1. 1 ??FDA??????
Denis Kluba ??
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2. 2 ??Table Of Contents ????
CGMP??????
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3. 3 Part One: What is Validation?
4. 4 What is Validation? For this Seminar??? it refers to two things:
1. The USA FDA requirements that must be met in order to successfully and continually sell drug products in the USA
2. Activities that will contribute to the success of the company in the manufacture of drug products
5. 5 Validation
6. 6 Validation Is.....
7. 7 To Consistently Produce A Desired Known Product Why Do We Validate?
8. 8 How Do We Validate? Details Will Follow But This is the General Model
9. 9 First three steps to CGMP compliance document
document
document
10. 10 Boundaries of Validation
11. 11 Validation Life Cycle Approach
12. 12 Validation Life Cycle Approach
13. 13 Benefits of Validation Increased Throughput
Reduction In Rejections and Reworks
Reduction In Utility Costs
Avoidance Of Capital Expenditures
Fewer Complaints About Process Related Failures
Reduced Testing – In-process and Finished Goods
More Rapid / Accurate Investigations Into Process Upsets
More Rapid and Reliable Startup Of New Equipment
Easier Scale-up From Development Work
Easier Maintenance Of The Equipment
Improved Employee Awareness Of Processes
More Rapid Automation
14. 14 Elements Of Contemporary Validation In The US Equipment Calibration - Process and Validation Equipment
Equipment Qualification - Installation and Operational
Process Development
Process Documentation
Performance Qualification - "Validation"
Maintenance of Validation - Process and Equipment Change Control
15. 15 cGMP and ISO-9000 - Similarities Aimed at Quality
Require Documentation
Require Specific Quality Program
QA and QC Included
16. 16 cGMP and ISO-9000 - Differences cGMP Aimed at Product
ISO-9000 Includes Design and Service, as well
cGMP Covers Activities Directly Related to Manufacturing
ISO-9000 Covers Broader Range of Activities (e.g.. Purchasing)
cGMP Requires Formal Validation
ISO-9000 Requires Applicable Statistical Methods
17. 17 Benefits of the Systems Approach to Validation More Rigorous Control Over Operations
Centralized Planning for all Validation Related Aspects
Ties Existing Sub-elements into Cohesive System
Establishes Validation as a Program, not a Project
Provides for Continuity of Approach
Affirms Validation as a Discipline Much like Others
Allows For Personnel Growth within the Validation Expertise
Usually Results in Centralization of Validation Expertise
More Compatible with the Accomplishment of a Corporate??? Objective for Validation
18. 18 The Validation Program Establish Goals and Objectives as to What Must be Validated
Qualify or Re-qualify the Equipment
Establish Validation Protocols for each, and obtain Approval of the Protocols
Establish Personnel Requirements and Training Records Procedure
Design and Conduct Experiments. Collect Data
Evaluate the Data
Prepare Summary Reports Outlining the Results of the Experiments. Obtain the Necessary Approvals
Establish and Maintain Validation Files Including Raw Data
Institute a Change Control Procedure to Insure the Ongoing Acceptability of the Work The validation program is not planned and carried out in a vacuum. It must emphasize design criteria and specifications initially and gradually progress through the test phase to establish operating requirements and procedures.
The validation program is not planned and carried out in a vacuum. It must emphasize design criteria and specifications initially and gradually progress through the test phase to establish operating requirements and procedures.
19. 19 Part Two: GMP Requirements
20. 20 GMP requirements Part 211: Current good manufacturing practice for finished pharmaceuticals � §211.68 - Automatic, mechanical, and electronic equipment. � §211.84 - Testing and approval or rejection of components, drug product containers, and closures. � §211.110 - Sampling and testing of in-process materials and drug products. � §211.113 - Control of microbiological contamination. � §211.165 - Testing and release for distribution. � §211.166 - Stability testing.
21. 21 cGMP in the Pharmaceutical Industry GMP is the abbreviation of “Good Manufacturing Practice” which is adopted by the medical and health related industries including the pharmaceutical industry in an effort to maintain the highest standards of quality in the development, manufacture and control of medicinal products. Since the industry standards are subject to continuous improvement, the letter ‘c’ in the abbreviation “cGMP” refers more specifically to the current or the latest version of the GMP requirements.
