calibration-and-validation

PREPARED BY
SUJITHA MARY
ASSISTANT PROFESSOR
KVM COLLEGE OF PHARMACY

Calibration & Validation
Introduction:
Concept of Validation: Ted Byers & Bud Loftus, U.S. FDA officials, in mid 1970’s,
more precise 1978 to improve the quality of pharmaceuticals
Drug regulatory authorities: ask for process, procedures, intermediate stages of
inspections, testing, adapted during Mfg. are adapted to produce similar, reproducible,
desired results meeting quality standards .The procedures are developed through
validation to maintain or assure high degree of quality.
VALIDATION: essential element of Pharm. quality assurance.
Validated process provides documented evidence & high degree of assurance that
uniform batches meeting the required specs. will be consistently produced.
Definition of validation: As per WHO: Action of proving & documenting that any
process, procedure or method actually & consistently leads to expected results.
Validation is the process of evaluating products or analytical methods to ensure
compliance with products or cleaning method requirements.

Qualification
 It is action of providing documented evidence that the equipment, premises, and systems
are designed, installed and perform correctly & are ready for intended use. Qualification
if a part of validation.
 There are six stages of qualifications:
a) Design qualification (DQ): It provides documented verification that all key aspects of
the design, procurement & installation adhere to the approved design intention & that
all the manufacturer’s recommendations have been suitably considered.
b) Installation Qualification (IQ): Document that the equipment is properly installed
according to the manufacturer and purchaser’s specifications. It covers equipment/system
descriptions, which includes principle of operation, design requirements, equipment
specifications piping, instruments diagrams, facility functional specifications, equipment
utility requirements, and equipment safety features.

Qualification
c) Operational qualification (OQ):
 Document that the equipment operates within established limits and tolerances. It covers
equipment operation procedures established and challenged equipment control functions,
calibration requirements and schedules established, and maintenance requirements.
d) Performance qualification (PQ):
 Documented evidence that the equipment can operate reliably as intended for the
process under routine, minimum, and maximum operating ranges. To prove consistency
in the performance of the equipments etc. test results are to be collected over a suitable
time period.

Qualification
e) Component qualification (CQ): It refers to manufacturing of auxiliary components to
ensure that they are manufactured to the correct design criteria. CQ is performed for the
components such as cartons, labels, shipping cases, phase change material etc. Random
inspections are to be carried out at the third party’s Mfg. site to ensure that the
components meeting the required specs are produced
f) Re- qualification: Refers to ensure that the equipments is still in the qualified state, after
any modification of relocation of the equipment is done. Re qualification is also
important at specific time intervals.

Importance of Validation
1. Quality assurance: Validation ensures that quality is built into the system at every step.
It checks accuracy & reliability of processes, procedures, methods to meet
predetermined criteria. It provides high degree of assurance & maintain batch to batch
quality
2. Cost reduction: Validation Helps in optimization of processes. It reduces sampling &
testing procedures within routine production, hence less re-inspection, retesting,
rework, rejection, & reduced no. of complaints & recalls. Thus save cost.
3. Regulatory compliance: It is an integral part of GMP guidelines. So, compliance is
must.
4. It assures quality
5. Customer./patient satisfaction
6. Quality is inbuilt into product
7. Increased efficiency, shortening lead time resulting in low inventories
8. Fewer rejects,reworks

Importance of Validation
9. Longer equipment life by operating as per specifications & establishing of cost effective
preventive schedules
10. Government regulations, successful inspections, approved products
11. Ability to export, increased throughput, reduction in utility cost
12. Avoid capital expenditures, fewer complaints about process related failures.
13. Reduced testing in process and finished goods.
14. More rapid & accurate investigations into process deviations
15. More rapid & reliable startup of new equipment.
16. Easier scale up from development work
17. Easier maintenance of the equipment
18. Improved employee awareness of processes
19. More rapid automation

PRINCIPLES OF VALIDATION
 the execution of validation should be in compliance with regulatory expectations;
 quality, safety and efficacy must be designed and built into the product;
 quality cannot be inspected or tested into the product;
 quality risk management principles should be applied in determining the need, scope
and extent of validation;
 ongoing review should take place to ensure that the validated state is maintained and
opportunities for continuing improvement are identified.

