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Cell Culture

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Title: Cell Culture


1
Cell Culture
Dr. Tarek Elbashiti Assoc. Prof. of Biotechnology
2
  • The term cell culture refers to the cultivation
    of dispersed (isolated) cells taken from an
    original tissue, a primary culture, or a cell
    line.
  • The practice of cultivating cells started at the
    beginning of the 20th century and was developed
    from a simple exploratory phase to an expansion
    phase in the 1950s.
  • For more than 50 years, the culture of cells
    derived from primary tissue explants has
    predominated, justifying the original name
    tissue culture.

3
  • Currently, cell culture is in a specialization
    phase. With the increase use of detached cells
    since the 1950s, the term tissue culture was
    substituted by cell culture.
  • At the present time, cell culture techniques
    allow in vitro propagation (proliferation) of
    various cell lines including those from insects,
    humans, mice, rats, and other mammals.

4
  • Basically, animal cell culture techniques are
    similar to those employed for bacteria, fungi,
    and yeast, although there are some characteristic
    differences.
  • In general, animal cells are more delicate,
    vulnerable to mechanical damage, present lower
    growth rates, and require more complex culture
    media and special substrates

5
  • cell culture has to be performed under rigorous
    aseptic conditions, since animal cells grow more
    slowly than most usual contaminants, such as
    bacteria and fungi.

6
HISTORICAL BACKGROUND
  • Tissue culture was first developed at the
    beginning of the twentieth century as a method
    for studying the behavior of animal cells free of
    systemic variations that might arise in vivo both
    during normal homeostasis and under the stress of
    an experiment.
  • The technique was elaborated first with
    un-disaggregated fragments of tissue, and growth
    was restricted to the migration of cells from the
    tissue fragment, with occasional mitoses in the
    outgrowth.

7
  • Roux in 1885 for the first time maintained
    embryonic chicken cells in saline).
  • Cell culture was first successfully undertaken by
    Ross Harrison in 1907( lymph)
  • 1911 Lewis made the first liquid media consisted
    of sea water, serum, embryo extract, salts and
    peptones. They observed limited monolayer growth.

8
  • 1913 Carrel introduced strict aseptic techniques
    so that cells could be cultured for long periods.
  • 1916 Rous and Jones introduced proteolytic
    enzyme trypsin for the subculture of adherent
    cells.
  • 1940s The use of the antibiotics penicillin and
    streptomycin in culture medium decreased the
    problem of contamination in cell culture.

9
  • Sanford was the first cloned cell strain,
    isolated by capillary cloning from mouse L-cells
    Sanford et al., 1948.
  • It was not until the 1950s that trypsin became
    more generally used for subculture, following
    procedures described by Dulbecco to obtain
    passaged monolayer cultures for viral plaque
    assays
  • Dulbecco, 1952, and the generation of a single
    cell suspension by trypsinization, which
    facilitated the further development of single
    cell cloning.

10
  • 1955 Gey established the first continuous human
    cell line, HeLa this was subsequently cloned by
    Puck, 1955
  • Tissue culture became more widely used at this
    time because of the introduction of antibiotics,
    which facilitated long-term cell line
    proliferation although many people were already
    warning against continuous use and the associated
    risk of harboring cryptic, or antibiotic-resistant
    , contaminations .

11
  • The 1950s were also the years of the development
    of defined media which led ultimately to the
    development of serum-free media 1966.

12
MAJOR
  • First was the use of chemically defined culture
    medium.
  • Second was the development was the use of
    antibiotics which inhibits the growth of
    contaminants.
  • Third was the use of trypsin to remove adherent
    cells to subculture further from the culture
    vessel

13
Advantages
  • Model systems for
  • Studying basic cell biology, interactions
    between disease causing agents and cells, effects
    of drugs on cells, process and triggering of
    aging nutritional studies
  • Toxicity testing
  • Study the effects of new drugs
  • Cancer research
  • Study the function of various chemicals,
    virus radiation to convert normal cultured
    cells to cancerous cells

14
Advantages
  • Virology
  • Cultivation of virus for vaccine production,
    also used to study there infectious cycle.
  • Genetic Engineering
  • Production of commercial proteins, large
    scale production of viruses for use in vaccine
    production e.g. polio, rabies, chicken pox,
    hepatitis B measles
  • Gene therapy
  • Cells having a functional gene can be
    replaced to cells which are having non-functional
    gene

15
Advantages
  • To produce artificial tissues ( skin)
  • Use single cell ( impossible in vivo)

16
Disadvantages
  • Cell characteristics can be changed
  • Cell adapts to different nutrients
  • If mixed cells cultivated some types will
    disappeared.
  • Activity of enzymes may altered by environment.

