PHARMACEUTICAL
PRODUCT DEVELOPMENT
NFNF2213
SEMESTER 1
SESSION
2016/2017
LAB
REPORT 1
LECTURER
: DR. HALIZA KATAS
GROUP
MEMBERS :
NISHAAL
KORAN (A153334)
TAN
MIN ANNE (A152663)
MUHAMMAD
ROSMAN BIN JUNAIDI (A153262)
MUHAMAD
HAZWAN BIN HARUN (A152983)
LEOW
PUI MUN (A152593)
Introduction :
The word ‘suspension’ implies a two-phase system which
consist of a finely divided solid dispersed in a liquid. Suspensions are
heterogeneous systems made up of at least two phases. The continuous or external
phase is generally a liquid or a semi-solid, and the dispersed or internal
phase is made up of particulate matter which is essentially insoluble in, but
dispersed throughout the continuous phase. Suspensions are often prepared for
oral administration as sweetened and as non-sweetened for many parenteral
routes of administration.
Suspensions have their advantages over other dosage
forms. Drugs in suspension are chemically more stable than in solution.
However, suspensions possess certain disadvantages as well such as physical
instability. Physical instability whereby they tend to settle over time causing
lack of uniformity of dose. This can be reduced by precise formulation and by
shaking the suspension before each dose is administered. In short, trying to
eliminate separation is not the best option but to minimize the rate of
settling and to allow re-suspension. One of the strategy is to use wetting
agent like tragacanth to reduce surface tension.
Objective :
The objective of the investigation is to study the
effect of different amount of tragacanth on the sedimentation rates of
suspensions.
Materials :
Chalk
Tragacanth
Concentrated
peppermint water
Double
strength chloroform water
Distilled
water
Syrup
BP
Apparatus :
1
ml graduated pipette
Pipette
bulb
Weighing
boat
Set
of mortar and pestle
200
ml graduated cylinder
100
ml beaker
Parafilm
Weighing
balance
Viscometer
Plastic
bottle
Dropper
Methodology :
1. A suspension of
Pediatric Chalk Mixture (150ml) is prepared according to the following formula
:
Ingredient
|
Suspension
|
|||
A
|
B
|
C
|
E
|
|
Chalk (g)
|
||||
Tragacanth (g)
|
||||
Concentrated
peppermint water (ml)
|
||||
Syrup BP (ml)
|
||||
Double Strength
Chloroform water (ml)
|
||||
Distilled water
q.s. (ml)
|
||||
2. 5 ml of the suspension
of each formulation is poured into a weighing boat and labelled. Each
suspension is observed and compared based on the texture, clarity and colour.
3. The sedimentation rate
of each suspension is determined. The suspension is shaken vigorously to make
sure all the particles are uniformly suspended and the time is noted. The
boundary between the sediment and the supernatant is observed and the time
taken for the boundary to pass each 10 ml graduation until the volume of
sediment reaches 80 ml is recorded.
4. The graduated cylinder
is set down on the lab bench, and the lab timer is started at this point.
5. The sedimentation
volume of the suspensions A to C is recorded at t = 0, 2, 5, 10, 15, and 30
min.
6. The data obtained is
recorded in the following table :
Suspension
|
Sedimentation
volume at pre-determined time (min)
|
Distinct
boundary (yes/no)
|
|||||
0
|
2
|
5
|
10
|
15
|
30
|
||
A
|
|||||||
B
|
|||||||
C
|
|||||||
E
|
|||||||
7. The sedimentation volume
ratio is calculated using the following formula :
Sedimentation volume ratio = Hu/Ho
Hu
: ultimate height of the sediment
Ho : initial height of the total suspension
8. The ease of re-dispersibility of each formulation
is examined after the last measurement. This is done :
i) The
Parafil is snugged on the mouth of the graduated cylinder and the seal is
re-enforced with our hand.
ii) The
number of inversions it takes to completely re-disperse the drug is counted.
iii) The
observation is recorded.
9. 95 ml of suspension is poured into a 100 ml beaker
and the viscosity of the the suspension is determined using viscometer at 100
rpm for 30 seconds.
10. The data is recorded in the following table :
Suspension
|
A
|
B
|
C
|
E
|
Viscosity(cP)
|
||||
Mean
|
||||
SD
|
11. Each suspension is poured into a plastic bottle.
All the suspension is stored for 4 days then, the ease of redispersion in each
system is determined as well as the most acceptable system.
Results :
Suspension
|
Sedimentation
volume at pre-determined time (mL)
|
Distinct
Boundary
|
|||||
0
|
2
|
5
|
10
|
15
|
30
|
||
A
|
0
|
0
|
30
|
20
|
18
|
18
|
Yes
|
B
|
0
|
0
|
0
|
15
|
20
|
18
|
No
|
C
|
0
|
0
|
0
|
2
|
18
|
20
|
No
|
E
|
0
|
0
|
0
|
0
|
0
|
0
|
No
|
Discussion :
1. 1.Compare and discuss the
physical appearances of all the suspensions produced.
