Role of quality by design (qb d) in quality assurance of pharmaceutical product
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Powerpoint Templates
ROLE OF QUALITY BY DESIGN (QbD)
IN QUALITY ASSURANCE OF
PHARMACEUTICAL PRODUCT
Presented by:
Dimple lodha
M. Pharm, sgsits
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CONTENTS
Introduction
Definition
Traditional Pharmaceutical Quality Assessment System
The Current And The Future State Of Quality Management
Comparision Of QbD Program With Current Status In QA
An Overview Of QbD Process
Steps Of QbD Program In Assuring Quality Of P’ceutical Product
Quality By Design (QbD) Tools
Important Computer Software For Optimization
Potential Benefits From QbD
Ten Key Challenges For QbD Adoption
Conclusion
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INTRODUCTION
a systematic method relating mechanistic understanding
of input material attributes and process parameters to
drug product critical quality attributes.
accomplished through the use of multivariate
experiments involving modern process controls enabling
process understanding.
QbD-based pharmaceutical manufacturing process will
be adjustable within a design space, providing a robust
process that is managed with a control strategy
developed using modern statistical process control
methods.
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DEFINITION
The International Conference on Harmonization (ICH)
has defined QbD in ICH Q8R as
“a systematic approach to pharmaceutical development
that begins with predefined objectives and emphasizes
product and process understanding based on sound
science and quality risk management.”
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COMPARISION OF QbD PROGRAM
WITH CURRENT STATUS IN QA
Aspect Current state Desired QbD state
Pharmaceutical
development
Empirical; univariate Systematic;
multivariate
Manufacturing
process
validation on three
batches; focus on
reproducibility
Adjustable within
design space; focus
on control strategy
Process control In-process testing PAT utilization
Product specification based on batch data based on product
performance
Control strategy intermediate and end
product testing
Risk-based; real-time
release
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STEPS OF QbD PROGRAM IN ASSURING
QUALITY OF PHARMACEUTICALS
Control manufacturing processes to produce consistent quality over time
Control strategy Process capability Maintain consistent
quality over time
Identify Critical Quality Attributes, Process Parameters and Sources of
Variability
Design space Source of variability
Design Product and Manufacturing Process
Product design and development Process design and development
Define Target Product Quality Profile
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Identifying Target Product Quality
Profile (TPQP)
The target product profile (TPP) has been
defined as a “prospective and dynamic summary
of the quality characteristics of a drug product
that ideally will be achieved to ensure that the
desired quality, and thus the safety and efficacy,
of a drug product is realized”.
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CONTD…
Quality target product profile for a lyo vial for sterile injectable
Requirement
Indication Chronic disease (treatment of nervous
breakdown)
Dosage form Lyophilisate for solution for injection
Dosage strength Nominal dose 20mg/vial
Administration route Subcutaneous (0.8ml)
Reconstitution time Not more than 2 min
Solution for reconstitution 1ml 0.9% saline (provided by the pharmacy)
Shelf life Two yr 2–8 ◦C
Drug product requirement Meets pharmacopoeial requirement for
parenteral dosage form as well as product specific requirements
Stability during administration Reconstituted solution is stable for 24 h at
Temperature ≤30 ◦C
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Product design and development
Physical properties
Chemical properties
Biopharmaceutical properties
Mechanical properties
Drug-excipient compatibility
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Process Design and Development
• Defined as outline of the commercial
manufacturing process. It includes:
Facility
Equipment
material transfer
manufacturing variables
computer-aided process design (CAPD)
process simulation
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Identifying CQA and CPP
• Critical Quality Attributes (CQA):
A CQA has been defined as “a physical, chemical,
biological, or microbiological property or characteristic
that should be within an appropriate limit, range, or
distribution to ensure the desired product quality”.
• Critical Process Parameters (CPP):
• Critical process parameters (CPP) are process inputs
that have a direct and significant influence on critical
quality attributes when they are varied within regular
operation range.
•
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Design Space
Design Space defines the relationship between Critical
Quality Attributes (CQAs) and Critical Process
Parameters (CPPs), and identifies acceptable operating
ranges for CPPs. It is the region where acceptable
product can be produced.
Design Space can be considered to be a snap-shot in
time representative of the current process knowledge.
The Design Space also contains the proven acceptable
ranges (PAR) for CPPs and acceptable values for their
associated CQAs.
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CONTD.
• Methods for presenting design space includes:
Graphs (surface-response curves and contour
plots)
Linear combination of parameter ranges
Equations
Models.
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CONTD.
