative)
Natural tissue colours can be restored after
formalin fixation.
Staining for fat and some enzymes can easily be
carried out on tissues fixed in formalin
Penetrates tissue reasonably well (medium
speed fixative)
Natural tissue colours can be restored after
formalin fixation.
DISADVANTEGES OF FORMALIN FIXATION
May lead to dermatitis of the hands of some workers
Fumes are irritating to nostril and eyes
Use of unbuffered formalin tends to reduce
basophilic staining i.e., does not give the best
nuclear definition
May lead to dermatitis of the hands of some workers
Fumes are irritating to nostril and eyes
Use of unbuffered formalin tends to reduce
basophilic staining i.e., does not give the best
nuclear definition
DISADVANTEGES OF FORMALIN FIXATION
Formation of formalin pigment in tissue
containing blood (e.g., spleen)
Reduces PAS positivity of reactive mucins due
to its polymerizing action
Potentially carcinogenic
Formation of formalin pigment in tissue
containing blood (e.g., spleen)
Reduces PAS positivity of reactive mucins due
to its polymerizing action
Potentially carcinogenic
CHROMATE
A strong oxidizing agent
Not used alone but in combination with other
ingredients
Penetrates slowly and leaves tissues in a state in
which shrinkage may occur during subsequent
processing
Potassium dichromate reacts with adrenal to
produce black or brown water-insoluble precipitates
Oxidation product is visible both grossly and in
histological sections
A strong oxidizing agent
Not used alone but in combination with other
ingredients
Penetrates slowly and leaves tissues in a state in
which shrinkage may occur during subsequent
processing
Potassium dichromate reacts with adrenal to
produce black or brown water-insoluble precipitates
Oxidation product is visible both grossly and in
histological sections
ADVANTAGES
Preserves phospholipids in paraffin sections
Chromation increases the intensity of PAS reaction
in PAS-reactive lipids
DISADVANTAGES
Tissue should be washed thoroughly to prevent
dichromate reacting with dehydrating alcohols to
produce an insoluble green precipitate that cannot
be removed in later processing
Preserves phospholipids in paraffin sections
Chromation increases the intensity of PAS reaction
in PAS-reactive lipids
DISADVANTAGES
Tissue should be washed thoroughly to prevent
dichromate reacting with dehydrating alcohols to
produce an insoluble green precipitate that cannot
be removed in later processing
•ALCOHOLIC FIXATIVES
Methanol and ethanol are the only alcohols used as
fixatives
Alter protein structure by denaturation
Both are closely related to water in structure and
compete with the latter for hydrogen bonds
replacing water molecules in tissues
Methanol and ethanol are the only alcohols used as
fixatives
Alter protein structure by denaturation
Both are closely related to water in structure and
compete with the latter for hydrogen bonds
replacing water molecules in tissues
CARNOY’S FLUID
•It is the only alcoholic fixative generally used in
histopathology - absolute ethanol 60ml, chloroform
30ml and glacial acetic acid 10 ml
ADVANTAGES
Penetrates tissues rapidly; fixes small tissue
fragments and used for urgent paraffin processing of
small biopsies
Initiates dehydration and tissues can be transferred
after fixative directly to absolute alcohol
•It is the only alcoholic fixative generally used in
histopathology - absolute ethanol 60ml, chloroform
30ml and glacial acetic acid 10 ml
ADVANTAGES
Penetrates tissues rapidly; fixes small tissue
fragments and used for urgent paraffin processing of
small biopsies
Initiates dehydration and tissues can be transferred
after fixative directly to absolute alcohol
Preserves macromolecular carbohydrates and is a
good fixative for glycogen
Precipitates nuclear proteins and at the same time
break the bonds between nucleic acids and proteins,
thereby increasing the number of acidic groups
available for staining. Therefore:
–Recommended if nucleic acids are to be studied in
paraffin sections
–Nuclear staining and definition are good
•DISADVANTAGES
Carnoy’s fluid lyses red cells (due to acetic acid)
It causes considerable shrinkage and is suitable for
only small pieces of tissue
Lipids and myelin are dissolved by it
good fixative for glycogen
Precipitates nuclear proteins and at the same time
break the bonds between nucleic acids and proteins,
thereby increasing the number of acidic groups
available for staining. Therefore:
–Recommended if nucleic acids are to be studied in
paraffin sections
–Nuclear staining and definition are good
•DISADVANTAGES
Carnoy’s fluid lyses red cells (due to acetic acid)
It causes considerable shrinkage and is suitable for
only small pieces of tissue
Lipids and myelin are dissolved by it
It is contraindicated whenever lipids are to be
studied due to lipid extraction
Tends to harden tissues excessively and always
distorts morphology
Prolonged fixation for more than 18 hours can result
in loss of RNA and DNA.
studied due to lipid extraction
Tends to harden tissues excessively and always
distorts morphology
Prolonged fixation for more than 18 hours can result
in loss of RNA and DNA.