22. 22 Regulatory Requirements for Validation..... The requirement of process validation is implicit in the language of 21 CFR 211.100 of the Current Good Manufacturing regulations which states:
“There shall be written procedures for product and process control to assure that drug products have the identity, strength, quality, and purity they purport or are represented to possess."
23. 23 GMP Regulatory Requirements �for Cleaning Validation 1978 cGMP Regulations (part 211.67(a)) Equipment cleaning and maintenance states:
“Equipment and utensils shall be cleaned, maintained, and sanitized at appropriate intervals to prevent malfunctions or contamination that would alter the safety, identity, strength, quality, or purity of the drug product beyond the official or other established requirements”.
24. 24 GMP Regulatory Requirements �for Test Method Validation Laboratory Controls 21 CFR 211.165(e) states:
The accuracy, sensitivity, specificity and reproducibility of test methods employed by the firm shall be established and documented. Such validation and documentation may be accomplished in accordance with Part 211.194(a)(2).
25. 25 GMP Regulatory Requirements �for Test Method Validation Part 211.194(a)(2) states:
A statement of each method used. . . shall indicate the location of data that establish that the methods used in the testing of the sample meet proper standards of accuracy and reliability as applied to the product tested. The suitability of all testing methods used shall be verified under actual conditions of use.
26. 26 GMP Regulatory Requirements �for Test Method Validation U.S. Federal Court decision:
United States vs Barr Labs
Cleaning Validation: . . . it was ruled for cleaning to be effective, the specific test methods had to be shown to be effective.
27. 27 PROCESS VALIDATION 21 CFR 211.110
“such control procedures shall be established to monitor the output and to validate the performance of those manufacturing processes that may be responsible for causing variability in the characteristics of in-process material and the drug product”
28. 28 Part Three: History and Expectations As applied by the FDA and Implemented by Industry
29. 29 History and expectations Learn for the experiences of the USA manufacturers and industry organizations
Current applications
Past citations
Industry guidelines
ICH Q7A
ISPE
PDA
Etc.
30. 30 Validation Targets Early Years
Sterilization
Aseptic Operations
Middle Years
Non-sterile Processes
Oral Dosage Forms
Recent Years
Biological Processes
Bulk Organic Synthesis
Developmental and Pilot Operations
Supporting Services
Currently
Total Operations
Review by Systems
Quality System
Production System Laboratory Controls
Packaging and Labeling, Materials and Facilities
Equipment Manufacturing. The trend in recent years has been to expand validation activities backwards both time-wise and process-wise. In other words, validation is now being performed both early in the drug development process and nearer the beginning of the production process.
This trend has paralleled the trend toward a systems or Life Cycle approach to validation.The trend in recent years has been to expand validation activities backwards both time-wise and process-wise. In other words, validation is now being performed both early in the drug development process and nearer the beginning of the production process.
This trend has paralleled the trend toward a systems or Life Cycle approach to validation.
31. 31 History of Validation Validation in The Early Years - 1972 to 1978
Regulatory Based to Satisfy FDA Pressures
Defensive to Protect Product Line
Validation in Its' Adolescence - 1978 To 1983
Primarily Defensive
Some Efforts at Process Optimization
Includes Some Peripheral Concerns
Validation in the US Today - 1983 to Present
Non- Regulatory in Many Areas Geared Towards Optimization and focused on Systems
32. 32 "validation" vs. "VALIDATION" "validation"
Defensive
Testing Oriented
Costly
Quality Control
Narrow Focus Big "V" vs. little "v" - the difference is obvious. How to get there is with the Life-cycle or systems approach. Then Validation becomes not an event, but a state, that is a state of control over the process.
Initially, validation encompassed only the "testing" of the system, process or product.
Contemporary Validation encompasses a system of inter-related practices which, in combination, provide regulatory compliance in addition to other advantages.Big "V" vs. little "v" - the difference is obvious. How to get there is with the Life-cycle or systems approach. Then Validation becomes not an event, but a state, that is a state of control over the process.