FIGURE 3 FIGURE 4
Design space for granulation parameters
linear combination of their ranges, (Figure 3)
nonlinear combination of their ranges, (Figure 4)
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Control strategy
• ICH Q10 defines a control strategy as “a planned set of
controls derived from current product and process
understanding that assures process performance and
product quality. The controls can include parameters and
attributes related to drug substance and drug product
materials and components, facility and equipment
operating conditions, in process controls, finished
product specifications and the associated methods and
frequency of monitoring and control.”
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CONTD.
• Different levels of control strategies:
Level 1: Extensive end product testing + Fixed
Critical Process Parameters
Level 2: Reduced end product testing + Flexible
manufacturing process within fixed design space
Level 3: PAT, Real-time automatic“engineering
control” + Flexible manufacturing process
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QUALITY BY DESIGN (QbB) TOOLS
Design of Experiment:
Defining objectives of study and planning the
experiment
Screening of factors and factor influence study
Response surface methodology
Formulation and evaluation of DDS
Computer aided modelling and search for an optimum
Validation of DOE methodology
Scale up and implementation
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CONTD.
The input variables, which are directly under the control
of the product development scientist, are known as
independent variables e.g., drug content, polymer
composition, compression force, percentage of
penetration enhancer, hydration volume, agitation speed.
Quantitative variables
Qualitative variables
The characteristics of the finished drug product or the in-
process material are known as dependent variables
e.g., drug release profile, percent drug entrapment, pellet
size distribution, moisture uptake.
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Experimental designs for RSM,
screening, and factor influence studies
• Factorial designs
• Fractional factorial
designs
• Plackett–Burman designs
• Star designs
• Central composite
designs
• Box–Behnken designs
• Equiradial designs
• Mixture designs
• Taguchi designs
• Optimal designs
• Rechtschaffner designs
• Cotter designs
• Center of gravity designs
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Product Analytical Technology (PAT)
• A desired goal of the PAT framework is to design and
develop well understood processes that will consistently
ensure a predefined quality at the end of the
manufacturing process.
• Various tools of PAT are as follows:
Multivariate tools for design, data acquisition and
analysis
Process analyzers
Process control tools
Continuous improvement and knowledge
management tools
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Risk Assessment
Risk is defined as the combination of the probability of
occurrence of harm and the severity of that harm.
Risk Assessment is a “systematic process of organizing
information to support a risk decision to be made within a
riskmanagement process”.
It consists of the identification of hazards and the
analysis and evaluation of risks associated with
exposure to those hazards.
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IMPORTANT COMPUTER
SOFTWARE FOR OPTIMIZATION
Design Expert
JMP
FUSION PRO
ECHIP
STATISTICA
NEMROD
MODDE
DOE WISDOM
XSTAT
Multisimplex AB
COMPACT
Omega
iSIGHT
SOLVER
MATREX
GRG2
OPTIMA
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POTENTIAL BENEFITS FROM QbD
Quantifiable benefits
• Reduction of COGS and
capital expense.
• Technical development
productivity.
• Improved quality and
lower risk.
• Increased sales
Non Quantifiable Benefits
• Improved public image
• Standardized definitions
• Sharing best practices
• High quality of reviews
and delivery of regulatory
benefits
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TEN KEY CHALLENGES FOR QbD
ADOPTION
Challenges occur within
companies
• Internal misalignment
• Lack of belief in business case
• Lack of technology to execute
• Alignment with third parties
Challenges are directly
related to the FDA
• Inconsistency of QbD across
FDA
• Lack of tangible guidance
• Regulators not prepared to
handle
• Does not inspire confidence
• Misalignment of international
regulatory bodies
• Current interaction with
companies is not conducive to
QbD
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REFERENCES
Sandipan Roy in “Quality by design: A holistic concept of building
quality in pharmaceuticals”, June 2012, Int J Pharm Biomed Res,
100-108
Bhupinder singh, Rahul Batova, Chandra Bhushan Tripathi, Rishi
Kapil in Developing micro/ nano particulate drug delivery system
using “Design of Experiments” Volume I, Issue 2, April 2011,
International Journal of Pharmaceutical Science, 75-87
Bhat,S.“Quality by design approach to cGMP” 2010.
Drakulich, A. “Critical challenges to implementing QbD: A Q&A with
FDA”, Pharm. Technol, 2009, 90–94.
Q8(R1) Pharmaceutical Development Revision 1, 1 -14
Q8(R2) Pharmaceutical ,August 2009
Q9 Quality Risk Management, 4 version, November 2005
Q10 Pharmaceutical Quality System, June 2008