SCOPE OF VALIDATION
Pharmaceutical Validation is a vast area of work and it practically covers every aspect
of pharmaceutical processing activities, hence defining the Scope of Validation
becomes a really difficult task. However, a systematic look at the pharmaceutical
operations will point out at least the following areas for pharmaceutical validation;
Analytical
Instrument Calibration
Process Utility services
Raw materials
Packaging materials
Equipment
Facilities
Manufacturing operations, Product Design, Cleaning. Operators

SCOPE OF VALIDATION
Selection of raw material i.e. raw materials of desired quality attributes
Product design based on expected performance
Process design to build desired quality attributes in product
Design of control parameters like change control, acceptance criteria, tolerance limits etc.
In process quality control parameters & sampling plans
Finished product testing or evaluation criteria
Validation of related analytical process
Validation of related system, facility & equipment
Personnel training
Validation involves careful determination of criteria variable of the process. Such as
moisture content of granules, drying temperature of time, etc. and then establishment

PHASES OF VALIDATION
 The activities relating to validation studies are classified into three phases.
 Phase 1:
Pre-validation phase or the qualification phase ,which covers all activities relating to
product R & D, formulation, pilot batch studies, scale-up studies, transfer of technology
to commercial scale batches, establishing stability conditions, storage and handling of
in-process and finished dosage form, equipment qualification ,installation qualification,
master production documents, operational qualification, process capability.
 Phase 2:
Process validation phase (process qualification phase) designed to verify that all
established critical process parameters are valid & satisfactory products can be
produced even under the worst case conditions.
 Phase 3:
Validation maintenance phase requiring frequent review of all process related documents
,including validation audit report to assure that there have been no changes ,deviations,
failures modification to production process, and that all SOP’s have been followed
including change control procedures. At this stage the validation team also assures that
there have been no changes /deviations that should have resulted in requalification and
revalidation.

TYPES OF VALIDATION
 1. Process validation: is establishing documented evidence which provides a high
degree of assurance that a specific process (such as the manufacture of pharmaceutical
dosage forms) will consistently produce a product meeting its predetermined
specifications and quality characteristics.
Stage of activities in Process validation :
 Stage 1 – Process Design: The commercial manufacturing process is defined during
this stage based on knowledge gained through development and scale-up activities.
 Stage 2 – Process Qualification: During this stage, the process design is evaluated to
determine if the process is capable of reproducible commercial manufacturing.
 Stage 3 – Continued Process Verification: Ongoing assurance is gained during
routine production that the process remains in a state of control.

TYPES OF VALIDATION
 Types of Process Validation:-
1. Prospective Validation: It is establishment of documented evidence of what a system does
or what it purports to do based upon a plan. This validation is conducted prior to the
distribution of new product.
2. Retrospective Validation: It is the establishment of documented evidence of what a system
does or what it purports to do based upon the review and analysis of the existing
information. This is conducted in a product already distributed based on accumulated data
of production, testing and control.
3. Concurrent Validation: It is establishment of documented evidence of what a system does
or what it purports to do information generated during implemented of the system.
4. Revalidation: Whenever there are changes in packaging, formulation, equipment or
processes which could have impact on product effectiveness or product characteristics,
there should be revalidation of the validated process.

TYPES OF VALIDATION
2. Cleaning validation: is the process of assuring that cleaning procedures effectively
remove the residue from manufacturing equipment / facilities below a predetermined
level. Cleaning validation primarily applicable to the cleaning of process
manufacturing equipment in the pharmaceutical industry. The term cleaning
validation is to be used to describe the analytical investigation of a cleaning
procedures or cycle. It should also explain the development of acceptance criteria,
including chemical & microbial specifications, limits of detection & the selection of
sampling methods.
 The reasons for validating the cleaning procedure:
 It is customer requirement. Ensures safety & purity of product. It is regularity
requirement in API manufacture. Pharmaceutical products & API can be contaminated
by other pharmaceutical products, cleaning agents & microbial contamination. The
objective of the cleaning validation is to verify the effectiveness of cleaning procedure
for removal of product residues, degradation products, preservatives, excipients and/ or
cleaning agents as well as the control potential microbial contamination.

TYPES OF VALIDATION
Elements of Cleaning Validation
a) Establishments of acceptance criteria : procedure consistently removes residues
of substance previously manufactured down to levels acceptable and the cleaning
procedure itself does not contribute unacceptable levels of residual materials to the
equipment.
b) Cleaning procedure
c) Residues to be cleaned: Cleaning limits, Solubility's of the residues
d) Cleaning agent parameters to be evaluated: solubility properties, Environmental,
Health and safety considerations
e) Cleaning techniques to be evaluated: Manual cleaning, CIP (Clean-in place),
COP(clean-out-of-place), Semi automatic, Automatic, Time considerations
f) Other requirements: Sampling Techniques: Direct surface sampling:, Swab
sampling, . Rinse sampling, Placebo Sampling Method

