Centrifugation Methods & Techniques PDF

Summary

This document provides a comprehensive overview of centrifugation, including its principles, types, and applications in biological labs. It details various techniques like rate-zonal and isopycnic centrifugations, as well as diverse types of centrifuges.

Full Transcript

CENTRIFUGATION
 Contents:

Basic
principle

Operation Types

Application
 Definition:
 Biological centrifugation is a process that uses
centrifugal forces to separate and purify mixture of
biological particle in a liquid medium.

 It is key technique for isolating and analysing the cells,
subcellular fractions, supramolecule complexes and isolated
macromolecules such as proteins and nucleic acids.
 History:
 The first analytical ultracentrifuge was developed by
Svedberg in 1920
 Basic principle
The basic physics on which the centrifuge works is gravity
and generation of the centrifugal force to sediment
different fractions.
Rate of sedimentation depends on ------ applied
centrifugal field (G) being directed radially outwards
G depends on
1. Angular velocity (ω in radians / sec).
2. Radial distance (r in cms)of particle from axis of
rotation

G = ω2r
Rate of sedimentation
 Depends on factors other than CF
 Mass of particle ---Density & Volume
 Density of medium
 Shape of particle
 Friction
 Sedimentation time

 Depends on ,

1. Size of particle

2. Density difference b/w particle and medium

3. Radial distance from the axis of rotation to liquid meniscus
(rt)

4. Radial distance from the axis of rotation to the bottom of
the tube(rb)
THE FACTORS ON WHICH THESE WORKS ARE
More dense a biological structure, faster it sediments in centrifugal
force.

More massive biological particle, faster it moves in centrifugal field.

Dense the buffer system, slower particle moves.

Greater the frictional coefficient, slower a particle will move

Greater the centrifugal force, faster particle sediments

Sedimentation rate of a given particle will be zero when density of
particle and the surrounding medium are equal.
 Common feature of all centrifuges is the central
motor that spins a rotor containing the samples to
be separated.
 Types of centrifuge

Desk top High speed
Ultracentrifuges
centrifuges centrifuges

Analytical

Preparative
 Types of rotor

Fixed Vertical
angle tube
rotors rotors

Swinging-
bucket rotors
 Types of rotor

Fixed angle rotors Vertical tube rotors

 Tubes are held at angle of  Held vertical parallel to rotor
14 to 400 to the vertical. axis.
 Particles move radially  Particles move short
outwards, travel a short distance.
distance.  Time of separation is
 Useful for differential shorter.
centrifugation  Disadvantage: pellet may
 Reorientation of the tube fall back into solution at end
occurs during acceleration of centrifugation.
and deceleration of the
rotor.
 Types of rotor

Swinging-bucket rotors

 Sing out to horizontal position when
rotor accelerates.
 Longer distance of travel may allow
better separation, such as in
density gradient centrifugation.
 Easier to withdraw supernatant
without disturbing pellet.
 Normally used for density-gradient
centrifugation.
Separation
 Small microfuges

 work with speed- 8000-
13000 rpm & RCF
10000g
for rapid sedimentation
of small volumes (1-2
min)

Eg : Blood ,
Synaptosomes ( effect
of drugs on biogenic
 Desk top centrifuge
 Very simple and small.

 Maximum speed of 3000rpm
 Do not have any temperature
regulatory system.

 Used normally to collect rapidly
sedimenting substances such as
blood cells, yeast cells or bulky
precipitates of chemical reactions.
 High speed centrifuges
 Maximum speed of 25000rpm,
providing 90000g centrifugal forces.
 Equipped with refrigeration to
remove heat generated.
 Temperature maintained at 0-40C by
means of thermocouple.
 Used to collect microorganism, cell
debris, cells, large cellular
organelles, precipitates of chemical
reactions.
 Also useful in isolating the sub-
cellular organelles(nuclei,
mitochondria, lysosomes)
 Ultracentrifuges
 Operate at speed of 75,000rpm,
providing the centrifugal force of
500,000g.
 Rotor chamber is sealed and evacuated
by pump to attain vacuum.
 Refrigeration system (temp 0-40C).
 Rotor chamber is always enclosed in a
heavy armor plate.
 Centrifugation for isolation and
purification of components is known as
preparatory centrifugation, while that
carried out with a desire for
characterization is known as analytical
centrifugation.
 Preparative centrifugation
 Is concerned with the actual isolation of biological
material for subsequent biochemical investigations.
 Divided into two main techniques depending on
suspension medium in which separation occur.

