Bioassay Is Assessment of a Biological Substance. Bioassay Or Biological Standardization

Bioassay is Assessment of a biological substance. Bioassay or biological standardization is a type of scientific experiment typically conducted to measure the effects of a substance on a living organism and is essential in the development of new drugs and in monitoring environmental pollutants. Both are procedures by which the potency or the nature of a substance is estimated by studying its effects on living matter. Bioassay is a procedure for the determination of the concentration of a particular constitution of a mixture.

Bioassays are procedures that can determine the concentration of purity or biological activity of a substance such as vitamin, hormone, and plant growth factor. While measuring the effect on an organism, tissue cells, enzymes or the receptor is preparing to be compared to a standard preparation. Bioassays can be classified in two types:

·  Qualitative

·  Quantitative

Qualitative bioassay is used for assessing the physical effects of a substance that may not be quantified, such as abnormal development or deformity. Example of a qualitative bioassay includes Arnold Adolph Berthold's famous experiment on castrated chickens. This analysis found that by removing the testes of a chicken, it would not develop into a rooster because the endocrine signals necessary for this process were not available.

Quantitative bioassays involve estimation of concentration/potency of a substance by measurement of the biological response it produces. These bioassays are typically analyzed using the methods of biostatistics.

Principles of bioassay

•  Bioassay involves the comparison of the main pharmacological response of the unknown preparation with that of the standard.

•  The reference standard and test sample should have same pharmacological effect and mode of action, so that their DRC curve run parallel and their potency ratio can be calculated.

•  The test solution and standard should be compared for their established pharmacological effect using a specified pharmacological technique.

•  The method selected should be reliable, sensitive, and reproducible and should minimize errors due to biological variation and methodology. (Animals should of same species, sex and weight and number of animals should be large enough to permit statistical analysis.

Need of Bioassay

1.  They not only help to determine the concentration but also the potency of the sample. Potency denotes activity of the compound i.e. if a compound shows better activity at minute concentration, greater is the potency, and if its activity is low at lower concentrations, lesser is the potency.

2.  It is used to standardize drugs, vaccines, toxins/ poisons, disinfectants, antiseptics etc. as these are all used over biological system in some form.

3.  These also help determine the specificity of a compound to be used ex: Penicillin's are effective against Gram+ve but not on Gram-ve. Testing of infected patient’s sputum helps determine which anti-biotic be given for quick recovery.

4.  Certain complex compounds like Vitamin B-12 which can't be analyzed by simple assay techniques can be effectively estimated by Bioassays.

5.  Sometimes the chemical composition of samples is different but has same biological activity.

6.  For samples where no other methods of assays are available.

Procedure

i.  Prepare the physiological salt solution

ii.  Arrange the instrument and adjust the water bath.

iii.  Balance the lever

iv.  Tissue selection

v.  Surgical process and collection of required tissue.

vi.  Tissue attachment to the water bath

vii.  Relaxation time given to the tissue

viii.  Prepare the standard drug( serial dilution)

ix.  Select the lowest possible measurable concentration by trial and error method.

x.  Prepare DRC for the standard drug.

xi.  Prepare DRC for the test drug.( serial dilution)

xii.  Select a assay method (3 point or 4 point assay)

xiii.  Calculation

1.  Prepare the physiological salt solution

reagent / Frog-Ringer / Kreb’s / Tyrode / Ringer-Locke / De Jalon / Mc Ewen
NaCl / 65 g / 69 g / 80 g / 91.5 g / 90 g / 76 g
KCl / 1.4 g / 3.5 g / 2.0 g / 4.2 g / 4.2 g / 4.2 g
MgCl². 6H²O / --- / 1.1 g / 1.0 g / --- / --- / ---
NaH2PO4. H²O / 0.1 g / 1.4 g / 0.5 g / --- / --- / 1.4 g
NaHCO³ / 2 g / 21 g / 10 g / 1.5 g / 5 g / 21 g
CaCl² / 1.2 g / 2.8 g / 2 g / 2.4 g / 0.6 g / 2.4 g
Glucose / 20 g. / 20 g. / 10 g. / 10 g. / 5 g. / 20 g
Aerating Gas / air / O² + 5%CO² / O² or air / Pure O² / O² +
5% CO² / O² + 5% CO²
Frog-Ringer / Amphibian tissue preparation
Kreb’s / Mammalian/Avian skeletal muscle preparation
Tyrode / Intestine preparation
Ringer-Locke / Heart muscle preparation
De Jalon / Rat uterus preparation