Initially, validation encompassed only the "testing" of the system, process or product.
Contemporary Validation encompasses a system of inter-related practices which, in combination, provide regulatory compliance in addition to other advantages.
33. 33 Elements of Contemporary Validation in the US Equipment Calibration - Process and Validation Equipment
Equipment Qualification - Installation and Operational
Process Development
Process Documentation
Performance Qualification - "Validation"
Maintenance of Validation - Process and Equipment Change Control
34. 34 Expectations Validation is a Program not a Project
Validation Contributes to the Stability of the Operations
Validation is not Someone Else's Job!
35. 35 Part Four: Validation An Overview
36. 36 Who Validates?
37. 37 Validation
38. 38 Validation
39. 39 Validation The objective of these two slides is to indicate the concept of validation as one which involves the entire life of the project, thus the term "Life-cycle".
A plant or process cannot be validated if it is not designed and installed properly. There must be design reviews by people who know the process and inspections of the equipment and facility as they are constructed and installed. Many different groups must become involved in the program. Although the team leader may be from manufacturing (as is usually the case at Roche in the bulk manufacturing area), the other team members are equally important. It must be a team effort.
The objective of these two slides is to indicate the concept of validation as one which involves the entire life of the project, thus the term "Life-cycle".
A plant or process cannot be validated if it is not designed and installed properly. There must be design reviews by people who know the process and inspections of the equipment and facility as they are constructed and installed. Many different groups must become involved in the program. Although the team leader may be from manufacturing (as is usually the case at Roche in the bulk manufacturing area), the other team members are equally important. It must be a team effort.
40. 40 Write Protocols
41. 41 Example Data Sheets
42. 42 Conduct Testing
43. 43 Installation Qualification (IQ) IQ documents that
system is installed in accordance with approved design, specification and regulatory codes
manufacturers installation recommendation have been taken into consideration
IQs implemented concurrently with construction of each system
44. 44 Operational Qualification (OQ) OQ documents that the equipment:
can operate as designed and intended
is capable of repeatable operation over the entire operating range of process variables
OQ executed when equipment can be started up
45. 45 Process Qualification (PQ) PQ documents
critical systems which can be challenged
test procedures
product quality attributes to be evaluated
acceptance criteria
alert/action levels
system validated under "worst case conditions"
generally 3 consecutive successful runs required
46. 46 Definition of Process Validation Validation is:
Documented evidence that provides a high degree of assurance that a specific process will consistently produce a product of a certain predetermined quality. THE DEFINITION OF PROCESS VALIDATION HAS CHANGED FROM:" PROOF THAT A PROCESS DOES WHAT IT PURPORTS TO DO. " TO THE MORE ACCEPTED DEFINITION CONTAINED IN THE FDA'S GUIDELINES ON PROCESS VALIDATION.
THE KEY DIFFERENCES ARE THAT WHEREAS THE OLDER DEFINITION EMPHASIZED THE TESTING APPROACH TO VALIDATION, THE NEWER DEFINITION REQUIRES A SYSTEMS APPROACH, INCLUDING EMPHASIS ON DESIGN AND OPERATION, AS WELL AS TESTING.THE DEFINITION OF PROCESS VALIDATION HAS CHANGED FROM:" PROOF THAT A PROCESS DOES WHAT IT PURPORTS TO DO. " TO THE MORE ACCEPTED DEFINITION CONTAINED IN THE FDA'S GUIDELINES ON PROCESS VALIDATION.
THE KEY DIFFERENCES ARE THAT WHEREAS THE OLDER DEFINITION EMPHASIZED THE TESTING APPROACH TO VALIDATION, THE NEWER DEFINITION REQUIRES A SYSTEMS APPROACH, INCLUDING EMPHASIS ON DESIGN AND OPERATION, AS WELL AS TESTING.
47. 47 Definition of Process Validation In addition to documented evidence that a process will perform reliably and repeatedly, validation, in its highest form, provides an understanding of why.