17
Typical structure of an animal cell
  • Various animal cell lines can be cultivated in
    vitro, such as cardiac cells, fibroblasts, smooth
    muscle cells, endocrine cells (such as pituitary,
    adrenal, and pancreatic cells), epithelial cells
    (such as liver, mammary, lung, and kidney cells),
    tumor cells (such as melanocytes), nervous system
    cells (such as glial cells and neurons), as well
    as hybridomas. Although these cells have
    different origins and functions, they all show a
    typical structure.

18
Animal tissue Cultures Classification
  • 1-classification a
  • A-Organ culture
  • B-Tissue culture
  • C-Cell culture

19
Types
20
A- Organ Culture
  • The term organ culture will always imply a
    three-dimensional culture of undisaggregated
    tissue retaining some or all of the histological
    features of the tissue in vivo.
  • The entire embryos or organs are excised from the
    body and cultured

21
  • Disadvantages
  • Scale-up is not recommended.
  • Growth is slow.
  • Fresh explanation is required for every
    experiment.

22
B-Tissue Culture
  • the term tissue culture is used as a general term
    to include organ culture and cell culture.
  • Fragments of excised tissue are grown in culture
    media
  • A fragment of tissue is placed at a glass (or
    plastic)liquid interface, where, after
    attachment, migration is promoted in the plane of
    the solid substrate

23
  • Advantages
  • Some normal functions may be maintained.
  • Better than organ culture for scale-up but not
    ideal.
  • Disadvantages
  • Original organization of tissue is lost.

24
C- Cell Culture
  • Cell culture refers to a culture derived from
    dispersed cells taken from original tissue, from
    a primary culture, or from a cell line or cell
    strain by enzymatic, mechanical, or chemical
    disaggregation into a cell suspension, which may
    then be cultured as an adherent monolayer on a
    solid substrate or as a suspension in the culture
    medium

25
  • Advantages
  • Development of a cell line over several
    generations
  • Scale-up is possible
  • Disadvantages
  • Cells may lose some differentiated
    characteristics.

26
classification b
  • Primary Cultures
  • Derived directly from excised tissue and cultured
    either as
  • Outgrowth of excised tissue in culture
  • Dissociation into single cells (by enzymatic
    digestion or mechanical dispersion)
  • Advantages
  • usually retain many of the differentiated
    characteristics of the cell in vivo
  • Disadvantages
  • initially heterogeneous but later become
    dominated by fibroblasts.
  • the preparation of primary cultures is labor
    intensive
  • can be maintained in vitro only for a limited
    period of time.

27
  • Continuous Cultures
  • derived from subculture (or passage, or transfer)
    of primary culture
  • Subculture the process of dispersion and
    re-culture the cells after they have increased to
    occupy all of the available substrate in the
    culture
  • can be serially propagated in culture for several
    passages
  • There are two types of continuous cultures
  • Cell lines
  • Continuous cell lines

28
  • Cell lines
  • finite life, senesce after approximately thirty
    cycles of division
  • usually diploid and maintain some degree of
    differentiation.

29
  • Continuous cell lines
  • can be propagated indefinitely
  • generally have this ability because they have
    been transformed
  • tumor cells.
  • viral oncogenes
  • chemical treatments.
  • the disadvantage of having retained very little
    of the original in vivo characteristics

30
Common cell lines
  • Human cell lines
  • -MCF-7 breast cancer
  • HL 60 Leukemia
  • HEK-293 Human embryonic kidney
  • HeLa Henrietta lacks
  • Primate cell lines
  • Vero African green monkey kidney
    epithelial cells
  • Cos-7 African green monkey kidney
    cells
  • And others such as CHO from hamster, sf9 sf21
    from insect cells

