TITLE :
EXAMINATION OF PHARMACEUTICAL FORMULATION USING LASER LIGHT SCATTERING METHOD PARTICLE SIZE ANALYSIS (METASIZER AND ZETASIZER)
EXAMINATION OF PHARMACEUTICAL FORMULATION USING LASER LIGHT SCATTERING METHOD PARTICLE SIZE ANALYSIS (METASIZER AND ZETASIZER)
OBJECTIVE :
1. To study how to use instruments to analyse particle size.
2. To determine particle size and size distribution of
different products using different methods of particle size analysis.
3. Analyse and interpret the data obtained.
4. Determine the best method to measure particle size for
each product.
INTRODUCTION :
To determine the size
distribution and particle size of small particles in suspension or polymers in
solution instrument that can be used is Zetasizer. Zetasizer instrument apply
Dynamic Light Scattering technique in order to determine particle size and size
distribution of nanoparticles, dissolve emulsion or suspension. Dynamic Light
Scattering technique apply for small size particles because small size
particles possess thermal motion known as Brownian motion. As these molecules
move around in the liquid, they are also bouncing off any suspended particles
in a random manner. When the laser beam shine the particles, the beam may
scattered in all direction results in scattering-angle-dependent intensity
pattern because the particles are experiencing Brownian motion. This make the
intensity pattern also fluctuates randomly. The rate of fluctuation depends on
the size of particles. Smaller size of particles, the higher rate of
fluctuation.
The Malvern Mastersizer uses the
technique of laser diffraction to measure the size of particles. It does this
by measuring the intensity of light scattered as a laser beam passes through a
dispersed particulate sample. This data is then analyzed to calculate the size
of the particles that created the scattering pattern. The principle used is
laser light scattering and the analysis is Mie and Fraunhofer scattering. A
typical system is made up of three main elements which are optical bench,
sample dispersion units and instrument software. Optical bench is a dispersed
sample passes though the measurement area of the optical bench, where a laser
beam illuminates the particles. A series of detectors then accurately measure
the intensity of light scattered by the particles within the sample over a wide
range of angles. Sample dispersion is controlled by a range of wet and dry
dispersion units. These ensure the particles are delivered to the measurement
area of the optical bench at the correct concentration and in a suitable,
stable state of dispersion. The Mastersizer software controls the system during
the measurement process and analyzes the scattering data to calculate a
particle size distribution. The usual particle size used is between 0.02 - 2000
µm. It has broad particle size range suitable for many different applications.
Besides that, it has wide range of sample dispersion options for emulsions,
suspensions and dry powders and fully automated simple SOP operation for ease
of use and method transfer.
MATERIALS :
Gaviscon Suspension (Sample B)
Cod Liver Oil emulsion (Sample C)
Polystyrene nanoparticles from Malvern, U.K. (Sample D)
Distilled water
Distilled water
PROCEDURES :
1. Malvern Zetasizer was powered up.
2. The software was launced up.
3. Cell was loaded and measurement was ran.
4. The resut was reviewed.
5. The cell was removed from the cell.
6. The cell was washed.
RESULTS :
1. Fill in the table below:
Result
for Metasizer:
No.
|
Particle size, µm
|
Size Distribution
|
||||
Cod Liver OilⓇ
|
GavisconⓇ
|
Polystyrene nanoparticles
|
Cod Liver OilⓇ
|
GavisconⓇ
|
Polystyrene nanoparticles
|
|
1.
|
36.797
|
21.997
|
0.444
|
0.537
|
||
2.
|
36.865
|
23.302
|
0.442
|
1.000
|
||
3.
|
39.919
|
0.000
|
0.678
|
0.000
|
||
Mean
±SD
|
37.774
± 1.459
|
22.650
± 0.653
|
0.523
± 0.111
|
0.769
± 0.232
|
||
Result for
Zetasizer:
No.
|
Particle size, µm
|
Size distribution
|
||||
Cod Liver Oil
|
Gaviscon
|
Polystyrene nanoparticles
|
Cod Liver Oil
|
Gaviscon
|
Polystyrene nanoparticles
|
|
1.
|
1.662
|
212.000
|
1.000
|
0.048
|
||
2.
|
1.559
|
212.900
|
0.400
|
0.021
|
||
3.
|
1.674
|
212.500
|
0.106
|
0.047
|
||
Mean
SD
|
1.632
0.052
|
212.470
0.368
|
0.502
0.372
|
0.039
1.563 X 10 -
4
|
||
2. Draw the shape of peak (s) obtained for each sample. Give your comments.
 |
| Gaviscon ( No. 1) |
 |
Gaviscon (No. 2)
|
 |
Cod liver oil (No. 1)
|
 |
| Cod liver oil (No. 2) |
 |
| Cod liver oil (No. 3) |
 |
Cod liver oil
(Average)
|
DISCUSSION :
1. Describe TWO (2) parameters which should be
provided when using Malvern Zetasizer® and Mastersizer®.
The
parameters that should be provided when using Malvern Zetasizer® and
Mastersizer® are time and temperature of
dispersant material. The time for the Malvern Mastersizer® is less 10 seconds
and its operating temperature (°C) is from 5°C to 40°C.While for the Malvern
Zetasizer®,the time is 2 minutes and the
operating temperature range (°C) is from
10°C – 35°C.
2.
Discuss the appropriateness of using the above
methods to analyse the samples.
