How to examine cells and tissues

Question 1

4 types of tissue

Answer 1

• epithelial
• connective
• muscle
• nerve

Question 2

epithelial tissue

Answer 2

• e.g. skin
• edge of other tissues and surround other tissues
• clusters within tissues (glands)
• polarised at surfaces - apical and basal surface
• basement membrane (basal lamina + reticular layer) on basal surface
• held together by strong anchoring proteins
• communicate through junctions at lateral and basal surfaces

Question 3

connective tissue

Answer 3

• consist of cells + extracellular proteins/glycoproteins
• fibroblasts, chondrocytes, osteocytes, osteoblasts, osteoclasts, stem cells, progenitor cells, bone marrow, blood, adipocytes
• main products are fibres, groud substance and wax + gel-like materials

Question 4

muscle tissue

Answer 4

• consists of muscle cells (skeletal, smooth, cardiac)
• major function is to contract - movement, stability, movement of contents
• minor function is to secrete hormones - natriuretic factor, myostatin

Question 5

nerve tissue

Answer 5

• made of nerve cells and support cells
• nerve tissues can be short or very long
• main fast communication system in the body
• cells congregate into nerve fibres
• fibres congregate into nerves that can be dissected and visualised

Question 6

what is the standard measurement for a cell

Answer 6

micron (µm)

Question 7

what is used for sizing of a cell

Answer 7

measurement graticule

Question 8

what is the limit of resolution

Answer 8

the smallest distance by which two objects can be separated and still be distinguishable as two separate objects (proportional to wavelength of viewing system)

Question 9

relationship between milli-, micro- and nano- metres

Answer 9

1mm = 1000µm
1µm = 1000nm
1mm = 1000000nm

Question 10

methods of obtaining a biopsy

Answer 10

• surgery and dissection
• scraping methods (curettes, scalpel scrapes)
• sharp needles (needle biopsy, pipelle, trephine, punch biopsy)
• direct venepuncture (blood smears)
• transvascular (kidney, lung, brain, heart)

Question 11

what is fixation done for

Answer 11

• protect biopsy from damage as once removed from the body it no longer has the protection of body’s immune defence systems so can be digested by microbes or destroyed by decay
• removes water from sample so stiffens biopsy

Question 12

why does sample need to be thin (<20µm)

Answer 12

allow light to pass through it so diffraction doesn’t occur producing a blurry image

Question 13

what is the most common fixation chemical

Answer 13

fixative formalin
- 37% aqueous solution of formaldehyde
- 0.9% sodium chloride solution

Question 14

why is it important for formalin to be isotonic with intracellular fluid

Answer 14

• allow better penetration of formaldehyde
• reacts with amino groups of amino acids within proteins forming methylated bridges between protein chains
• preserves general structure of cells in tissue

Question 15

embedding choice for histological studies

Answer 15

paraffin wax

Question 16

embedding choice for electron microscopy

Answer 16

epoxy resins or plastics

Question 17

process of paraffin wax embedding

Answer 17

• washed and dehydrated in series of alcohol concentrations
• washed in solvents miscible with alcohol and wax (xylene or toluene)
• immersed in hot paraffin wax overnight
• placed in mould and more hot wax used to completely cover specimen
• allowed to solidify
• gently eased out of mould

Question 18

microtome process

Answer 18

• block of tissue mounted onto microtome
• thin sections cut using sharp steel blade, sharp edged glass or diamond knife
• fragile sections picked up with paintbrush and floated on warm water bath
• place glass microscope slide under floating section to adhere to specimen

Question 19

staining process

Answer 19

• dissolve paraffin (toluene or xylene)
• rehydrate with different alcohol concentrations
• stain sections (H&E)

Question 20

haematoxylin and eosin staining

Answer 20

• immerse section in solution of aqueous haematoxylin
• wash in water and transfer into alcohol
• immerse section in eosin
• wash with alcohol
• specimen mounted in non-aqueous mounting medium
• coverslip applied
• examine specimen once solvents evaporated