TYPES OF VALIDATION
3. ANALYTICAL METHOD VALIDATION:
Refers to steps necessary to perform analytical test. Analytical methods needs to be
validated and re validated as the conditions of test may change.
It is the process to establish the performance characteristics of analytical method
fulfilling the required analytical applications.
It demonstrates that the method is suitable for intended purpose
Validity of specific method can be demonstrated in lab using samples/ standards
similar to unknown samples.
Role of each departments involved in validation must be clearly defined as per
Validation Master Plan

TYPES OF VALIDATION
TYPES OF ANALYTICAL METHOD FOR VALIDATION:
1. Identification Tests: To identify 1 or more analyte in sample, Property of test
samples compared with standard samples
2. Quantitative & limit test for impurities: To reflect the purity of a sample.
3. Quantitative Tests (assay): To measure analyte present in given sample

TYPES OF VALIDATION
VALIDATION CHARACTERISTICS OF ANALYTICAL METHOD
VALIDATION
1. Specificity
2. Linearity
3. Range
4. Accuracy
5. Precision: Repeatability, Intermediate precision, reproducibility
6. Detection Limit
7. Quantitation Limit
8. Robustness
9. System suitability test

TYPES OF VALIDATION
1. Specificity: ability of method to assess the analyte in presence of other components
(degradants, impurities, matrix etc.) of sample.
 Specificity of method should be determined during validation of Identification test,
impurity testing, assay methods.
 Specificity is essential to ensure correct identity of a sample, that the method provides
an accurate statement of content of impurities etc. & to provide exact estimate of the
potency of the analyte in sample.
 If impurity or degradation products are available, then assay methods should
demonstrate differences in analyte in presence of impurities. Pure drug substance is
spiked with required levels of impurities or excipients & compare results obtained on
unspiked samples.
 If not available, the specificity of method can be demonstrated by comparing test
results of samples containing impurities/degradation products to pharmacopoeial or
other validated analytical method.

TYPES OF VALIDATION
2. Linearity of analytical method
 It is the ability to produce test results within a given range directly proportional to the
amt/conc. of analyte in the sample. Dilution of stock solution of drug can be used.
Evaluation of linearity is done by visual inspection of plots which are function of
amt/conc. of analyte
 By using statistical methods, results can be evaluated.
 Ex. Regression line can be calculated by least square method, and regression line can be
used to calculate degree of linearity
 Slope of regression line, y intercept, correlation coefficient & residual sum of squares
along with the plot of data are estimated
 Minimum 5 conc. are recommended for obtaining linearity

TYPES OF VALIDATION
3. Range: It is the interval between the upper & lower conc. of analyte in sample for
which suitable level of precision, accuracy & linearity has been done. It is mainly
obtained from linearity studies
 Following minimum specified ranges for consideration:
a. For assay of drug subs./finished product- 80%-120% of test conc.
b. For content uniformity : 70-130% of test conc. According to dosage forms ex:
metered dose inhalers
c. For dissolution testing: ± 20% over the specified range
d. For impurities known to be extremely potent or to produce toxic or unexpected
pharmacological effects: Detection/quantitation limit should be in proportion to level
at which impurities can be controlled
e. If assay & purity are done together as one test & only a 100% std. is used, linearity
should cover the range from reporting level of impurities to 120% of the assay spec.

TYPES OF VALIDATION
4. Accuracy: “known as trueness” Agreement between true and measured value. Minimum
9 determinations of 3 conc. levels is done to check accuracy. It should cover the
specified range.
 ICH defines the accuracy of an analytical procedure as the closeness of agreement
between the values that are accepted as conventional true values or an accepted
reference value and the value found.
 Accuracy is usually reported as % recovery by the assay (using the proposed analytical
procedure) of known added amount of analyte in the sample or as the difference
between the mean and the accepted true value together with the confidence intervals.
 Typical accuracy of the recovery of the drug substance is expected to be about 99–
101%.
 Typical accuracy of the recovery of the drug product is expected to be about 98–102%.

TYPES OF VALIDATION
4. Precision: Repeatability, Intermediate precision, reproducibility
The precision of an analytical procedure expresses closeness of agreement between a series of
measurements
Precision may be considered at three levels: repeatability, intermediate precision and
reproducibility
The precision of an analytical procedure is usually expressed as the variance, standard deviation
or coefficient of variation of a series of measurements.
Repeatability: measure of the precision under the same operating conditions over a short
interval of time, that is, under normal operating conditions of the analytical method with the
same equipment. It is intra assay precision.
Intermediate Precision: variation within the same laboratory. Typical parameters that are
investigated include day-to-day variation, analyst variation, and equipment variation.
Experimental design will minimize the number of experiments that need to be performed
Reproducibility: means closeness of agreement in test results obtained b/w different
laboratories using same analytical method, assessed based on inter laboratory trial. Methods in
pharmacopoeias include reproduce.