Homogenous medium – differential centrifugation

Density gradient medium – density gradient
centrifugation
 1. Differential centrifugation
 Separation is achieved based in the size of particles in
differential centrifugation.

 Commonly used in simple pelleting and obtaining the partially
pure separation of subcellular organelles and
macromolecules.

 Used for study of subcellular organelle, tissues or cells (first

disrupted to study internal content)
 During centrifugation, larger
particles sediment faster than the
smaller ones.
 At a series of progressive higher
g-force generate partially purified
organelles.
 Inspite of its reduced yield differential centrifugation remains
probably the most commonly used method for isolation of
intracellular organelle from tissue homogenates because of
its;
relative ease
Convenience
Time economy

 Drawback is its poor yield and fact that preparation obtained
never pure.
2. Density gradient centrifugation
 It is the preferred method to purify subcellular organelles
and macromolecules.
 Density gradient can be generated by placing layer after
layer of gradient media such as sucrose in tube, with
heaviest layer at the bottom and lightest at the top in
either.
 Classified into two categories:

Rate-zonal Isopycnic
(size) (density)
separation separation
 Gradient material used are:
Sucrose (66%, 50C)
Silica sols
Glycerol
CsCl
Cs Acetate
Ficol (high molecular wgt sucrose polymer & epichlorhydrin)
Sorbitol
Polyvinylpyrrolidone
 2.1 Rate zonal centrifugation
 Gradient centrifugation.
 Take advantage of particle size and
mass instead of particle density for
sedimentation.
 Ex: for common application include
separation of cellular organelle such as
endosomes or proteins ( such as
antibodies)
 2.1 Rate zonal centrifugation
 Criteria for successful rate-zonal
centrifugation:
Density of sample solution must be less than
that of the lowest density portion of the
gradient.
Density of sample particle must be greater
than that of highest density portion of the
gradient.
Path length of gradient must be sufficient for
the separation to occur.
Time is important, if you perform too long
runs, particles may all pellet at the bottom of
the tube.
 2.2 Isopycnic centrifugation
 Particle of a particular density will sink during
centrifugation until a position is reaches where
the density of the surrounding solution is
exactly the same as the density of the particle.
‘

 Once quasi-equilibrium is reached, the length
of centrifugation doesnot have any influence
on the migration of particle.

 Ex: separation of Nucleic acid in CsCl
(Caseium chloride) gradient.
 Rate-Zonal Isopycnic

Synonym S-zonal, sedimentation velocity Density equilibrium, sedimentation
equilibrium

Gradient Shallow, Steep,
Maximum gradient density less Maximum gradient density greater
than the least dense sedimenting than that of the most dense
specie, sedimenting specie,

Gradient continuous. Continuous or discontinuous
gradients.
Centrifuga- Incomplete sedimentation, Complete sedimentation till
tion
Low speed, equilibrium is achieved,
Short time High speed,
Long time.
Separation RNA- DNA hybrids, ribosomal DNA, plasma lipoproteins,
subunits, etc., lysosomes, mitochondria,
peroxisomes, etc.,
 Operation
Tubes recommended by their manufacturer should be used.

Top of tube should not protrude so far above the bucket.

Properly balanced- weight of racks, tubes, and content on opposite side of a
rotor should not differ by more than 1%. (Centrifuges auto balance are
available).

Should centrifuge before unstopper the tubes.

Cleanliness –minimizing the possible of spread of infection (hep Virus).

Spillage and break of tube should be considered as the bloodborne

pathogen
hazard.

Speed of centrifuge should be checked once 3m.
 Application
 In clinical laboratory, centrifugation is used to;

Remove cellular elements from blood to provide cell free
plasma or serum for analysis.
Remove chemically precipitated protein from an analytical
specimen.
Separate protein bound from free ligand in immunochemical
and other assay.
Separation of the subcellular organelle, DNA, RNA.
Extract solutes in biological fluids from aqueous to organic
solvents.
Separate lipid components.
 Types of Centrifuges & applications

Types of centrifuge

Characteristic Low Speed High Speed Ultracentrifuge

Range of Speed (rpm) 1-6000 1000-25,000 20-80,000

Maximum RCF (g) 6000 50,000 6,00,000

Refrigeration some Yes Yes

Applications

Pelleting of cells Yes Yes Yes

Pelleting of nuclei Yes Yes Yes

Pelleting of organelles No Yes Yes

Pelleting of ribosomes No No Yes

Pelleting of Macromolecules No No Yes