48. 48 Stages of the Life-Cycle Even the R&D phase is important, because it defines the requirements of the product and process. In each succeeding step, the system becomes better and better defined and is subject to stricter and stricter controls. The operational phase (SOPs/maintenance) may be considered the most critical phase of validation. After all, this is the phase where the product is made. This is the phase which operator and mechanics control.Even the R&D phase is important, because it defines the requirements of the product and process. In each succeeding step, the system becomes better and better defined and is subject to stricter and stricter controls. The operational phase (SOPs/maintenance) may be considered the most critical phase of validation. After all, this is the phase where the product is made. This is the phase which operator and mechanics control.
49. 49 Benefits of Validation Increased Throughput
Reduction in Rejections and Reworks
Reduction in Utility Costs
Avoidance Of Capital Expenditures
Fewer Complaints About Process Related Failures
Reduced Testing – In-process and Finished Goods
More Rapid / Accurate Investigations Into Process Upsets
More Rapid and Reliable Startup Of New Equipment
Easier Scale-up From Development Work
Easier Maintenance Of The Equipment
Improved Employee Awareness Of Processes
More Rapid Automation
50. 50 Documentation of Validation Master Plan
Protocol
Data Sheets
Report
Procedures The key to modern validation is documentation. Much of what we now do is a repeat of what might be considered good engineering and construction practices. The problem in the past is, that although these practices were carried out, they were often not properly documented and maintained, resulting in the loss of valuable information.
The validation program ensures that this information gets into the hands of the operating (manufacturing, QC, QA, Tech. Services) people who run the process after engineering has moved on.The key to modern validation is documentation. Much of what we now do is a repeat of what might be considered good engineering and construction practices. The problem in the past is, that although these practices were carried out, they were often not properly documented and maintained, resulting in the loss of valuable information.
The validation program ensures that this information gets into the hands of the operating (manufacturing, QC, QA, Tech. Services) people who run the process after engineering has moved on.
51. 51 Validation Protocols Provide an Outline of the Validation Effort
Include a Clear Definition of What Will Be Validated
Is Uniquely Identified
Is Dated
Approved By Competent Individuals In Responsible Areas
Are Suitable For Review By Regulatory Agencies Although not strictly required by the GMPs, the protocol has become a necessary part of a solid validation program. It not only plans the testing phase, but provides the background necessary to understand the system. In doing so, it becomes the foundation for future operating and maintenance procedures.
Although not strictly required by the GMPs, the protocol has become a necessary part of a solid validation program. It not only plans the testing phase, but provides the background necessary to understand the system. In doing so, it becomes the foundation for future operating and maintenance procedures.
52. 52 Validation Protocol Essential Elements Introduction/Abstract
Description of Process or System
Test Plan
Responsibilities
Acceptance Criteria
Approvals
Append Data Sheets, Etc. The introduction or abstract may be short, explain the location of the system and the purpose of the protocol.
The description is important as it serves to familiarize the responsible team members so that they may plan and review the test program.
The results of the test program are judged against the acceptance criteria. These should be clear and unambiguous, so that review and approval of the final report is expedited.
Data sheets and other records to be filled out during testing should also be prepared up front so that they may be reviewed for completeness.The introduction or abstract may be short, explain the location of the system and the purpose of the protocol.
The description is important as it serves to familiarize the responsible team members so that they may plan and review the test program.
The results of the test program are judged against the acceptance criteria. These should be clear and unambiguous, so that review and approval of the final report is expedited.
Data sheets and other records to be filled out during testing should also be prepared up front so that they may be reviewed for completeness.
53. 53 Validation Reports – Functions Restrict to One Task or Subject
Has a Unique Identification
Is Dated
Formally Reviewed and Approved
Identifies Protocol(s) Used in the Study
Is Suitable for Review by FDA
54. 54 Validation Report - Contents Abstract Or Summary Conclusion
Plan Of Study
Experimental
Results
Conclusions
Protocol Reference
Diagrams
Any Miscellaneous Information
Approvals The report is the ultimate record. It should contain the protocol, and thus, a complete but concise description of the system. Sketches and drawings, both of the system and the experimental design , are valuable.
The objective is to provide a ready reference for future understanding, operating and troubleshooting of the system. It may become the system "bible", so to speak.