By
using the above method to analyse the samples, the accurate, reliable and
repeatable particle size analysis can be determined. This can be proved by
Mastersizer 3000 which is the latest generation of the world’s most popular
particle sizing instrument that can deliver rapid, accurate particle size
distributions with minimum effort for
both wet and dry dispersions .It can measures over nanometer to millimeter
particle size ranges. It delivers class-leading particle sizing performance in
a compact footprint and bring the operator-independent measurements that every
user can rely on. For Malvern Zetasizer® , particles and molecules from less
than a nanometer in size to several microns can be analyzed by a range of
variants to suit your applications and budget. Next, the apparatus of above
method is easy to set up as it is fully automated measurement.
3.
Suggest another method to measure particle size,
if both methods are not suitable to analyse particle size any of the samples.
If
both methods are not suitable to analyse particle size any of the samples, the
other method that can be used to analyse the particle size is microscope method
which involve using of the polarized microscope .This method involve
observation of the material (Eg: Gaviscon suspension, Scott's emulsion cod
liver oil) under the bright light and polarized light. Detail
microscopic description under bright light and polarized light at 10x was
analysed for determination of particle size distribution.
4.
Explain
the principle of Malvern Mastersizer® and Zetasizer® operation on measurement
of particle size. (Please include the Frounhofer and Mie Theory).
Mastersizer uses
the technique of laser diffraction to measure particle sizes by measuring the intensity of light scattered
as a laser beam passes through a dispersed particulate sample. To calculate the
size of the particles that created the scattering pattern this data is then
analyzed.
Large
particles scatter light at small angles relative to the laser beam.
Meanwhile, small particles scatter light
at large angles. To calculate the size of the particles responsible for
creating the scattering pattern the angular scattering intensity data is then
analyzed. Laser diffraction uses Mie theory of light scattering to calculate
the particle size distribution, assuming a volume equivalent sphere model.
Mie
theory requires knowledge of the optical properties which are refractive index
and imaginary component of the sample being measured, along with the refractive
index of the dispersant. Optical properties of the dispersant are easy to find.
Mie theory completely solves the equations for interaction of light with matter.
This theory assumes the volume of the particles as opposes to Fraunhofer which
is a projected area prediction.
Fraunhofer
approximation is more simplified which does not require knowledge of the
optical properties of the sample. This can provide accurate results for large
particles. However it should be used with caution when working with samples
which might have particles below 50µm or particles are relatively transparent.
Zetasizer
uses two techniques in a single compact unit which are Dynamic Light Scattering
and Static Light Scattering and has a range of options and accessories to
optimize and simplify the measurement of different sample types.
Dynamic
Light Scattering is used to measure particle and molecule size. This technique
measures the diffusion of particles moving under Brownian motion, and converts
this to size and a size distribution using the Stokes-Einstein relationship.
Typical applications of dynamic light scattering are the characterization of
particles, emulsions or molecules, which have been dispersed or dissolved in a
liquid. The Brownian motion of particles or molecules in suspension causes
laser light to be scattered at different intensities.
Static
Light Scattering is used to determine the molecular weight of proteins and
polymers. In this technique, the scattering intensity of a number of
concentrations of the sample is measured and used to construct a Debye plot.
Thus, average molecular weight and second virial coefficient can be calculated.
This
measurement is very demanding on the stability of the whole system, and means
that every element of the design has been optimized to ensure accuracy and
repeatability.
5. Describe the advantages of using the above
methods in analysing particle size.
Advantages
of Laser light scattering method are it does not require calibration against a
standard. The sample also measured entirely. It is also simple and fast data
collection. It has very broad dynamic range(< 0.1 μm up to millimeter
sizes). It can also measure powders and fluid suspensions. Testing is
non-destructive. Thus, samples can be recovered if necessary. The method is
widely used and many people are familiar with the method.
Dynamic
light scattering technology from Malvern Instruments have the following
advantages. It is accurate, reliable and repeatable particle size analysis in
one or two minutes. The mean size only requires knowledge of the viscosity of
the liquid. It is simple in which no sample preparation required and high concentration and turbid samples can be
measured directly. The set up is simple and fully automated measurement. Size
measurement of sizes is less than 1nm. Furthermore, a minimum amount of
information about the sample is needed to run an analysis. Even mixtures of different
materials can be accurately measured. Except for the viscosity of the medium
must be known accurately. Besides, only a tiny sample is needed. The analysis
also fast and simple. Lastly, testing is non-destructive, so samples can be
recovered if needed.
CONCLUSION :
One
of the theory use in Mastersizer is the Fraunhofer model. This model can predict the
scattering pattern that is created when a solid, opaque disc of a known size is passed
through a laser beam. Other than that, the Mie theory was developed to predict
the way light is scattered by spherical particles and deals with the way light
passes through. This theory is more accurate but it require some specific
information about your particle such as its refractive index and its
absorption.
If
you know the size of the particle and other details about its structure, you
can accurately predict the way it will scatter light. Each size of particle
will have its own characteristic scattering pattern. The Mastersizer works
backwards from the above theories by using the Mastersizers’ optical unit to
capture the actual scattering pattern from a field of particles. Then using the
theories above it can predict the size of particles that created that pattern.
Zetasizer
provides the ability to measure three characteristics of particles or molecules
in a liquid medium which are particle size, zeta potential and molecular
weight. The Zetasizer system also enables determination of the protein melting
point and perform Trend measurements.
REFERENCES
:
1.http://www.malvern.com/en/products/technology/laser-diffraction/default.aspx
2.http://www.cpsinstruments.eu/pdf/Compare%20Sizing%20Methods.pdfhttp://www.cpsin
struments.eu/pdf/Compare%20Sizing%20Methods.pdf
3.http://www.ceic.unsw.edu.au/centers/partcat/facilities/Mastersizer.pdf
4.http://www.biophysics.bioc.cam.ac.uk/files/Zetasizer_Nano_user_manual_Man0317-1.1.pdf
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