Thursday, April 29, 2010

Micromeritics

Micromeritics is the study of finer particles which are smaller in size.

The merits and demerits of fine particles as dosage forms are given below:

Advantages of fine powder as dosage form:
1. Flexibility or activity:
In powder form, all quantity of a drug becomes active but in tablet or capsule form all quantity of drug is not active and small quantity is excreted out as inactive drug for example, in powder form if we take 100 mg drug then all of 100 mg will be active while in 500 mg tablet 350 or 400 mg drug will be activated and remaining will be excreted out.

2. Stability:
Some drugs are more stable in dry powder form and their activity is reduced in solution form.
Moreover, drugs in powder form are completely hydrolyzed where as in tablets form it may be possibility that no total drug is hydrolyzed.

3. Rapid therapeutic effect:
The effect of a tablet or capsule is given below:
If drug is already available in powder form then it is rapidly absorbed and show rapid therapeutic effect than tablets.

4. Ease of administration:
In powder form smaller surface area of drug particles can be easily administered  but in tablets form there is a difficulty to swallow it.

Disadvantages of fine powder as dosage form:
1. Prevention due to acidity:
Some drugs become inactive due to acidity in stomach pH.
So we take them in enteric coating to prevent from acidity instead of taking in powder form.

2. Efflorescent, Deliquescent and hygroscopic:
Some drugs become efflorescent, deliquescent or hygroscopic in nature and we can not use them in powder form, so we take them in tablets or in capsule forms for preventing them.

3. Bitter in taste:
Some drugs are bitter in taste and we take them in tablet or in capsule form instead of powder form.
Their bitter taste is masked by coating.
Comminution:
It is a process by which we can reduce the size of a substance.

There are various methods of size reduction.
1. Manual Size reduction
2. Mechanical size reduction

Manual size reduction:
It can be done by one of the following methods or their combination.

These are used mostly on small scale.

1. Cutting:
In this method, sharp blades or knives are used to cut a material into small particles.
This method is used for those materials which are elastic in nature.

2. Compression:
By applying pressure larger molecules can be broken down into smaller pieces.

3. Impaction:
In this method, large particles are broken by heavy mass.
If we hit large particle with heavy mass or hit heavy mass with stationary large particle, the large particle is broken into pieces.

4. Attrition:
In this method, large particles are crushed down into small pieces between two opposite moving surfaces.

5. Trituration:
Grinding of solid into powder is done by continuous stirring or rubbing the particle in mortar with pestle.
Trituration is also used for mixing of two or more substances.
Here different types of mortar and pestles can be used.

6. Levigation:
It is also called as wet grinding.
In this size of substance is reduced to finer state by triturating the substance with few drops of liquid in which it is insoluble.
Substances are used: oil, water, glycerine and alcohol.
This process is often used to incorporate the solid substances into dermatological and ophthalmic preparations.
After mixing, levigation continue for this purpose, mortar and pestle, spatula and glass slabs are used.
In this you will get fine paste.

7. Pulverization by intervention:
In this method, solid substance is reduced to a fine powder by means of triturating the solid with a suitable solvent which is easily removed at the end for example camphor is difficult to reduce in size because as it reduces in size. It cohere with each other but when few drops of alcohol, ether, chloroform, it can be powdered easily and these substances evaporate.

Mechanical method:
On large scale, size reduction is carried out mostly by using different kinds of mills which have capacity of producing powder of wide range of particle size. As different mills are used to reduce the particle size hence it is also known as milling.

Various mills are ball mill, hammer mill, colloidal mill etc.

Grading of powders:
1. Very coarse:
All particles pass through sieve number 8 and not more than 20% through sieve number 60.

2. Coarse:
All particles pass through sieve number 20 and not more than 40% through sieve number 60.

3. Moderately coarse:
All particles pass through sieve number 40 and not more than 40% pass through sieve number 80.

4. Fine:
All particles pass through sieve number 60 and not more than 40% through sieve number 80.

5. Very fine:
All particles pass through sieve number 80 and there is no limit for greater finest.

Methods used to determine the size:
The following methods are used to determine the size of particles and to separate them:

1. Seiving method:
This is the most common applicable method. By this method, we can get 50-5000micrometer.
In this method, different sieves are arranged together, when material is put over the sieves and sieves are shaken. We get finest powder at the last while the remaining material is present in above sieves which entrap them according to size of their holes. So in this way size of powder is determined.

