FACULTY OF
PHRMACY
TECHNOLOGY
PHARMACEUTICAL II
NFNF 2263
LABORATORY
REPORT
PRACTICAL 4: SUPPOSITORY
GROUP B4
LECTURER'S NAME :
DR.
NG SHIOW FERN
GROUP MEMBERS:
3. MUHAMMAD
SHAHIR BIN ABU BAKAR A136436
4. AINAA
ZURIANI BINTI ABDUL AZIZ A136650
5. NOOR
FARAHIN BINTI ARIFFIN A136602
Title: Evaluation on the effect of
different formulation on the characteristic of suppository.
Objective: To study the effect of different composition of base on the physical
characteristic of suppositories.
Introduction:
Suppository is a solid formulation that has different size and
appearance and thus is suitable to be administered by rectal route. A good
suppository must be melt after being administered into the rectum and release
the drug content to achieve local or systemic effect. The drug must be spread
in a suitable base of suppository. A good base should be nontoxic, nonirritate,
no reaction with the drug and easily to be formed as a suppository. Different
composition of base will influence the rate and limit of drug release from the
suppository. In this experiment,
the effects of the different base composition to the suppository physical
characteristics and also to the drug release characteristics are evaluated.
Apparatus:
Analytical balance
Weighing boats
Spatula
50ml and 100ml beakers
Hotplate
5ml measuring cylinder
Suppository mould set
Water bath 37oC
Dialysis bag
Thread
Glass rod
5ml pipette and pipette bulb
Plastic cuvette
UV spectrophotometer
Materials:
Polyethylene glycol (PEG) 1000
Polyethylene glycol (PEG) 6000
Paracetamol
Distilled water
Liquid paraffin
Procedure:
- Paracetamol
saturated stock solution is prepared by adding 10g of Paracetamol in 5ml
distilled water.
- The
10g suppository is prepared using the formulation below:
|
Suppository
|
Group
|
PEG 1000
(g)
|
PEG 6000
(g)
|
Paracetamol stock solution (ml)
|
Total
(g)
|
|
I
|
1,5,9
|
9
|
0
|
1
|
10
|
|
II
|
2,6,10
|
6
|
3
|
1
|
10
|
|
III
|
3,7,11
|
3
|
6
|
1
|
10
|
|
IV
|
4,8
|
0
|
9
|
1
|
10
|
3. The suppository is
shaped using the suppository mould. The shape, texture and color of the
suppository is observed and discussed.
4. The suppository is
placed in the water bath 10ml at 37oC and the time for the
suppository to melt is recorded.
5. The suppository is
placed inside the dialysis bag and placed in the 50ml beaker. The beaker then
placed inside the water bath 37oC.
6. The sample is pipette in 5 minutes interval and the release of the
Paracetamol from the suppository is determined using the spectrometer UV/Vis.
The distilled water must be stirred first before the sample is taken.
Results and Discussions:
1. Compare
the physical appearance of suppositories that are formed and discuss.
|
Group
|
Paracetamol Stock Solution (ml)
|
Substance (g)
|
Physical appearances
|
|
PEG 1000
|
PEG 6000
|
Shape
|
Texture
|
Hardness
|
Colour
|
|
I
|
1
|
9
|
0
|
Bullet-shaped
|
Very greasy and least shining
|
Soft
|
Chalky white
|
|
II
|
1
|
6
|
3
|
Bullet-shaped
|
Greasy and slightly shining
|
Slightly hard
|
White
|
|
III
|
1
|
3
|
6
|
Bullet-shaped
|
Slightly greasy and shining
|
Hard
|
Colourless white
|
|
IV
|
1
|
0
|
9
|
Bullet-shaped
|
Least greasy and very shining
|
Very Hard
|
Colourless white
|
In this experiment, all
the suppositories formulated have the shape of a bullet or bullet-shaped since
the mould that is being used is of this shape. The quantities of PEG 1000 and
PEG 6000 are different for each group and this will lead to formation of
suppositories with different physical characteristics.
