Limit test for Arsenic

Official compounds

It constitute an important section of pharmacopoeia which gives all necessary information of drugs and compounds that are official. The information includes the title, subtitle, molecular formula, molecular weight , test for identification , tests for purity , description and solubility , method of assay , category and dose it applicable

Assay

The quantitative estimation of the amount of drug present in a given sample constitutes as assay. The percentage purity of the sample is determine by caring out its assay

Limit test

These are qualitative or semi- quantitative test designed to detect and limit small quantities of impurities that are commonly present in pharmaceutical substance. They are based on the comparison or opalescence, turbid ty or colour produced due to impurity in asample with that produced in a standard under t he same test conditions

Ex

Limi t test for CCl, SO4, Fe2 , Heavy metals, lead and arsenic 

Limit test for arsenic

The limit test for arsenic is provided to demonstrate that the content of arsenic does not exceed the limit given in the individual monograph in terms of micrograms of arsenic per gram of the test substance.

To carry out the limit test for arsenic a solution is prepared from the test substance by a procedure specified in the monograph.

This procedure assures that the solution in every case contains the whole of the arsenic (if any) present in the substance.

The standard stain against which the comparison is made contains 10 μg of As.

The procedure described may also be used to determine the amount of arsenic in the substance by matching the depth of color of the stain with a series of standard stains.

In the statements of arsenic limits, the permitted amount of arsenic is expressed as As.

Limit test for Arsenic

Principle

The principle is based on converting any arsenic impurity present in the sample to arsine gas by a series of reaction. The arsine gas is made to come in contact with mercuric chloride test paper when by it produces a yellow or brown s train due to the formation of mercuric arsenic

The stain produce by the sample is compare to a standard stain produced by standard strain

The sample stain should not be darker than standard stain

Reactions

1. The arsenic impurity is converted in acidic medium into arsenious acid or arsenic acid depending upon the valency state of arsenic

As 3+  --------------------------   As (OH)3  or H3 AsO3

Trivalent                                    Arsenious acid

As 5+  --------------------------   O  = As (OH)3  or H3 AsO4

Pentavalent                                    Arsenic acid

2. Any arsenic acid formed is converted int arsenious acid by reduction with stannous chloride and hydro chloric acid

                           Stanous chloride

H3 ASO4    ------------------------------------  H3ASO3

3. The arsenic acid is further reduced to arsine gas with the help of nacent hydrogen obtained in the reaction between zinc and hydrochloride acid

                                 Reduction

H3ASO3 +6H  ---------------------------------------- ASH3  +3H2O

4. Arsenic gas react with mercuric choride test paper to produce yellow to brown stain due to formation  of mercuric arsenide

2ASH3 + HGCl2   -----------------------------------   Hg (As H2)2   + 2HCl 

Apparatus

It consist of  which mouthed bottle of 120ml capacity fitted with a rubber bung.

Through the rubber bung insert a glass tube as a internal diameter of 6.0 mm and external diameter of 8.0 mm

It has a total length of 200 mm , is drawn out at one end to a diameter of about 1 mm, and has a hole not less than 2 mm in diameter blown in the side of the tube, near the constricted part.

The mercuric chloride test paper is placed between the bund and clipped together with a clip

Procedure

The glass tube is packed with lead acetate cotton

Sample Stain

The solution of the sample is placed in the wide mouthed bottle.

10 ml stagnated HCl ,  and 10 grms of zinc is added to the sample solution.

The reaction is allowed to proceed for 40 minutes at the temperature of 40c

Standard stains

Solutions are prepared by adding to 50 ml of water, 10 ml of stannated hydrochloride acid AsT and quantities of dilute arsenics solution AsT varying 0.2 ml to 1 ml. The resulting solutions , when treated as described in the general test yield stains on the mercuric chloride paper referred to as the standard stains

Stannated hydrochloride acid AsT

Stannous chloride solution AsT     -      1ml

Hydrochloric acid AsT                  -       100 ml

Comparison and results

The intensity of sample stain is immediately compared to the that of the standard stain. For the sample to pass the limit test for arsenic , the intensity of sample stain should not be greater than of the standard stain 

Basis of test

Both in the sample and the the standard is done by the combined action of Zinc, acid , stannous chloride and potassium iodide.