2. By microscopy:
We can measure the size of particles of powder by microscope.
The particles whose size ranges from 1-25 micron can be measured under microscope.
When a prepared slide of material is examined under microscope then the microscope has a micrometer by which we can determine the size of particles.
The advantage of this method is that we can measure the size of particle directly.

3. Sedimentation method:
This method is based on sedimentation time i.e. How much time is taken to settle down the particles of powder from dispersion medium.
The apparatus used in this method is called as Andreasen apparatus.
The larger particles settle down rapidly while smaller particles take sometime to settle down.
So, larger sedimented particles are taken out by the tube from the bottom and remaining are the fine particles.

4. Elutriation method:
This method is used for the separation of different sized particles of the powder.

Importance of particle size in pharmacy:
1. Size reduction increases the surface area of drugs, which helps in solution formation and bioavailability increases.
2. Mixing is easier and uniform.
3. Rate of drying is enhanced, if particle size is reduced.
4. Stability of emulsion is increased by decreasing the size of globules.
5. Rate of absorption will be greater when the particle size is small.
6. In case of suspension, very small particles result in formation of cake and very large particles settles quickly but we should have to form loose cake because it redisperse upon shaking.
7. Physical appearance of ointments, paste and creams can be improved.
8. Stability of some drugs increase in powder form and decrease in solution form.
9. Powdered drugs are easily administered than solid dosage forms.

Multiple Choice  Questions (MCQs) from Micromeritics in Pharmaceutics
1. ……………..  Is the science and technology of small particles.

(a) Nanotechnology
 (b) Micromeritics
(c) Molecular Chemistry
(d) None of above
------------------
2. Increase the particle size increase will be,

(a)Absorption
(b) Distribution
(c) Both a and b
(d) None of above
-----------------
3. Particle size can be reduced by,

(a) Mortar and pestle
(b) Sieve
(c) Grinder
(d) Both a and c
---------------
4. Sedimentation rate can be decreased by …………. Particle size,

(a) Increase
(b) Decrease
(c) Unchanged
(d) None of above
-------------------
5. Which is smallest,

(a) Micrometer
(b) Millimeter
(c) Nanometer
(d) Catharometer
------------------
Answers to Multiple Choice  Questions (MCQs) from Micromeritics in Pharmaceutics

1. Micromeritics,

2. None of above,

3. Both a and c,

4. Decrease,

5. Nanometer
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Further Reading:
Micromeritics,: The technology of fine particles

Tutorial Pharmacy

Textbook of Pharmaceutics

Remington: The Science and Practice of Pharmacy (Remington the Science and Practice of Pharmacy)

British Pharmacopoeia 2010

USP NF 2009 (United States Pharmacopeia/National Formulary)

Effervescence

Multiple Choice Question (MCQs) from Efflorescence in Pharmaceutics
1. Loss of water (or a solvent) of crystallization from a hydrated or solvated salt to the atmosphere on exposure to air is called ………… .

(a) Efflorescence   
 (b) Hygroscopy
(c) Deliquescent
(d) Hydration
-------------------
2. After efflorescence color of NaCl becomes,

(a)  Blue                 
(b) White         
(c) Decolorization
(d) Orange
------------------
3. During efflorescence the water of crystallization ………… the substance,

(a)   Enters             
(b)   Leaves        
(c)   None of above
(d)   Both a and b
-----------------
4. After efflorescence the substance becomes,

(a)    Liquid              
(b)   Gas              
(c)   Solid              
(d)   None of above
---------------
5. Increasing the temperature of atmosphere will cause …………. in efflorescence,

(a)  Increase           
(b) Decrease       
(c) No change      
(d) Both a and b
----------------
Answers to Multiple Choice Question (MCQs) from Efflorescence in Pharmaceutics
1. Efflorescence,

2. White,

3. Leaves,

4. Solid,

5. Increase
-----------------
Further Reading:
Tutorial Pharmacy

Textbook of Pharmaceutics

BENTLEY'S TEXT-BOOK OF PHARMACEUTICS

Applied Pharmaceutics in Contemporary Compounding

Aulton's Pharmaceutics: The Design and Manufacture of Medicines

Remington's Pharmaceutical Sciences

Pharmaceutical Incompatibility (MCQs)

(For detailed study of Pharmaceutical Incompatibility Click here)

Multiple Choice Questions (MCQs) from Pharmaceutical Incompatibility in Dispensing
1. There are ………. Types of incompatibility.