Based
on the observation that has been carried out, suppositories from Group 1 which
contain 9g of PEG 1000 and contain no PEG 6000 has the highest intensity of
white colour (chalky white) compared to the other groups. The intensity of
white colour is decreasing to nearly colourless from Group 2 to Group 4 due to the
presence of small amount of PEG 1000 and increasing amount of PEG 6000. Since the active
ingredient that is used in the experiment is paracetamol which is white in
colour, the colour of the suppositories produce will be white but differ in the
transparency degree. The formulation with the lowest amount of PEG 1000 is more
transparent compared to the others.
As for texture, suppositories
from Group 1 are very greasy but least shining compared to the other
suppositories. This is due to the presence of high amount of PEG 1000.
Suppositories from our group which is Group 4 are the least greasiness due to
presence of high amount of PEG 6000 and absence of PEG 1000. As for the
formulation with lowest amount of PEG 1000 and highest in the amount of PEG
6000 which is suppository from Group 4, the suppository formed is the hardest
of all. This is because the hardness of PEG increases with increasing molecular
weight. PEG 6000 has bigger molecular weight compared to PEG 1000. In other words, the higher the quantity of
PEG 6000 in a formulation, the less greasy the suppository will be. As for
hardness, we can conclude that the higher quantity of PEG 1000 (lower quantity
of PEG 6000), will produce softer suppository.
1. Plot a graph of the time needed
to melt the suppository vs. the amount of PEG 6000 in the formulation. Compare
and explain the results.
The time needed for the suppository to melt is 74.00
minute.
|
Amount
of PEG 6000
|
0
|
3
|
6
|
9
|
|
Groups
|
1
|
5
|
2
|
6
|
3
|
7
|
4
|
8
|
|
Time
(min)
|
61.82
|
71.45
|
33.72
|
36.47
|
39.21
|
37.14
|
74.00
|
53.34
|
|
Amount
of PEG 6000 (g)
|
0
|
3
|
6
|
9
|
|
Average of time (min) (¯x ± SD)
|
66.635± 4.815
|
35.095± 1.375
|
38.175± 1.035
|
63.67± 10.33
|
Based on the graph above, it can clearly seen that
the average time needed for the suppository to completely melt decreases
initially and increases with the increase of the amount of PEG 6000. The time
needed for the suppository with 0g of PEG 6000 to melt is supposed to be the
shortest. However, errors may have occured in the procedure of this experiment.
The increase of the time needed is due to the presence of hydroxyl(OH) group in
the suppository. The higher the amount of PEG 6000 used, the more the OH group
that will be present in the suppository. Therefore, there will be more hydroxyl
group forming hydrogen bond with paracetamol. With the increase in the
formation of hydrogen bond, the suppository formed will be harder and time
needed to completely melt the suppository will increase in water. This is
because time needed for the dissociation of the hydrogen bond is more difficult
with the increase in the formation of the hydrogen bond. From the graph, it can
be seen that the average time needed for the suppository with 9g PEG 6000
increases abruptly after the time needed for suppository with 6g PEG 6000 The
time taken for suppository containing 9g PEG 6000 to melt measured by both
Group 4 and Group 8 has a large difference.
The time taken for suppository to melt measured by Group 8 is shorter while
Group 4 is much more longer. They are not around the same range.
The inaccuracy of the result, that is the time
needed for suppository with 0g PEG 6000 and the large difference of time
measured for group 4 and group 8 can be due to the errors that occur in the
experiment. This might due to the inappropriate temperature where higher
temperature will increase the melting of the suppository, producing the shorter
time needed as measured in Group 8.
Besides, the accidental addition of water from the water bath into the
beaker containing suppository will also increase the dissolution of suppository
as more water to dissociate the hydrogen bond. A Noyes-Whitney equation of
dissolution can explain the theory behind where the additional water will
reduce the value of C, concentration of solid in bulk solution.
is the rate of dissolution.
A is the surface area of the solid.
C
is the concentration of the solid in the bulk dissolution medium.
Cs is the concentration of the solid in the diffusion layer surrounding the solid.