The pharmacopoeial test  of arsenic which is a toxic component in medicinal substances is based on the fact that arsenic in the arsenious state can be readily reduced to arsine (As H3) gas which passing over mercuric chloride paper develops a yellow to brown stain

The intensity and length of which are proportional to the amount of arsenic

The solution is reacted with a reducing agent like stannous chloride or sulphurous acid to convert the penta valent arsenic acid into the trivalent arsenious acid which is converted into gaseous arseniou  hydride (arsine gas) with the help of nascent hydrogen produced by the action of zinc with hydrochloric acid

HCl

Arsenic  to arsenious or arsenic acid in presence of acidic media

Stannous chloride

This solution is reacted with a reducing agent like stannous chloride to convert the pentavalent arsenic acid into the trivalent arsenious acid

Zinc with hydrochloric acid

Nascent hydrogen produced by the action of zinc with hydrochloric acid

Trivalent arsenious acid which is converted into gaseous arsenious hydride (arsine gas) with the help of nascent hydrogen produced by the action of zinc with hydrochloric acid

                         Sn Cl2                           Zn + HCl   

H3 AsO4   -------------------  H3 AsO3 -----------------  AsH3   +  3H2O

Arsenic acid                     Arsenious acid                     Arsine gas

Arsine gas is carried out through the tube with the help of hydrogen to the mercuric chloride paper

The reaction of arsine with mercuric chloride produces a yellow colored stain

The intensity of the color is dependent on the quantity of arsenic

2AsH3  + HgCl2 ------------------------  Hg (AsH2)2   +2HCl

                                                             Yellow stain 

The most suitable temperature for carrying out the test is generally abou 40c

The tube must be washed with HCl , rinsed with water and dried between successive tests

The stains may be preserved by dipping in hot melted paraffin or placing over phosphorus pentoxide protected from light

Stannous chloride is required for the complete evolution fo arsine

The acion between pure zinc and hydrochloric acid is slow and he presence of other metals accelerates the formation of hydrogen . Stannous salts reduce arsenic to arsenious state

Hydrogen sulphide

Metallic zinc may contain traces of sulphiide which on  reaction with the acid yields hydrogen sulphide

The lead acetate papers are used to trap any hydrogen sulphide evolved together with arsine.

The hydrogen sulphide reacts with mercuric chloride paper developing a dark stain , thus interfering with the formation of the required mercuric arsenide stain

Apparatus  

A suitable type of apparatus is described below, though other acceptable constructions are available.

A wide-mouthed bottle of about 120 ml capacity, is fitted with a rubber bung through which passes a glass tube.

The tube is passed through the bung fitting the bottle so that, when inserted in the bottle containing 70 ml of liquid, the constricted end of the tube is above the surface of the liquid and the hole in the side is below the bottom of the bung.

The upper end of the tube is cut off square, and is either slightly rounded off or ground smooth.

Two rubber bungs (about 25 mm × 25 mm), each with a hole bored centrally and true and exactly 6.5 mm in diameter, are fitted with a rubber band or spring clip for holding them tightly together.

Alternatively, the two bungs may be replaced by any suitable construction satisfying the conditions of the test, as described below.

Recommended procedure

Pack the glass tube lightly with cotton-wool, previously moistened with lead acetate (80 g/l) TS and dried, so that the upper surface of the cotton-wool is not less than 25 mm below the top of the tube.