•ACETONE
Similar in action to ethanol and methanol but does
not make liver glycogen insoluble
Has a rapid action but causes brittleness if tissue
exposure is prolonged
More volatile than alcohols and because of this and
its flammability, it is not used in automated
processing schedules
Similar in action to ethanol and methanol but does
not make liver glycogen insoluble
Has a rapid action but causes brittleness if tissue
exposure is prolonged
More volatile than alcohols and because of this and
its flammability, it is not used in automated
processing schedules
ACETIC ACID
Never used alone:
–Fixes only nucleoproteins by precipitation – does not fix
proteins
–Causes tissues to swell
Used in combination with other fixatives that cause
shrinkage, such as ethanol, methanol and picric acid
Penetrates rapidly and thoroughly
Causes lyses of red cells
All mucins except gastric neutral mucin are
precipitated by acetic acid.
Never used alone:
–Fixes only nucleoproteins by precipitation – does not fix
proteins
–Causes tissues to swell
Used in combination with other fixatives that cause
shrinkage, such as ethanol, methanol and picric acid
Penetrates rapidly and thoroughly
Causes lyses of red cells
All mucins except gastric neutral mucin are
precipitated by acetic acid.
•PICRIC ACID
Used in combination with other fixatives
Penetrates well and leaves tissue soft but causes
considerable shrinkage.
Causes loss of basophilia (little affinity for basic
dyes) unless the tissue is thoroughly washed
following fixation
Preserves glycogen well
Used in combination with other fixatives
Penetrates well and leaves tissue soft but causes
considerable shrinkage.
Causes loss of basophilia (little affinity for basic
dyes) unless the tissue is thoroughly washed
following fixation
Preserves glycogen well
•ADVANTAGES
One of the best fixatives for demonstrating glycogen
Small fragments of tissue are easily identified as
they pick up the yellow colour of picric acid
In a fixative mixture produces bright staining with
dyes
•DISADVANTAGES
Lyses red cells
Tissues left in fluid for longer than 12 to 24 hours
become hard and brittle and difficult to section
Tissues fixed in picric acid solutions crumble when
frozen sections are cut
One of the best fixatives for demonstrating glycogen
Small fragments of tissue are easily identified as
they pick up the yellow colour of picric acid
In a fixative mixture produces bright staining with
dyes
•DISADVANTAGES
Lyses red cells
Tissues left in fluid for longer than 12 to 24 hours
become hard and brittle and difficult to section
Tissues fixed in picric acid solutions crumble when
frozen sections are cut
•BOUIN’S FLUID
Saturated aqueous picric acid (750 ml), 40%
Formalin (250 ml), Glacial acetic acid (50 ml)
The complete Bouin’s formula is a stable solution
and keeps indefinitely
Preserves morphology such as nuclei and connective
tissue
Physical distortion of tissue is minimal
Paraffin sections are easy to cut
Saturated aqueous picric acid (750 ml), 40%
Formalin (250 ml), Glacial acetic acid (50 ml)
The complete Bouin’s formula is a stable solution
and keeps indefinitely
Preserves morphology such as nuclei and connective
tissue
Physical distortion of tissue is minimal
Paraffin sections are easy to cut
•ROSSMAN’S FLUID
100% ethanol saturated with picric acid (900 ml)
and neutralized commercial formalin (100 ml)
Fixation time 12-24 hours; wash very well in 95%
ethanol
100% ethanol saturated with picric acid (900 ml)
and neutralized commercial formalin (100 ml)
Fixation time 12-24 hours; wash very well in 95%
ethanol
•MERCURIC CHLORIDE
Usually combined with other fixatives
Mixtures containing mercuric chloride include:
- Zenker’s,
- Helly’s,
- Susa
- Formol sublimate
Usually combined with other fixatives
Mixtures containing mercuric chloride include:
- Zenker’s,
- Helly’s,
- Susa
- Formol sublimate
•ADVANTAGES
Give better staining of nuclei and connective tissue
Cytoplasmic staining with acidic dyes is enhanced
•DISADVANTAGES
Solutions of mercuric chloride corrode all metals
except nickel alloys
Zenker’s solution causes considerable lysis of red
cells and removes much iron from haemosiderin.
All mercurial fixatives reduce the amount of
demonstrable glycogen
Give better staining of nuclei and connective tissue
Cytoplasmic staining with acidic dyes is enhanced
•DISADVANTAGES
Solutions of mercuric chloride corrode all metals
except nickel alloys
Zenker’s solution causes considerable lysis of red
cells and removes much iron from haemosiderin.
All mercurial fixatives reduce the amount of
demonstrable glycogen
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