A summary section, with data tables, but not complete raw data, may serve for initial presentation to the FDA.
Include lab results and all completed data sheets in the main report. These should be signed off according to cGMP.The report is the ultimate record. It should contain the protocol, and thus, a complete but concise description of the system. Sketches and drawings, both of the system and the experimental design , are valuable.
The objective is to provide a ready reference for future understanding, operating and troubleshooting of the system. It may become the system "bible", so to speak.
A summary section, with data tables, but not complete raw data, may serve for initial presentation to the FDA.
Include lab results and all completed data sheets in the main report. These should be signed off according to cGMP.
55. 55 Installation Qualification (IQ) IQ Documents That The:
System is Installed in Accordance with Approved Design, Specifications and Regulatory Codes
Manufacturers Installation Recommendations have been taken into Consideration
IQ is Implemented Concurrently with Construction of Each System IQ answers the questions: "What is the system, how and where is it documented, and has it been built and/or installed properly?" This can be a monumental task, especially in large plants. It requires an understanding of engineering and construction principles, the current state of the industry with regard to design and , of course, the cGMPs.
Some IQ can be carried out by contractors or construction supervisors, if properly documented and audited. The validation team must determine the criticality of the data and whether 100% inspection is required. Examples include pressure testing, cleaning and passivation, receipt of materials, workmanship, HVAC balance, DOP testing, etc.
The close link between engineering and validation reaches a high point during IQ. The following diagram indicates how these two activities interact starting with the inception of the project.
Key engineering documents, drawings and specifications, are used in the field as a reference.. The validation team will audit or inspect to see that they are followed.
The most often used drawing is the P&ID, example included. This will be taken to the field and marked up to indicate whether the installed system complies or not. Where it does not, a decision must be reached as to whether a field correction needs to be made or whether the drawing needs to be changed. When agreement is reached, the validation team will mark-up the field copy and sign it, indicating the accepted state of the installation. This is only done after field corrections are completed and inspected. The marked up and signed drawing becomes the reference for preparation of "as built" P&IDs. It becomes part of the validation record. In some critical systems (e.g.. WFI, clean rooms) other design drawings, such as piping isometrics or duct drawings might also be used in IQ.
Some other typical data sheets used in IQ are also included.
IQ answers the questions: "What is the system, how and where is it documented, and has it been built and/or installed properly?" This can be a monumental task, especially in large plants. It requires an understanding of engineering and construction principles, the current state of the industry with regard to design and , of course, the cGMPs.
Some IQ can be carried out by contractors or construction supervisors, if properly documented and audited. The validation team must determine the criticality of the data and whether 100% inspection is required. Examples include pressure testing, cleaning and passivation, receipt of materials, workmanship, HVAC balance, DOP testing, etc.
The close link between engineering and validation reaches a high point during IQ. The following diagram indicates how these two activities interact starting with the inception of the project.
Key engineering documents, drawings and specifications, are used in the field as a reference.. The validation team will audit or inspect to see that they are followed.
The most often used drawing is the P&ID, example included. This will be taken to the field and marked up to indicate whether the installed system complies or not. Where it does not, a decision must be reached as to whether a field correction needs to be made or whether the drawing needs to be changed. When agreement is reached, the validation team will mark-up the field copy and sign it, indicating the accepted state of the installation. This is only done after field corrections are completed and inspected. The marked up and signed drawing becomes the reference for preparation of "as built" P&IDs. It becomes part of the validation record. In some critical systems (e.g.. WFI, clean rooms) other design drawings, such as piping isometrics or duct drawings might also be used in IQ.
Some other typical data sheets used in IQ are also included.
56. 56 Design Documentation Design and Procurement Documentation Support of IQ:
PFDs/P&IDs
Critical System Installation Drawings (E.G. Water System Isometrics, Sanitary Duct Drawings)
Purchase and Installation Specifications
Vendor Manuals and Prints
Computer Software Documentation The list is by no means complete, but is meant to alert designers/constructors as to the types of documentation required to support validation. Any given project may require additional documentation to support facility, equipment and support system qualification.