Insert the upper end of the tube into the narrow end of one of the pair of rubber bungs, either (1) to a depth of about 10 mm in the case of the tube with the rounded-off end or (2) so that the ground end of the tube is flush with the larger end of the bung. Place a piece of mercuric bromide paper AsR flat on the top of the bung, and place the other bung over it. Secure the assembly by means of a rubber band or spring clip, in such a manner that the borings of the two bungs (or the boring of the upper bung and the glass tube) meet to form a true tube 6.5 mm in diameter interrupted by a diaphragm of mercuric bromide paper AsR.

Instead of this method of attaching the mercuric bromide paper AsR, any other method may be used provided (1) that the whole of the evolved gas passes through the paper, (2) that the portion of the paper in contact with the gas is a circle 6.5 mm in diameter, and (3) that the paper is protected from sunlight during the test.

Place the solution, prepared as specified in the monograph, in the wide-mouthed bottle, add 1 g of potassium iodide AsR and 10 g of granulated zinc AsR, and place the prepared glass tube assembly quickly into position. Allow the reaction to proceed for 40 minutes. Compare any yellow stain that is produced on the mercuric bromide paper AsR, with a standard stain, produced in a similar manner with a known quantity of dilute arsenic AsTS. Make the comparison in daylight and immediately after simultaneous preparation of the test and standard stains; the stains fade on keeping.

The most suitable temperature for carrying out the test is generally about 40°C The temperature may be adjusted to obtain a regular

The reaction may be accelerated by placing the apparatus on a warm surface, care being taken to ensure that the mercuric bromide paper AsR remains quite dry throughout the test.

Between successive tests, the tube must be washed with hydrochloric acid (~250 g/l) AsTS, rinsed with water, and dried.

cardiac cycle

Cardiac cycle

Def

It is the sequence of events during a cardiac beat

Various changes that follow during a heart beat, undergo cyclic repetition

One complete cycle of such cardiac events of a beat is the cardiac cycle

Duration

72times/m

One beat takes 0.8s

If the heart beats faster, the time is less than 0.8sec

If the slower it would be little more

Events

Both atria and ventricles undergo systolic and diastolic phase with every beat

There is a an atreal systole and an atreal diastole, ventricular systole and ventricular diastole

Atrial events

These include atrial systole and atrial diastole .Atrial systole occurs for 0.1 s

Atrial systole is followed by 0.7sec of aerial diastole

During atrial systole the atria contract pouring their blood into their respective ventricles

During atrial diastole ,  the atria relax and the blood from superior and inferior vena cava in the right atrium and the pulmonary veins in the left atrium, fill them  up. After this they again contract to perform atrial systole

Ventricular events

As the atrial systole ends, the ventricular systole begins

This continues for 0.3 sec and is followed by ventricular diastole

Isometric ventricular contraction period

As ventricular systole starts, the atrioventricular valves (AV valves) of both ventricles close. This produces the first heart sound. At this time semi lunar (SL) valves are closed

In the beginning of ventricular systole there are closed cavities and ventricular pressure is mounting up without any decrease in its volume

In isometric contraction period, its onset is marked by closure of AV valves and termination by opening of SL valves. This period remains for 0.05 sec

Intraventricular pressure is highest during this period

Rapid and slow ejection period

After 0.05 sec isometric contraction periods, semi lunar valves open and due to ventricular systole, blood is ejected out into respective arteries

This is period , ejection period (0.15 sec)

The intraventricular pressure starts rising

The intrventricular volume step-down and blood is poured out with maximum force

In the late part of ventricular systole  , intravintricular pressure declines and blood is poured with slow speed. This is called slow ejection period (0.1 scc)

Pro- diastolic and isometric relaxation period

The aorta and pulmonary trunk recoil and blood tries to rush back into the respective ventricles

But this is suddenly stopped by the swift closure of semi lunar valves

This produces the second heart sound, heralding the end of ventricular systole

The ventricular between the start of ventricular diastole and the closure fo SL valves (0,04 sec)  is known is know as prodiastilic period

The next to this period is isometric relaxation period (0.08 sec)

This is the period during which both the valves (AV and SL)  are closed but ventricles and atria are in diastolic condition