With
the decrease in the value of C, the value for (Cs - C) will be
larger. Hence, the rate of dissolution will be faster, time taken for the
suppository to melt will be shorter. Another error that might cause the
inaccuracy may be due to the stirring of water when the suppository is melting
by using glass rod. Hence, these errors has to avoided in order to improve the
accuracy of the experimental result.
|
Time
(minutes)
|
UV
Absorption
|
|
0
|
5
|
10
|
15
|
20
|
25
|
30
|
35
|
40
|
45
|
50
|
55
|
60
|
|
UV
Absorption at 520 nm
|
0.0
|
0.002
|
0.001
|
0.003
|
0.004
|
0.004
|
0.009
|
0.052
|
0.014
|
0.007
|
0.007
|
0.016
|
0.052
|
1.
Plot a graph of UV absorption against time and give
explanation.
The UV spectrometer measures the release of
paracetamol from the suppository in the dialysis bag to the distilled water.
The release of the drugs from the suppository involved the diffusion mechanism.
The water is set to 37 0C to mimic the temperature of human body as
suppository will be applied in the human body. Meanwhile, the dialysis bag
represents the skin membrane.
The graph above shows the relationship between the
UV absorption against time for paracetamol suppository. Based on the graph, it
shows slowly increasing in the absorption of UV. The increasing flow continue
until minutes 38 where there is a sudden decrease in the absorption.
Supposingly, the UV absorption of the suppository increases when the time
increases, which means that the longer the time, the higher the amount of drugs
passing through the membrane or the higher the bioavailability is.
Theoretically, the acceleration of UV absorption at the first 5 minutes is
caused by greater hypertonicity of the content in dialysis bag compared to the
surrounding distilled water.
As the experiment proceeds, the content in the
dialysis bag becomes closer to isotonicity to the distilled water as some of
the paracetamol has been moved to the distilled water. This will result in the
reduced gradient of the graph when time passes by. If the experiment is
continued beyond 60 minutes, it may result in a straight line graph as the
concentration of paracetamol in the distilled water equals to the concentration
of paracetamol at the dialysis bag.
Polyethylene
Glycol Polymers have received much attention as suppository bases in recent
years because they possess many desirable properties. They are chemically
stable, nonirritating, miscible with water and mucous secretions, and can be
formulated, either by molding or compression, in a wide range of hardness and
melting point. Like glycerinated gelatin, they do not melt at body temperature,
but dissolve to provide a more prolonged release than theobroma oil.
In this experiment, some of the precaution steps
must be taken during conducting the experiment. The rope should tie both end of
the dialysis bag tightly to prevent leakage of the suppository that has
miscible with water. We must also stir the distilled water before sample is
taken out for measurements to ensure uniform distribution of the released
active ingredient. Besides, the smooth surface of the cuvette should not face
the source of UV light and the smooth surface should be cleaned before it is
placed into the device.
1.
Plot a graph of UV absorption vs. time for other suppositories that have
different formulation. Compare and discuss the results.