31
American Type Culture Collection.
32
3- Culture Morphology
  • Suspension (as single cells or small
    free-floating clumps)
  • or as a monolayer that is attached to the tissue
    culture flask.
  • The form taken by a cell line reflects the tissue
    from which it was derived
  • from blood tend to grow in suspension
  • from solid tissue (lungs, kidney) tend to grow as
    monolayer's.
  • Attached cell lines can be classified as
    endothelial, epithelial, neuronal or fibroblasts
    and their morphology reflect the area within the
    tissue of origin

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Anchorage dependent or independent
  • Cell lines derived from normal tissues are
    considered as anchorage-dependent grows only on a
    suitable substrate. ( Epith, CT)
  • Suspension cells are anchorage-independent e.g.
    blood cells

35
Adherent cells
  • Cells which are anchorage dependent
  • Add enough trypsin/EDTA to cover the monolayer
  • Incubate the plate at 37 C for 5 mts
  • Tap the vessel from the sides to dislodge the
    cells
  • Add complete medium to dissociate and dislodge
    the cells with the help of pipette which are
    remained to be adherent
  • Add complete medium depends on the subculture
    requirement either to 75 cm or 175 cm flask

36
Suspension cells
  • Easier to passage as no need to detach them
  • As the suspension cells reach to confluence
    aseptically remove 1/3rd of medium
  • Replace with the same amount of pre-warmed medium

37
Confluence
  • Once the available substrate surface is covered
    by cells growth slows ceases.

38
hep 3B - 70 confluency
39
100 confluence
40
After 24 h
41
Confluence
  • Cells to be kept in healthy in growing state
    have to be sub-cultured or passaged , when they
    reach 80-90 confluence in flask/dishes/plates
  • Enzyme such as trypsin, dipase, collagenase in
    combination with EDTA breaks the cellular glue
    that attached the cells to the surface

42
Design and Equipment for the Cell Culture
Laboratory
43
Design and Equipment for the Cell Culture
Laboratory
  • 1. Laboratory design- in a safe and efficient
    manner
  • 2. safety cabinets

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Laminar- flow hood
46
Laminar- flow hood
  • The working environment is protected from dust
    and contamination by a
  • Constant, stable flow of filtered air
  • Two types
  • Horizontal, airflow blow from the side facing
    you, parallel to the work surface, and is not
    circulating
  • Vertical, air blows down from the top of the
    cabinet onto the work surface and is drawn
    through the work surface and either re-circulated
    or vented.

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Laminar- flow hood
  • The efficiency of the hood depends on a minimum
    pressure drop across the filter
  • When the filter resistance builds up, the
    pressure drop increases and the flow rate of air
    falls.
  • Below 0.4 m/s (80 ft/min), the stability of the
    laminar airflow is lost, and sterility can no
    longer be maintained. The pressure drop can be
    monitored with a manometer fitted to the cabinet

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Laminar- flow hood
  • Routine maintenance checks of the primary filters
    are required (every 3-6 months).
  • They might be removed and discarded or washed
    in soap and water.
  • Every 6 months the main high efficiency
    particulate air (HEPA) filter above the work
    surface should be checked for airflow and hole

51
Before use
  • Ultraviolet lights are used to sterilize the air
    and exposed work surfaces in laminar flow
    cabinets between use.
  • Detergent
  • 70 alcohol

52
Cell Culture Incubator
53
  • It requires a controlled atmosphere with high
    humidity and super controlled of CO2 tension.
  • The incubator should be large enough, probably
    50-200 liter, have forced air circulation,
    temperature control and a safety thermostat that
    cuts out if the incubator overheats.

54
  • - It should be stainless steel, and easily
    cleaned.
  • A double cabinet, one above the other,
    independently regulated, is preferable to one
    large cabinet.
  • Incubators are supplied either with a heated
    water jacket as a method for distributing the
    heat evenly around the cabinet or with surface
    heater elements for heating.

55
Humid CO2 Incubator
  • CO2 incubators are more expensive, but the are
    ease of use and superior in the control of CO2
    tension and temperature
  • A controlled atmosphere is achieved by using a
    humidifying tray and controlling the CO2 tension
    with a CO2-monitoring device, which draws air
    from the incubator into a sample chamber,
    determines the concentration of CO2, and injects
    pure CO2 into the incubator to make up any
    deficiency.