This is the period when intra-ventricular pressure is minimum and heart is relaxing

Rapid and slow inflow period

The isometric relaxation period ends with the opening of AV valve and because ventricles are under diastolic condition , rapid inflow of blood starts

This is known as rapid inflow period

Third heart sound is heard on echophine at this juncture and it lasts for 0,03 sec

The next phase is slow inflow period (9.2 sec) and is also known as diastalsis

When ventricular diastole is about to end, the atrial systole has started and it overlaps for 0.1 sec

During this phase because of active contraction of atria, filling of ventricles start rapidly

This is called rapid filling period and fourth heart sound is heard at this stage on echo phone

ECG Changes

The events of cardiac cycle can be traced on ECG

During atrial systole P wave is seen

QRS seen in the beginning of ventricular systole

The last T wave can be seen in the beginning of ventricular diastole

Heart sound records (Phonocardiogram/ echo-cardiograph or echocardiograph

The heart sound can be recorded using suitable equipment phonocardiograph

The first heart sound is recorded on the closure of A-V valves

Second heart sound can be recorded at the time to the closure of semi lunar valves

Two small sounds are recorded during the sudden rush of blood into the ventricles

 

COCONUT OIL SHAMPOO

Aim:  To prepare and submit 25ml of coconut oil shampoo.

Chemical requirements :  Coconut oil, potassium hydroxide, boric acid, purified water.

Apparatus:  water bath, beaker, mortar and pestle etc.

Procedure:  

1.       Heat the coconut oil about 85⁰c.

2.       Dissolve potassium hydroxide in 5ml of hot water.

3.       The hot water solution is added to hot oil with vigorous shaking until a complete emulsion is produced and heat the mixture until it becomes homogenous.

4.       Add sufficient water to produce required volume.

5.       Set aside the preparation for 24hrs at 15⁰c and filter.

6.       Finally add Boric acid till pH of sample is 3.3 using phenopthalein as indicator.

7.       Store  the preparation in a container and label it.

Report:  25ml of coconutoil shapoo was prepared and submitted .

Formula :

S.NO	INGREDIENTS	WORKING FORMULAE
1.	Coconut oil	10ml
2.	Pottasium hydroxide	5mg
3.	Boric acid	q.s
4.	Purified water	Upto 25ml

PREPARATION OF VANISHING CREAM

Aim:  To prepare and submit 25gm of vanishing cream.

Chemical requirements :  Stearic acid, Potassium carbonate, borax, carbitol, Perfume and water.

Apparatus:  water bath, beaker,china dish etc.

Principle              : 

                                Vanishing cream is a particlar type of skin cream used during the day time, either alone in which it is expected to immiscible or vanish on application, or in conjunction with powder when it must serve as a foundation for the makeup providing suitable adherent base for the powder.

                                These creams are water continuous cream with low or medium oil content. Most of the formulations contain high quantity of stearic acid as the oil phase. This provides an oil phase which melts above body temperature and crystallizes in a suitable form, so as to be immiscible and gives nongreasy film, and moreover can confirm a very attractive appearance to the product.

                                These creams can be defined as stearic acid in a gel of stearate soap.

Procedure           :  

1.       Stearic acid is melted in waterbath at 70⁰C.

2.       Potassium carbonate dissolved in water and borax is added to it then mix it thoroughly. This solution is heated to 70⁰C.

3.       Then the solution is poured into melted stearic acid with stirring at same temperature for 10 mins until the saponification is completed.

4.       China dish is removed from the flame and stirred until it is cold.

5.       Perfume is dissolved in carbitol which is added to the cream and mixed thoroughly

Report                  :  25 of vanishing cream was prepared and submitted .

Formula              :

S.NO	INGREDIENTS	WORKING FORMULAE
1.	Stearic acid	4.5gm
2.	Pottasium  carbonate	0.2gm
3.	Borax	0.05gm
4.	Carbitol	1.25gm
5.	Perfume	q.s
6.	Purified water	Upto 25ml