(a)       1        
(b)       2        
(c)       3            
(d)       4
-------------
2. Liquification is the example of ………….. Incompatibility.

(a)    Immediate
(b)    Delayed
(c)    Instantaneous
(d) Both a and b
--------------------
3. Crystallization is an example of …………... Incompatibility.
 
(a)   Immediate
(b)   Delayed 
(c)   Instantaneous
(d)   Both a and b
------------------
4. Physical change may almost be ……….. .

(a)    Visible        
(b)    Invisible
(c)    Clear         
(d)    Turbid
---------------------
5. ……………. Compatibility may be corrected by changing the order of mixing.

(a)   Delayed       
(b)   Immediate
(c)   Tolerated    
(d)   Adjusted
--------------------
Answers to Multiple Choice Questions (MCQs) from Pharmaceutical Incompatibility in Dispensing 

1. Three,

2. Instantaneous/immediate,

3. Delayed,

4. Visible,

5. Tolerated.

(This blog is helpful for the preparation of pharmacy exams)

--------------------
Further Reading:
Cooper and Gunn's Dispensing for Pharmaceutical Students

Incompatibility in prescriptions and how to avoid it;: To which is added a dictionary of incompatibilities

Incompatibilities in prescriptions: For students in pharmacy and medicine and practicing pharmacists and physicians

Incompatibilities in prescriptions,: For students in pharmacy and medicine, practicing pharmacists and physicians,

Prescription writing: Including weights and measures, preparation of solutions, doses, administration and incompatibilities

Real numbers

These are numbers including integers and all the other numbers with values present between them such as 22/7, 2.5, square root of 5 etc.

Further Reading:
Cracking the GRE, 2010 Edition (Graduate School Test Preparation)

Kaplan GRE Exam Vocabulary in a Box

Barron's GRE

Essential Words for the GRE (Barron's Essential Words for the GRE)

Kaplan GRE Exam 2010-2011 Premier with CD-ROM (Kaplan GRE Premier Program (W/CD))

Fractions

When one integer is divided by another, it is fraction for example

3/5 or 4/10 and many more.

Here in these examples 3 and 4 are numerators and 5 and 10 are denominators.

Further Reading:
Cracking the GRE, 2010 Edition (Graduate School Test Preparation)

Kaplan GRE Exam Vocabulary in a Box

Barron's GRE

Essential Words for the GRE (Barron's Essential Words for the GRE)

Kaplan GRE Exam 2010-2011 Premier with CD-ROM (Kaplan GRE Premier Program (W/CD))

Factors and product

In the multiplication of two integers with each other these two integers are referred to as factors and the result of their multiplication is called as product.

For example in
5 x 2 = 10

5 and 2 are factors and 10 is product.

Further Reading:
Cracking the GRE, 2010 Edition (Graduate School Test Preparation)

Kaplan GRE Exam Vocabulary in a Box

Barron's GRE

Essential Words for the GRE (Barron's Essential Words for the GRE)

Kaplan GRE Exam 2010-2011 Premier with CD-ROM (Kaplan GRE Premier Program (W/CD))

Integers

Integers are all of the counting numbers. They are represented by "I" i.e.
....,-3,-2,-1,0,1,2,3.....

They may be positive or negative. Integers that are multiples of 3 are called as even numbers or integers. Moreover 0 is also called as an even number/integer e.g.....,-6,-4,-2,0,2,4,6,......

The numbers other than these are odd integers.

Remainder is that integer which remains at the end of division of one number by another.

(This article give some study about the numbers in GRE preparation)
Further Reading:
Cracking the GRE, 2010 Edition (Graduate School Test Preparation)

Kaplan GRE Exam Vocabulary in a Box

Barron's GRE

Essential Words for the GRE (Barron's Essential Words for the GRE)