2.  Arrange the instrument and adjust the water bath.

§  Student Organ bath

o  Outer bath:-

§  First designed by rudolph magnus

§  Perplex glass

§  Store water outside the inner bath to maintain the temperature

o  Inner bath:-

§  Glass

§  To observe the tissue during experiment

§  5-50ml (usually 10ml)

Kymograph: Sherrington- starling kymograph

•  To obtain a graphical amplified measurable response of a muscle or tissue

•  Two important parts: motor box and drum

•  Speed lever: 1 revolution/ 96 min.

•  Paper: glossy side outside – least resistance

Rough side inside – stick to the drum.

•  Fixing solution: shellac and colophony saturated in alcohol

3.  Surgical process and collection of required tissue

Ø  Animal sacrificed by cervical dislocation.

Ø  Tissue identified and isolated.

Ø  Carefully dissect and separate unwanted tissue.

Ø  Tissue kept in a physiological salt solution.

Ø  Avoid excessive handling of tissue.

4.  Tissue attachment to the water bath

Attach the ends of the tissue: - One end to tissue holder other end to lever

Method of attachment of tissue: Attach the thread at the end by a needle. Care should be taken for intestine tissue not to block the lumen.

5.  Prepare DRC for the standard and test drug

two std doses s1& s2 from linear part of DRC [Let the corresponding response be S1, S2] Also s2/s1 = t2/t1 = 3/2

Types of Bioassays

Basically there are two types of bioassays as per the technique used in determination of the Sample under test.

1.  Graded Response Assay

2.  End Point or Quantal Assay

Graded Response Assay: In these assays, as the dose increases there are an equivalent rise in response. The potency is estimated by comparing the Test sample responses with the standard response curve. In the graded dose response relationship, relates the size of the response to the drug in a single biologic unit as the dose administered increased the pharmacological response also increases and eventually reaches a steady level called the ceiling effect there will be on further increase in response even with an increase in dose.

The graded dose response curve is obtained by plotting a graph with dose on the X-axis and response on the Y-axis. It is usually sigmoid in shape however the log dose response curve is almost a straight line and particularly useful in bio assay.

Conc. of unknown= Threshold dose of standard/threshold dose of test x Conc. of standard.

Conc. of unknown is read from a standard plot of a log dose response curve of at least 4 sub maximal concentrations

End Point or Quantal Assay

It is the simplest type of the bioassay. The threshold dose of the sample required eliciting a complete or a particular pharmacological effect is determined and compared with standard.

E.g. Digitalis producing cardiac arrest. Here the sample effect is identified by the response it produces on the biological system. Digitalis produces cardiac stimulation on further doses it produces cardiac arrest.

(+)d TC (Tubocurarine) producing neck relaxation in rabbit, Here as the sample is injected to the neck muscle of the Rabbit, the neck starts to droop. On further doses there is complete hanging of the neck and rabbit has no ability to lift the neck. Even the Determination of LD50 (LD=Lethal dose) or ED50 (ED= effective dose) is done by this method.

•  Based on the method used during the grade point assay procedure for determination of Type of activity and Potency of the Sample, four methods of assays are classified as:

1.  Matching point or bracketing method

2.  Interpolation assay

3.  Three point (2+1) assay

4.  Four- point (2+2) assay

1.  Matching point or bracketing method: Here a constant dose of the standard is bracketed by varying dose of sample until an exact matching between the standard dose responses and the particular dose response of the sample is achieved.

This technique is used

1. when test sample is too small
2. Inaccurate & margin of error difficult to estimate
3. Eg: histamine on guinea pig ileum, Posterior pituitary on rat uterus.

2.  Interpolation assay: Bioassays are conducted by determining the amount of preparation of unknown potency required to produce a definite effect on suitable test animals/organs/Tissue under standard conditions. This effect is compared with that of a standard. Thus the amount of the test substance required to produce the same biological effect as a given quantity the unit of a standard preparation is compared and the potency of the unknown is expressed as a% of that of the standard by employing a simple formula.