56
  • Air is circulated around the incubator by natural
    convection or by using a fan to keep both the CO2
    level and the temperature uniform.
  • Dry, heated wall incubators also encourage less
    fungal contamination on the walls, as the walls
    tend to remain dry, even at high relative
    humidity.

57
Sterlization Heat
  • Moist heat denatures proteins by coagulation,
    caused by H bonds breakage, can happened more
    quickly in the presence of water
  • Autoclave Steam under pressure
  • Air should be Exhausted

Figure 7.2
58
  • Pasteurization reduces spoilage organisms and
    pathogens and can be safe if refregerated
  • Equivalent treatments as the temprature increase
    the time decreased and the same no of mo killed
  • 63C for 30 min
  • High-temperature short-time P 72C for 15 sec
  • Ultra-high-temperature P 140C for lt1 sec
  • Thermoduric organisms survive

59
Physical Methods of Microbial Control
  • Dry Heat Sterilization kills by oxidation effect
  • Flaming
  • Incineration
  • Hot-air sterilization temp 170C for 2 hrs

Hot-air Autoclave
Equivalent treatments 170C, 2 hr 121C, 15 min
60
Steam Sterilizer (Autoclave)
  • A simple bench-top autoclave that generates 100
    kPa (1 atm, 15 lb/in.2) may be sufficient, but a
    larger model with a timer and a choice of
    presterilization and poststerilization evacuation
    and temperature recording give more capacity and
    greater flexibility in use
  • and offers the opportunity to comply with good
    laboratory practice (GLP).

61
  • The chamber should also be evacuated after
    sterilization, to remove steam and promote
  • subsequent drying otherwise the articles will
    emerge wet, leaving a trace of contamination from
    the condensate on drying.
  • To minimize this risk when a postvac cycle is
  • not available, always use deionized or
    reverse-osmosis water to supply the autoclave.

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Cell culture contaminants
  • two types
  • 1- Chemicals-difficult to detect caused by
    endotoxins, plasticizers, metal ions or traces of
    disinfectants that are invisible
  • 2- Contamination by microorganisms remains a
    major problem in tissue culture.
  • Bacteria, mycoplasma, yeast, and fungal spores
    may be introduced via the operator, the
    atmosphere,work surfaces, solutions, and many
    other sources

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Contamination
  • They competes for nutrients with host cells
  • Secreted acidic or alkaline by-products ceases
    the growth of the host cells
  • Degraded arginine purine inhibits the synthesis
    of histone and nucleic acid
  • They also produces H2O2 which is directly toxic
    to cells

68
Safety
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  • For best results in tissue culture, we want to
    work to keep microbial (bacteria, yeast and
    molds) contamination to a minimum.
  • Guidelines to follow
  • Work in a culture hood set-aside for tissue
    culture purposes.
  • Most have filtered air that blows across the
    surface to keep microbes from settling in the
    hood.
  • Turn off the UV/antimicrobial light and turn on
    the hood 30 minutes prior to entering the hood.

71
  • Wear short sleeves or roll your sleeves up. Turn
    your baseball caps back if you MUST wear them,
    tie long hair back and remove rings and watches
  • Wash hands with soap and water before beginning
    the procedure and rewash if you touch anything
    that is not sterile or within the hood.

72
  • Spray down your hands, work surface, and anything
    that will go into the hood with 70 ethanol.
    Re-wipe at intervals if you are working for a
    long time in the hood. This will reduce the
    numbers of bacteria and mold considerably.
  • Do not breathe directly into your cultures,
    bottles of media, etc. This also means to keep
    talking to a minimum. No singing or chewing gum.

73
  • Work as quickly as you can within limits of your
    coordination. Also, keep bottles and flasks
    closed when you are not working with them. Avoid
    passing your arm or hand over an open bottle.
  • Use only sterilized pipettes, plates, flasks and
    bottles in the hood for procedures.

74
  • Take special precautions with the sterile
    pipette. Remove them from the package just before
    use. Make certain to set up the numbers on the
    pipette so that they face you.
  • Never mouth-pipette, use the pipetting aid.
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