Question 21

haematoxylin

Answer 21

• basic dye so binds to acidic structures like DNA and RNA
• stains blue

Question 22

eosin

Answer 22

• acidic dye so binds to basic structures like intracellular and extracellular proteins (cytoplasm, collagen, elastic fibres)
• stains pink

Question 23

preparation for histology

Answer 23

• tissue procurement - biopsy
• fixation/frozen section
• embedding
• microtome
• staining
• examine

Question 24

Masson’s trichrome

Answer 24

• red = keratin and muscle fibres
• blue/green = collagen and bone
• light red/pink = cytoplasm
• brown + black = nuclei

Question 25

Periodic acid-schiff stain

Answer 25

identifies anything with a sugar attached - glycocalyx

Question 26

how can tissue processing lead to formation of shrinkage and other artefacts

Answer 26

leaving biopsy in fixative over 24-48 hours can cause dehydration and fixation artefacts

Question 27

mechanism of immunohistochemistry and immunofluorescence

Answer 27

both utilise labelled antibodies to localise specific cell and tissue targets

Question 28

immunofluorescence

Answer 28

• antibodies labelled with fluorescent dye bind to target antigens allowing structure to be visualised directly
• incident lighting often from UV light source

Question 29

indirect immunohistochemistry

Answer 29

• uses enzyme activated secondary antibody complexes that precipitate a coloured product at site of interaction
• primary antibody binds to target antigen
• secondary antibody with enzyme binds to primary antibody
• dye is added which is converted into coloured precipitate by enzyme
• enzymes routinely used are peroxidases which will produce brown precipitate at reaction site

Question 30

how is a frozen section prepared

Answer 30

• specimen on metal disc is frozen rapidly
• frozen specimen cut with microtome in cryostat in freezer
• stained with H&E

Question 31

paraffin wax formalin fixed VS frozen section

Answer 31

paraffin wax formalin fixed
- fixed tissue specimens
- 24-48 hours
- permanent saving time
- clarity in morphology under microscope
- used for pathological diagnosis

frozen section
- fresh tissue specimens
- 10-20 minutes
- months saving time
- opacity in morphology under microscope
- used for intraoperative consultation

Question 32

difference in tissue preparation for light vs electron microscopy

Answer 32

light microscope
- fix with formalin
- embed in paraffin wax
- stain e.g. H&E, methylene blue

electron microscope
- fix with glutaraldehyde
- embed in epoxy resin
- stain e.g. osmium tetroxide

Question 33

light vs electron microscope

Answer 33

light microscope
- natural coloured images
- large field of view ~2mm
- cheap and easy
- view living and moving objects
- magnification ~600x
- resolution ~0.25µm

electron microscope
- monochrome images
- limited field of view ~100µm
- difficult and expensive
- view dead and inert objects
- magnification ~500,000x
- resolution ~0.25nm

Question 34

scanning electron microscopy

Answer 34

• surface of cells coated with electron dense chemicals to reveal 3D aspect of cells and tissues
• good for examining surface of cells
• limit of resolution ~10nm

Question 35

transmission electron microscopy

Answer 35

• ultra thin sections of cells coated with electron dense chemicals to reveal 2D aspect of cell
• good for examining intracellular structures and organelles, especially membranes
• limit of resolution ~2nm

Question 36

why are electron microscopes capable of finer resolution than light microscopes

Answer 36

light microscope uses visible light whereas electron microscope uses electrons which has much smaller wavelength therefore much smaller limit of resolution

Question 37

advantage of phase contrast microscopy

Answer 37

living cells can be examined in their natural state without being killed, fixed, and stained

Question 38

advantage of confocal light microscopy

Answer 38

• control of depth-of-field
• collect serial optical sections from thick specimens
• create 3D images of the structures within cells