TYPES OF VALIDATION
5. Detection Limit/ limit of detection (LOD)
It is capability of an analytical method to detect the lowest amt of
analyte in a sample. But quantitation of that amt is not considered.
Various approaches are there based on instrumental or non instrumental
procedures. They are
a) Visual evaluation : minimum level at which analyte can be detected
reliably is established.
b) Signal to noise approach: suitable with procedures with base line
noise. Signal to noise ratio: measures signals from sample with
known low conc. of analyte & compare the measured signals with
blank samples, & establish minimum conc. At which analyte can be
detected. Accepted limit is 3:1 or 2:1
c) Standard deviation of response & slope: Detection limit by this is
given by DL= 3.3 SD/S, SD is std. deviation, S is slope of calibration
curve. SD can be determined from SD of the blank or from calibration
curve.

TYPES OF VALIDATION
6. Quantitation Limit (QL/ LOQ limit of quantification) of an
analytical procedure
It is lowest amount of analyte in a sample which can be quantitatively
determined with suitable precision and accuracy. Used for the
determination of impurities and/or degradation products.
Approaches based on instrumental or non instrumental procedures are
a) Visual evaluation : Minimum level at which analyte can be quantified
reliably is established by taking sample with known conc.
b) Signal to noise approach: suitable with procedures with base line
noise. Signal to noise ratio: measures signals from sample with
known low conc. of analyte & compare the measured signals with
blank samples, & establish minimum conc. At which analyte can be
quantified. For QL signal is to noise ratio accepted limit is 10:1
c) Standard deviation of response & slope: QL is given by QL= 10
SD/S, SD can be determined from SD of the blank or from
calibration curve.

TYPES OF VALIDATION
7. Robustness: Robustness of an analytical procedure is a measure of
the analytical method to remain unaffected by small but deliberate
variations in method parameters and provides an indication of its
reliability during normal usage. The evaluation of robustness is
normally considered during the development phase and depends on the
type of procedure under study. Experimental design (e.g., fractional
factorial design or Plackett–Burman design) is common and useful to
investigate multiple parameters simultaneously. Common method
parameters that can affect the analytical procedure should be considered
based on the analytical technique and properties of the samples:
1. Sample preparation: Extraction time , Sample solvent, Membrane
filters, Sample and standard stability
2. HPLC conditions: Mobile-phase composition, Column used (equivalent
columns, lots and/or suppliers, age), Temperature, Flow rate
 3. Gas chromatography (GC) conditions: Column used, Temp. Flow rate

TYPES OF VALIDATION
8. System suitability test: It is an integral part of many analytical
procedures. The test are based on concept that the samples to be
analyzed, analytical operations, equipment & electronics constitute
an integral system that can be evaluated as such. It ensures that
system is working properly at the time of analysis. Determination
mode are repeatability, tailing factor T, capacity factor K’, resolution
R, theoretical plates N

VALIDATION MASTER PLAN
 It is key document to implement validation programme in GMP
regulated Pharm. Industry.
 It summarizes the company’s overall philosophy, intentions,
approaches to be used.
 It is approved written plan & summary doc. Provides overview of
entire validation operation.
 It outlines the principles involved in qualification of a facility,
defines the areas & systems to be validated & provides a written
program for achieving & maintaining a qualified facility with
validated processes.
 Format & content of validation master plan includes:
1. Introduction: Validation policy, scope, location, schedule
2. Organizational structure: personnel responsibilities

VALIDATION MASTER PLAN
 3. Plant/process/product description: rational for inclusions or
exclusions & extent of validation specific processes
considerations that are critical & those requiring extra
attention.
 4. List of products/processes/systems to be validated,
summarized in a matrix format, validation approach.
 5. revalidation activities, actual status and future planning
 6. Key acceptance criteria
 7. Documentation format
 8. Reference to the existing documents like required SOP’s
 9. Time plans of each validation project and sub project

CALIBRATION
 It is process of comparing a reading on one piece of equipment or
system with another piece of equipment that has been calibrated
& referenced to a known set of parameters.
 As per WHO: Calibration is set of operations that establish,
under specified conditions, the relationship between values
indicated by an instrument or system for measuring weight, temp.
pH etc. , recording, & controlling or the values represented by a
material measure, & the corresponding known values of a
reference standard.
 As per ICH: It is demonstration that a particular instrument or
device produces results within specified limits by comparison
with those produced by a reference or traceable standard over an
appropriate range of measurements.