3.  Multi point Bioassay: This method incorporates the principle of interpolation and bracketing. 2+1 indicates- Two response of Standard and one response of Test respectively. This procedure of 2+1 or 2+2 is repeated 3 times or 4 times based on the method with crossing over of all the samples. It can further divided as 3 point, 4 point and 6 point bioassay.

•  Three point assay [2+1 dose assay] is Fast & convenient:

•  Log dose response [LDR] curve plotted with varying conc of std drug solutions and given test solution

•  Select two std doses s1& s2 [ in 2:3 dose ratio] from linear part of LDR [ Let the corresponding response be S1, S2]

•  Choose a test dose t with a response T between S1 & S2

•  Record 4 sets data as follows

§  s1 s2 t

§  t s1 s2

§  s2 t s1

§  s1 s2 t

Log Potency ratio [M] = [(T –S1) / (S2-S1)] X log (dose ratio)

•  4 point assay [2 +2 dose assay] [E.g. Ach bioassay]

•  Log dose response [LDR] curve plotted with varying conc of std Ach solutions and given test solution

•  Select two std doses s1& s2 from linear part of DRC [ Let the corresponding response be S1, S2]

•  Choose two test doses t1 & t2 with response T1 &T2 between S1 & S2 ;

•  Also s2/s1 = t2/t1 = 2/3

•  Record 4 data sets

•  s1 s2 t1 t2

•  s2 t1 t2 s1

•  t1 t2 s1 s2

•  t2 s1 s2 t1

ELISA

The enzyme-linked immuno-sorbent assay (ELISA). An ELISA test uses components of the immune system and chemicals to detect immune responses in the body. The ELISA test involves an enzyme (a protein that catalyzes a biochemical reaction). It also involves an antibody or antigen (immunologic molecules). ELISA is a popular format of a "wet-lab" type analytic biochemistry assay that uses a solid-phase enzyme immunoassay (EIA) to detect the presence of a substance, usually an antigen, in a liquid sample or wet sample.

The ELISA has been used as a diagnostic tool in medicine and plant pathology, as well as a quality-control check in various industries.

·  Use of an ELISA test

ELISA tests are widely utilized to detect substances that have antigenic properties, primarily proteins (as opposed to small molecules and ions such as glucose and potassium). The substances detected by ELISA tests include hormones, bacterial antigens and antibodies

·  Principle of ELISA test

There are variations of the ELISA test, but the most basic type consists of an antibody attached to a solid surface. This antibody has affinity for the substance of interest, E.g. human chorionic gonadotropin (HCG), the commonly measured protein which indicates pregnancy. A mixture of purified HCG linked to an enzyme and the test sample (blood, urine, etc) are added to the test system. If no HCG is present in the test sample, then only HCG with linked enzyme will bind. The more HCG which is present in the test sample, the less enzyme linked HCG will bind. The substance the enzyme acts on is then added, and the amount of product measured in some way, such as a change in color of the solution.

As a wet lab analytic biochemistry assay, ELISA involves detection of an "analyte" (i.e. the specific substance whose presence is being quantitatively or qualitatively analyzed) in a liquid sample by a method that continues to use liquid reagents during the "analysis" (i.e. controlled sequence of biochemical reactions that will generate a signal which can be easily quantified and interpreted as a measure of the amount of analyte in the sample) that stays liquid and remains inside a reaction chamber or well needed to keep the reactants contained; It is opposite to "dry lab" that can use dry strips - and even if the sample is liquid (e.g. a measured small drop), the final detection step in "dry" analysis involves reading of a dried strip by methods such as reflectometry and does not need a reaction containment chamber to prevent spillover or mixing between samples.

Types of ELISA

Four kinds of ELISA here are here illustrated as you may concern:

Direct ELISA

Direct ELISAs involve attachment of the antigen to the solid phase, followed by an enzyme-labeled antibody. This type of assay generally makes measurement of crude samples difficult, since contaminating proteins compete for plastic binding sites.

Indirect ELISA

Indirect ELISAs also involve attachment of the antigen to a solid phase, but in this case, the primary antibody is not labeled. An enzyme-conjugated secondary antibody, directed at the first antibody, is then added. This format is used most often to detect specific antibodies in sera.