Question 39

advantage of dark field microscopy

Answer 39

high degree of contrast, making it easy to see samples on difficult backgrounds

Question 40

how does dark field work

Answer 40

illuminates the sample with light that will not be collected by objective lens so doesn’t form part of the image

Question 41

plasma membrane functions

Answer 41

• intercellular adhesion and recognition
• signal transduction
• compartmentalisation
• selective permeability
• transport of materials along and across cell surface
• endocytosis
• exocytosis

Question 42

nucleus

Answer 42

• contains DNA, nucleoproteins and RNA
• inactive cells have small nuclei with condensed heterochromatin
• actively transcribing cells have large nuclei with dispersed euchromatin
• no nuclei in terminally differentiated cells like erythrocytes, stratum corneum, lens fibre cells

Question 43

nucleolus

Answer 43

• sites of ribosomal RNA synthesis
• disappear during cell division

Question 44

nuclear envelope

Answer 44

• double layer of membranes bounding nucleus
• perinuclear cisternae between inner and outer nuclear membranes continuous with ER
• contains nuclear pores where macromolecules transported and micromolecules diffuse

Question 45

endoplasmic reticulum

Answer 45

interconnecting set of membranes, cisternae and vesicles
rough
- ribosomes attached to outer surface
- actively synthesing proteins that destined for cell exterior, lysosomes or cell membrane
- free ribosomes synthesise proteins for cytsol

smooth
- not associated with ribosome
- cisternae not flattened
- lipid biosynthesis and intracellular transport

Question 46

golgi apparatus

Answer 46

• saucer shaped stacks of cisternae
• sort, concentrate, package and modify proteins synthesised by RER
• vesicles from RER fuse with golgi body
• proteins migrate from convex to concave end of stack
• secretory vesicles condense together and release contents by exocytosis

Question 47

lysosomes

Answer 47

• contain acid hydrolases
• generated by golgi apparatus
• lysosomal membrane proteins are highly glycosylated for protection from these enzymes
• primary lysosomes phagosomes, endosomes, autophagosomes or excess secretory products to form secondary lysosomes where contents are degraded
• residual bodies = lysosomes which have digested their contents but contain indigestible remnants\
• primarily digest and re-use carbohydrates, lipids and peptides

Question 48

peroxisomes

Answer 48

• contain granular matrix
• self-replicating - obtain all materials from cytoplasm
• modify toxic molecules before they re-enter bloodstream
• kill bacteria
• major sites of oxygen utilisation and peroxide production
• catalase utilises H2O2 generated to oxidise other substrates

Question 49

mitochondria

Answer 49

• double membrane with inner membrane folded into cristae
• generation of energy rich ATP molecules by oxidative phosphorylation using glucose and fatty acids
• large numbers in liver and skeletal muscle
• matrix contains enzymes of Krebs and fatty acid cycles, DNA, RNA, ribosomes and calcium granules
• can divide because they have their own genetic information

Question 50

functions of cytoskeleton

Answer 50

• provide structural support for plasma membrane and cell organelles
• provide way of movement for organelles, plasma membrane and cytosol content around the cell
• provide locomotor mechanisms for amoeboid movements and cilia + flagella
• provides machinery for contractility in cells of specialised tissue like muscle

Question 51

microfilaments

Answer 51

• 5nm in diameter
• two strings of actin chains twisted together with ability to bind ATP
• contract and change shape of cell
• assemble and dissociate quickly

Question 52

intermediate filaments

Answer 52

• not dynamic
• 10-12nm in diameter
• common in nerve, neuroglial cells and epithelial cells (cytokeratin)
• form tough supporting network within cytoplasm
• anchored to plasma membrane by desmosomes
• hold cell together and prevent lysis

Question 53

microtubules

Answer 53

• thirteen α and β subunits polymerise to form wall
• originate from centrosome
• found where structures are moved e.g. mitotic spindle, cilia, flagella
• attachment proteins (dynein and kinesin) bind to organelles and move structures along microtubule
• highways within cell to move molecules and organelles to more distant parts of cell