Differences Between Calibration & Validation
CALIBRATION VALIDATION
Purpose: to demonstrate that a particular
instrument or device produces results
with in specified limits by comparisons
with those produced by reference over
appropriate range of measurements
Purpose: to documented verification that
provides high degree of assurance that a
specific process, equipment, method or a
system consistently produces a result
meeting predetermined acceptance
criteria
Performance of instrument or device is
compared against a reference standard
No such reference std. are used
Ensures that instrument/ measuring
device produce accurate results
Provides documented evidence that a
process, equipment, method or system
produces consistent results i.e. uniform
batch are produced
Performed periodically, to identify drift of
the measuring device or equipment &
make them accurate
No such req. performed when changes or
modifications happen to the existing
system or once revalidation period is
reached
Performed as per calibration SOP Performed as per validation protocol
Adjust the precision & accuracy of
instrument
Confirms precision & accuracy of
equipment

Qualification of UV visible spectroscopy
1. DESIGN QUALIFICATION
Documented evidence that the
plant design agrees with design
specs of costumer
3. OPERATIONAL
QUALIFICATION
Documented evidence which shows
that all parts of plant & equipment
work within their specifications &
process parameters
2. INSTALLATION
QUALIFICATION
Written evidence that all parts of
equipment are installed
according to equipment and
purchase spec.
4. PERFORMANCE
QUALIFICATION
Documented evidence that all parts
of a plant & processes produce
products of specified quality under
conditions of normal production
for a longer period of time
Qualification is an act or process to assure complies with standard

 Installation procedure: While the UV instrument was shipped
after precise adjustment & inspection at factory, it is
recommended to install according to following procedure so as to
provide its optimum performance & to meet user’s demand:
 Installation site:
 Room Temp. during use : 15-35C
 Out of direct sunlight
 No strong vibration or continuous weak vibration
 No strong magnetic fields or electromagnetic fields
 Humidity of 45 to 80%
 No corrosive gases or organic or inorganic gases with absorptivity
in UV range
 Small amount of dust

 ACCEPTANCE PROCEDURE
Items to be checked Specifications
Appearance No defect
Number of parts No missing parts
ROM check Latest version
Linearity of Absorbance Bent : ±0.002Abs
Shock noise: ±0.004 Abs
Noise level Noise width: ±0.002Abs
Shock noise: ±0.004 Abs
Accuracy of wavelength ±0.5nm
Repeatability of wavelength ±0.1nm

 OPERATIONAL AND PERFORMANCE QUALIFICATION
 Wavelength accuracy: it is defined as the deviation wavelength reading at an absorption
band and emission band from the wavelength of the band
 Acceptance: ±nm in UV range (200-380nm) &
± nm in visible range (380-800nm)
Three repeated scan of same peak should be within ±0.5nm
Stray Light: It is defined as the detected light of any wavelength that is outside the band
width of the wavelength selected
Acceptance: the transmittance of the solution in a 1cm cell should be less than 0.01 or the
absorbance value should be greater than 2
Resolution Power: the resolution power of UV-Vis Spectrophotometer is related to its
spectral band width. The smaller the band width the finer the resolution. Spectral band
width depends on the slit width & dispersive power of the monochromator

 Acceptance : The ratio of absorbance at 269nm & absorbance at 266 nm should be
greater than 1.5
 Noise: Noise is measurement affecting the accuracy at both end of absorbance scale.
Photon noise from the light source affects the accuracy of the measurement leads to low
absorbance
Acceptance : The RMS noise should be less than 0.001AU
Baseline flatness: the flat baseline test demonstrates that the ability of the instrument to
normalize the light intensity measurement & spectral output at different wavelength
throughout the spectral range
Acceptance: The measurement is typically less than 0.01AU
Stability: The lamp intensity is function of lamp age, temp. fluctuation, & wavelength of the
measurement. These changes can lead to errors in the value of measurements, over an
extended period of time
Acceptance : The deflection is less than 0.002AU/hr

 Photometric accuracy: it is determined by comparing the difference between the
measured absorbance of the reference material & the established value.
 Acceptance: six replicate measurements of the 0.006% w/v of potassium dichromate
solution at 235, 257, 313 & 350nm should be less than 0.5% RSD.
 Linearity: The linearity dynamic range of measurement is limited by stray light at high
absorbance and by noise at low absorbance.
The accuracy of the quantification of the sample depends on the precision & linearity of the
measurements.
Acceptance: Correlation coefficient: r ≥0.999

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