Some of the above documents, particularly specifications and vendor literature, are also important in support of OQ. These tell the validation team what the capability of the equipment or system is intended to be, so that it may be tested.The list is by no means complete, but is meant to alert designers/constructors as to the types of documentation required to support validation. Any given project may require additional documentation to support facility, equipment and support system qualification.
Some of the above documents, particularly specifications and vendor literature, are also important in support of OQ. These tell the validation team what the capability of the equipment or system is intended to be, so that it may be tested.
57. 57 Construction Documentation Construction Documents In Support Of IQ:
Slope Checks
Piping Pressure Test Reports
Motor Checkout Reports
Weld Inspection Reports
Cleaning, Passivation and Sanitization Procedures and Reports
HVAC Test and Balance Reports
Other Appropriate Construction Documentation
58. 58 The P&ID Process Equipment
Support Vessels
Interconnecting Lines
Utility Lines
Instruments/Instrument Functions
Schematic
No Scale - Not Spatially Precise
Shows Relationships and Relative Position For most systems the P&ID is the only drawing necessary to check out a field installation. All members of the validation team should familiarize themselves with this type of document and learn how to read it and use it.For most systems the P&ID is the only drawing necessary to check out a field installation. All members of the validation team should familiarize themselves with this type of document and learn how to read it and use it.
59. 59 Operational Qualification (OQ) OQ Documents That The Equipment:
Can Operate as Designed and Intended
Is Capable of Repeatable Operation Over the Entire Operating Range of Process Variables
OQ Implemented After Equipment has been Started Up or Commissioned OQ should begin after the system has been started up and/or commissioned. This may be called pre-Q and involves the proper application of power, leak checking, lubrication, coolant addition, etc. These activities are best carried out by construction or maintenance crews. The validation team, unless specifically charged to do so, should not be expected to perform start-up.
The real reasons for OQ are to run the equipment through its paces for comparison with operating specs. This is generally not done with product, but makes use of water or a placebo.
Often, operating parameters which are not subject to specification (e.g. heat up rate) will also be checked during OQ to establish baseline date for future system evaluation. Several OQ data sheets of various kinds are included. A non conformance report triggers corrective action, or at least establishes a record, where a system may not meet spec.OQ should begin after the system has been started up and/or commissioned. This may be called pre-Q and involves the proper application of power, leak checking, lubrication, coolant addition, etc. These activities are best carried out by construction or maintenance crews. The validation team, unless specifically charged to do so, should not be expected to perform start-up.
The real reasons for OQ are to run the equipment through its paces for comparison with operating specs. This is generally not done with product, but makes use of water or a placebo.
Often, operating parameters which are not subject to specification (e.g. heat up rate) will also be checked during OQ to establish baseline date for future system evaluation. Several OQ data sheets of various kinds are included. A non conformance report triggers corrective action, or at least establishes a record, where a system may not meet spec.
60. 60 Process Qualification (PQ) PQ Documents That:
Processes Operate as Required at the Normal Operating Limits of Critical Parameters
Systems Operate Consistently and Reliably
Appropriate Challenges Are Employed
61. 61 Review and Approvals Design Drawings and Specifications
Master Plan
Protocols
Reports
Procedures
62. 62 Part Five: Validation Master Planning
63. 63 Planning “If you don’t know where you are going, you are likely to end up someplace else!” - Lewis Carroll
Like any other important activity in a complex organization validation must be managed. This is especially true given the multi-disciplined nature of many validation activities.
64. 64 Existing Plants The same level of management is necessary for the validation of an existing facility, whether fully validated or not.
Validation is easier when it is an integral part of the day-to-day operation of the facility.
65. 65 Master Plan Defines and Establishes the Validation Approach and the Acceptance Criteria
66. 66 Facilities, Processes or Products What needs to be done?
Who will do it?
How will they do it?
How long will it take?
How much will it cost?