|
Time (min)
|
Average of the UV absorption at 520nm (x ± SD)
|
|
0
|
5
|
10
|
15
|
20
|
25
|
|
Suppository
|
I
|
0.0040 ±
0.0014
|
0.0155±
0.0106
|
0.0265±
0.0134
|
0.0325±
0.0092
|
0.0410±
0.0127
|
0.0460±
0.0127
|
|
II
|
0.0120±
0.0113
|
0.0310±
0.0127
|
0.0345±
0.0035
|
0.0390±
0.0226
|
0.0475±
0.0106
|
0.0455±
0.0247
|
|
III
|
0.0230±
0.0084
|
0.0395±
0.0212
|
0.0530±
0.0396
|
0.0645±
0.0502
|
0.0705±
0.0530
|
0.0755±
0.0559
|
|
IV
|
0.0035±
0.0050
|
0.0220±
0.0283
|
0.0080±
0.0099
|
0.0110±
0.0113
|
0.0110±
0.0099
|
0.0115±
0.0106
|
|
Time
(min)
|
Average
of the UV absorption at 520nm (x ±
SD)
|
|
30
|
35
|
40
|
45
|
50
|
55
|
60
|
|
Suppository
|
I
|
0.0555±
0.0205
|
0.0555±
0.0106
|
0.0605±
0.0162
|
0.0720±
0.0311
|
0.0880±
0.0467
|
0.1005±
0.0431
|
0.1925±
0.0516
|
|
II
|
0.0595±
0.0205
|
0.0750±
0.0141
|
0.0655±
0.0191
|
0.1135±
0.0473
|
0.0850±
0.0156
|
0.0925±
0.0233
|
0.0900±
0.0297
|
|
III
|
0.0845±
0.0693
|
0.0940±
0.0693
|
0.1115±
0.0742
|
0.1290±
0.0707
|
0.1335±
0.0742
|
0.1305±
0.0629
|
0.1915±
0.1435
|
|
IV
|
0.0175±
0.0120
|
0.0405±
0.0162
|
0.0325±
0.0261
|
0.0275±
0.0290
|
0.0385±
0.0445
|
0.0475±
0.0445
|
0.0660±
0.0198
|
Based on the graph plotted, it can be seen that
suppository I has the highest UV absorption. This means that the amount of
paracetamol present in the solution is the highest. This may be caused by the
presence amount of hydroxyl group is higher in PEG 1000 compared to PEG 6000.
Higher number of hydroxyl group in PEG result in more availability of it to
react with water and thus make it more miscible with water and higher
percentage content of paracetamol to diffuse out of the dialysis bag. Amount of
PEG 1000 used in suppository will affect the distribution of hydrophilic and
hydrophobic phase. Paracetamol is a hydrophilic drug depend on the amount of
PEG 1000 been used in this experiment. So, when the dialysis bag is immersed in
the water, water diffuses into the dialysis bag via osmosis. This causes the
paracetamol to dissolve in the presence of water. Due to the miscibility of
water and PEG base, the dissolved paracetamol will diffuse out of the dialysis
bag into the water medium. This causes the UV absorption measured to be the
greatest.
On the other hand, suppository IV has the slowest
rate of drug released which accounts for its lowest UV absorption in this
experiment. This is because of the high amount of PEG 6000 which contain less
amount of hydroxyl group in its structure make it immiscible with water.
Therefore the amount of paracetamol to diffuse out of the dialysis bag is
smaller and resulted in the less present of paracetamol in the water bath when
reading is taken. Besides, PEG 6000 has the characteristic of higher viscosity
make it less available to miscible with water. This causes the drug to be
difficult to diffuse out into the water. As increased of PEG molecular weight
resulted in decreased solubility in water and solvent. From the graph, we can
see that there is repeated in decrease of the UV absorption reading when at a
certain time the reading is increased.
This resulted in undesired reading of UV absorption. This may be due to
errors while conducting the experiment. Some of it might be uneven stirring of
the solution in the beaker before the solution is taken to be filled in the
cuvette. Thus amount of paracetamol that has diffuse out into the water medium
is uneven distributed.
Suppository III is the second
lowest UV absorption value while suppository II has the second highest UV
absorption value. This result can be said accurate as the PEG 1000 used for
suppository II and III are 16g and 3g respectively. The UV absorption value of
suppository II is higher than suppository III. Therefore, the
UV absorption value of suppository II is definitely higher than suppository III, which is shown
in the graph. Proper ratio of the two bases will enable optimum and constant
release of drug into the environment. When water diffused in, PEG 1000 will
miscible with water evenly where the drug can dissolves in water. Therefore,
constant rate of release of drug can be achieved.
There are several precaution steps that must be
taken when using the UV spectrophotometer. Firstly, don't touch the optical
surface of cuvettes with fingers to avoid erratic reading. Then, do not
overfill or under fill the cuvette, the cuvette should be three-fourth full.
Besides, preserve the instrument from dust particles. Moreover, never wash the
cuvettes with chromic acid. Wash the cuvette with the distilled water and then
with methanol before storage.
