Cell Injury 3

Question 1

Morphologic features of necrosis- CYTOPLASMIC CHANGES

Answer 1

-EARLY PHASE: Cytoplasm becomes homogenous pink in HE staining. Increased eosinophilia.
Loss of RNA causes cytoplasmic basophilia.
Consolidation of cytoplasmic components on cell collapse.
Degradation of cytoplasmic proteins gives a ‘ghost like’ appearance to the cell.

Necrotic cells become INDIVIDUALISED- Lose adherence to basement membranes and adjacent cells- Are found free in tubules, alveoli, follicles and other lumens or surfaces.

-LATE PHASE- Cell rupture with loss of integrity and release of cell contents.

Question 2

Morphologic features of necrosis- NUCLEAR CHANGES

Answer 2

Pyknosis
Karyorrhexis
Karyolysis

Question 3

PYKNOSIS

Answer 3

Nucleus is shrunken, dark, homogeneous and round.

Question 4

KARYORRHEXIS

Answer 4

Nuclear membrane is ruptured, dark fragments of the nucleus are released in to the cytoplasm.

Question 5

KARYOLYSIS

Answer 5

The nuclear outline is extremely pale due to dissolution of the chromatin caused by the action of DNAases.

Question 6

ONCOTIC NECROSIS

Answer 6

Swelling/pressure necrosis. 5 types:

1. COAGULATION NECROSIS eg. Ischaemic or toxin induced necrosis in liver/heart/kidneys
2. CASEATION/CASEOUS NECROSIS- Associated with mycobacterial infections.
3. LIQUEFACTIVE NECROSIS eg. Ischaemic or toxin induced necrosis in CNS
4. GANGRENOUS NECROSIS- Gas/moist/dry gangrene caused by bacterial toxins, other toxic agents, ischaemia.
5. ENZYMATIC NECROSIS- Typically of adipose tissue by leakage of pancreatic enzymes (lipases) subsequent to exocrine acinar tissue injury.

Question 7

COAGULATION NECROSIS

Answer 7

Preservation of basic outline of necrotic cells.
Cytoplasm has homogenous eosinophilic appearance due to coagulation of cellular proteins.
Delayed proteolysis due to denaturing of structural proteins/enzymes.
Pyknotic/karyorrhectic/karyolytic/absent nucleus.
Occurs in any tissue, EXCEPT BRAIN PARENCHYMA.
Common in kidney, liver, muscle.

Commonly caused by loss of blood supply/hypoxia (leads to infarcts), bacterial toxins, chemical toxins.

Question 8

CASEATION/CASEOUS NECROSIS

Answer 8

Necrotic cells and tissues form granular, friable material. Necrotic focus (centre) is coagulum of nuclear and cytoplasmic debris. Surrounded by granulomatous inflammation. Mainly from dead leukocytes.
Typically seen in TB (M. bovis) and Corynebacterium pseudotuberculosis.
Seen throughout body.
Dystrophic calcification commonly occurs at later stages.
Often encapsulated.

“Compared with coagulation necrosis, caseation is an older (chronic) lesion often associated with poorly degradable lipid substances of bacterial origin”

Question 9

LIQUEFACTIVE NECROSIS

Answer 9

CENTRAL NERVOUS SYSTEM.
Initially individual neurones show coagulative necrosis, then a liquefactive process affects the neuroparenchyma- Enzymatic.
Hypoxia or toxin induced.
Due to little fibrous connective tissue in the CNS, there is no fibrotic reaction to replace lost/necrosed tissue.

The resulting cavity fills with fluid and neuronal lipid membrane debris.
Debris will be cleared up by macrophages (Gitter cells)

Can occur in tissues other than CNS- Abscess formation following destruction of pyogenic bacteria by neutrophils.
If dehydration occurs, pus inspissates, turning liquefaction in to caseation.

Question 10

Spinal Cord Compression

Answer 10

Can cause haemorrhage and necrosis. 
HISTOLOGICALLY- Malacia of white and grey matter. 
-Ischaemic neurons
-Necrosis
-Haemorrhage
-Oedema
-Liquefaction
-Pallor (rarefaction of neutrophil)

Question 11

GANGRENOUS NECROSIS

Answer 11

Starts as coagulation necrosis, which progresses with specific mechanisms and morphologic patterns.
Three types- Dry/Moist/Gas.

Question 12

ENZYMATIC NECROSIS

Answer 12

Seen in fact necrosis- SAPONIFICATION is caused by leakage of enzymes.
Appears as white spots of fat on surface of tissue.
eg.. Mesenteric fat necrosis.

Question 13

Fat necrosis

Answer 13

Enzymatic

Traumatic- Crushed fat eg. Pelvic fat in calf dystocia, sternal fat of recumbent animals.

Abdominal fat necrosis in cattle- Necrosis is seen in fat of mesentery, omentum and retroperitoneum.

Question 14

Diphtheritic membrane

Answer 14

Thick plaques of fibrinonecrotic exudate, seen for example in Infectious Bovine Rhinotracheitis.
Covers laryngeal and tracheal mucosae.
Produced due to secondary bacterial infection.

Question 15

Canine Parvovirus Enteritis

Answer 15

An important disease condition that is also characterised by necrosis.
MULTIFOCAL/SEGMENTAL NECROSIS seen in GI tract.
Flaccid, dilated, segmentally reddened intestine
Serositis
Fibrin deposits
Histologically- Hyperplastic crypt epithelial cells
Squamoid crypt epithelial cells
GALT responds to infection with CPV-2 virus.

CPV-2 INFECTION- Initial infection and multiplication in lymphoid tissues

• > viraemia
• > dissemination of virus to GI tract (+ other areas)
• > necrosis of crypt epithelial cells
• > crypt dilation
• > villus atrophy due to inability to replace enterocytes from crypts

Question 16

Canine Infectious Hepatitis

Answer 16

Caused by Canine Adenovirus 1 (CAV-1)
Enlarged, friable liver, fibrin tags often visible on capsular surface.
Thickened gall bladder wall due to oedema.
Serosa has granular appearance.
Histologically- Necrosis and loss of hepatocytes
- Large amphophilic/basophilic intranuclear inclusions visible in hepatocytes (may also be visible in endothelial cells)

Question 17

SEQUELAE TO ONCOTIC NECROSIS

Answer 17

Inflammatory reaction seen in viable tissue (band of white blood cells, hyperaemia)

Digestion and liquefaction of necrotic tissue. Macrophage phagocytosis, drainage/diffusion by blood or lymphatic vessels.
Regeneration of normal tissue or formation of fibrous scar tissue.

Question 18

APOPTOSIS

Answer 18

Programmed cell death.
Highly coordinated sequence of events.
Active process- Requires energy.

Can be PHYSIOLOGICAL or PATHOLOGICAL.
Irreversible.
Involves specific enzymes- CASPASES (Cys-Asp cleaving proteases) and NUCLEASES.