Suspension
|
Amount
of tragacanth(g)
|
Texture
|
Clarity
and Appearance
|
Colour
|
A
|
0.0
|
Water-like, least viscous, fastest to
sediment
|
Least cloudy, 2 distinct layer after
sedimentation
|
Less milky
|
B
|
0.1
|
Viscous, slower to sediment
|
Cloudy
|
Milky white
|
C
|
0.3
|
More viscous, slowest to sediment
|
Cloudy
|
Milky white
|
E
|
0.5
|
Most viscous, no sedimentation
|
Opaque
|
Yellowish-white
|
Based on the observation, we can see that
suspension A has the least viscosity. Suspension C is more viscous than suspension
B. However, suspension E is the most viscous.
In suspension A, the wetting agent tragacanth powder is not
present , causing the suspension to sediment very quickly as well as behave as
water-like and can flow freely. Therefore, it has the least viscosity. Suspension
B is less viscous then suspension C as it has lesser wetting agent tracaganth
powder. Therefore, the chalk will sediment quickly in suspension B compare to
suspension C. Suspension E serves as a control as it does not contain any
chalk. The amount of wetting agent will influence the sedimentation rate as
wetting agent lowers the surface tension and the contact angle of chalk and
liquid particles.
2. 2.Plot Hu/ Ho vs time for each suspensions. (Table
1) Discuss the findings .
Sedimentation volume ratio = Hu/Ho
Hu:
ultimate height of the sediment, i.e., the height of the sediment at a
particular time
Ho: initial height of the total suspension
Hu/Ho value of Suspension
|
0
|
2
|
5
|
10
|
15
|
30
|
A
|
0
|
0
|
0.2
|
0.13
|
0.12
|
0.12
|
B
|
0
|
0
|
0
|
0.1
|
0.13
|
0.12
|
C
|
0
|
0
|
0
|
0.01
|
0.12
|
0.13
|
E
|
0
|
0
|
0
|
0
|
0
|
0
|
Based on the graph constructed,
suspension A which does not contain tragacanth wetting agent shows a high
sedimentation volume ratio. At the first 5 minutes, the sedimentation height
increases dramatically. However, the value drops to 0.13 and remained constant
after that. At the beginning, the chalk particles sediment very quickly due to
the absence of tragacanth wetting agent, thus proving the sedimentation ratio
at the first 5 minutes. Later on, the sedimentation ratio decreases until a
constant value because the chalk particles compressed each other, flocculation
occurred, which causes the sedimentation value to decrease.
For suspension B and C which contain
the tragacanth wetting agent , the sedimentation ratio is lower than A .
Tragacanth helped to lower the interfacial tension and contact angle between
chalk particle and liquid particles. The ratio will remain constant after a
certain time because the sedimentation volume had reach the limit. Suspension B
has a higher sedimentation ratio because it has lesser tragacanth wetting
agent, thus allowing chalk powder to sediment more quickly.
3.
Briefly explain the principle of analysis using viscometer. Plot the viscosity
vs tragacanth content. Discuss the findings.
Suspension
|
A
|
B
|
C
|
E
|
||||||||
Viscosity (cP)
|
1.38
|
1.62
|
0.87
|
1.86
|
2.28
|
2.04
|
2.76
|
2.16
|
2.40
|
0.54
|
0.48
|
0.57
|
Mean
|
1.29
|
2.06
|
2.44
|
0.53
|
||||||||
Standard Deviation
|
0.31
|
0.17
|
0.25
|
0.04
|
Amount of tragacanth (g)
|
0
|
0.1
|
0.3
|
0.5
|
Viscosity (cP)
|
1.29 ± 0.31
|
2.06 ± 0.17
|
2.44 ± 0.25
|
0.53 ± 0.04
|
There are
many ways to measure viscocity of liquid. One of the way is by using
viscometer. In this experiment, the viscocity of the suspension is measured by
using rotational viscometer. The rotational viscometer basically consists of
two parts which is a head unit with a motor and a spindle that is driven by the
motor. The viscosity is determined by measuring the resistance of a spindle
rotating in the sample. When immersed in a sample fluid, the rotational
viscometer senses torque (twisting force) required to rotate a spindle at
constant speed to calculate the viscosity of the fluid. The measured torque is
proportional to the dynamic viscosity. The torque required to maintain constant
rotational rate while overcoming viscous resistance and it is correlated with
viscosity. Thus, it can be said that the dynamic viscosity is proportional to
the measured torque. The continuous changes in magnetic field cause the rotor
magnet to spin. There are different types of the spindle that are used in the
rotational viscometer. For us, we are using the thinner spindle as we are
measured the suspension in the small beaker.
In the making of suspension, we must put a suspending
agent. This experiment we are using tragacanth as a suspending agent. The
function of suspending agent is to
help the suspending medium to support the insoluble solid and thus decrease the
rate of sedimentation. It will suspend the chalk in the external phase.
We are using 4 formulations in this experiment
which is sample A, B, C and E. All the formulations contain different amount of
tragacanth in gram. Theoretically, the more amount of tragacanth used, the more
viscocity of the suspension. Tragacanth will lower the interfacial tension and thus,
increase the viscosity of the suspension
From the
graph plotted based on the result obtained from the experiment, we can see that
the viscocity of the suspension increases gradually with the increase amount of
the tragacanth and suddenly the viscocity is drop at the end. This is because for
the sample E, there is no active ingredient which is chalk. Eventhough the
amount of tragacanth is higher in the sample E, it cannot make the suspension
become viscous as there is no activity of lowering interfacial tension of chalk
by tragacanth. Sample C with 0.3 g of Tragacanth is
the most viscous suspension in this experiment with an average viscosity of
2.44 cP. The least viscous suspension among the sample that have active
ingredient is Sample A which has 0.1 g of Tragacanth record an average
viscosity of 1.29 cP. Sample E is the least among others with an average
viscocity of 0.53 cP.
4. After storing the suspensions for a period of 4 days, determine the ease
of redispersion of each.
After
we stored the suspensions for 4 days, the ease of redispersion of each
suspensions are as follows :
Suspension
|
Ease of redispersion of each
suspensions
|
A
|
Normal
|
B
|
Easy
|
C
|
Very Easy
|
E
|
Difficult
|
5. Based on all the observations, which products would be considered to be
most acceptable? Explain.
Based on all the observations, we found
that the most acceptable product are product of Sample C. This is because Sample
C have the precise amount of Tragacanth powder in the suspension. The
suspension with too many Tragacanth are too viscous and have smooth texture
while suspension with no or too small amount of Tragacanth(sample A and B) have
less smooth texture with intermediate of redispersion rate of the suspension if
we compare to sample C.
As
the amount of Tragacanth used increase, the suspension will become more viscous
and stable against coagulation. Tragacanth
may increase the viscosity of the aqueous vehicle and thus slow the rate of
sedimentation of the particles but they will also form adsorbed layers around
the particle so that the approach of their surfaces and aggregation to the
coagulated state is hindered. Viscosity are important for acceptable suspension but the
suspension must be in the normal viscocity in which the viscocity of the
suspension is not too high and not too low. When the suspension is too viscous
it will cause difficulty in administration of product by patient.
Ease of redispersion of the sediments in the
suspension are vital for uniformity of dose. It is to prevent from the
suspension having inaccurate dosing
which can be overdose or underdose. By having a good suspension which is
readily to be redispersed, the accurate dose most probably can be achieved. From
all the sample, Sample C is the sample that can easily redisperse. Tragacanth
will support the insoluble solid in the
suspending medium for a longer time to prevent it from forming hard cake that
is difficult to be redispersed. Flocculation
is the way to prevent formation of hard cake. Tragacanth also can bother the sedimentation
rate of suspension. When the amount of
tragacanth powder increase, sedimentation rate will occur more slowly and thus
sediment height will be lower.
6. Briefly explain the function of each excipients used in the suspension
formulation. Explain the influence of tragacanth on the physical
characteristics and stability of a suspension.
Excipient
|
Function
|
Tragacanth
|
Wetting
agent, to increase the viscosity of solution, to slow down sedimentation of
particles in suspension
|
Concentrated
Peppermint Water
|
Acts
as flavouring agent
|
Syrup
|
Acts
as flavouring agent
|
Double
Strength Chlorofoam Water
|
Acts
as preservative agent to reduce microbial growth in the suspension
|
Distilled
Water
|
Acts
as a solvent
|
Chalk powder is an active ingredient
in the suspension. The general use of chalk powder is to treat diarrhea as it
adsorb excess fluid in the faeces.
Tragacanth powder acts
as wetting agent so that the stability and uniformity of a solution is ensured
whereby there are no two distinct layers of ingredients present in the
suspension. Therefore, the amount of tragancath will determine the viscosity of
solution, texture and appearance. When the tragacanth is present in the
solution, the solution looks more cloudy and smooth. However, the amount of
tragacanth in the suspension must be not be too much. The more the amount of tragacanth
used, the slower the sedimentation occur. If the viscosity of suspension is too
high, it might results in caking and difficult to pour which will be
inconvenient for the patient.
Conclusion :
Conclusion :
The rate of sedimentation and height of sediment formed in the suspension depend on the different amount of Tragacanth powder used during the formation of suspension. The higher the amount of Tragacanth powder, the lower the height of sediment formed. This happens due to the action of Tragacanth powder that prevent the solution from forming sediment.