67. 67 Master Plan - General Introduction to Facility Purpose and Design Intent
Facility/Process Description
Process Control Considerations
System Definitions
Planning/Scheduling
68. 68 Master Plan - Why Project Familiarization/Training
Management Introduction
FDA Introduction/Familiarization
Validation Program Foundation
Basic Procedures
Protocol Outlines/Bases
Resource Planning/Scheduling
Contract Execution Interaction
Codifies Prior Decisions
Structures Validation Activities
Facilitates Regulatory Compliance
Useful in Regulatory and Client Interactions
Use With 3rd Parties
Convertible Into Drug Master File
Internal Audit Preparation
69. 69 Master Plan - What Introduction
Facility / Process / Product Description
Process Control Considerations
System Definition
Protocol Outlines/Acceptance Criteria
Formats
SOPs
Planning/Scheduling
70. 70 Master Plan - Getting Started Facility Layout
Process Description(s)
Product Description(s)
Equipment List
Utility List
Controlled Environment Requirements
Control Philosophy
Schedule
71. 71 Master Plan – Facility Description Layout/Equipment Arrangement
People/Material/Component Flow
Controlled Environments
Materials of Construction
Sketches
72. 72 Master Plan - Process Description Major Process Steps
Block Diagram
Process Flow Diagram(s)
Utilities (WFI, DI, CIP, Etc.)
Major Support Equipment
(Autoclaves, Ovens, Etc.)
73. 73 Master Plan - Process Control General Architecture
Central/Distributed Control System
PLCs/Individual Control Systems
Building Automation System
Higher Level Systems (LIMS, EBR, Etc.)
Integrate into other Sections if Minimal
74. 74 Master Plan - Validated Systems Lists Of Systems To Be Validated
General Acceptance Criteria
Specific Acceptance Criteria
Basic Protocol Outlines
75. 75 Master Plan - Procedures and Formats Protocol Format
SOP Format
Basic Procedures
Validation Program
Responsibilities
Calibration
Change Control
List Of SOPs
76. 76 Master Plan - Planning and Scheduling Manpower Resources
Document Preparation
Field Execution
Calibration
Lab Support
Test & Balance/Filter Certification
Start-Up/Commissioning
77. 77 Master Plan - Focus Sterile Products Facility
Emphasis On Facility and Environment
People, Component, Product Flows
Automation May Or May Not Be Central
Support Systems Critical (Autoclaves, Ovens, WFI, Etc.)
78. 78 Master Plan - Focus Solids Facility
In-process Controls
Tests
Examinations to be Conducted on Appropriate Samples of In-process Materials of Each Batch
79. 79 Master Plan - Focus API Facility
Emphasis On Chemical Process
Identify API Step
Cross-contamination Control, if Appropriate
Automation Critical
Cleaning Critical In Multi-product Facilities
80. 80 Master Plan - Focus CIM Systems
Emphasis on Functional Requirements
System Structure
Communication Routing
81. 81 Master Plan - Focus Anything Unusual
Areas that are Unique to Your Process
Emphases on the Philosophy for Controls (Procedural and Automation)
82. 82 Part Six:�Methods of Performing Validation Including Document �Requirements,
Formats and Approvals
83. 83 Qualification Combine I/OQ into Single Document
Add PQ for Smaller Projects
I/OQ is Sometimes 90% of the Overall Effort, but Receives Only 10% of the Investigators Attention
Review Contractor Proposals Closely
84. 84 Design Qualification Useful on Larger Projects
Critiques Design from an Operability & Validation Perspective
Reduces Costs of Correcting Errors
Required in Device Regulations
85. 85 Installation/Operational Qualification Checklist Format Preferred
Avoid Arbitrary Criteria
Convey Requirements to Suppliers in Specifications
Check at Vendor and Reconfirm on Site
Focus on Accuracy of Collected Documentation
Test to Manufacturer’s Specifications if the Detailed Process Needs are Vague
86. 86 Performance Qualification Use Generic Protocols [“Terminal Sterilization” rather than “Sterilization of xxxxx Vials, Autoclave 6, Building 4”]
Use Quantitative Criteria [“RSD Maximum of 4.5%” Rather Than “Must Demonstrate a Uniform Mix”]
Use Meaningful Criteria [“3 Log Reduction in Endotoxin” Rather Than “8 Minutes At 300 C”]
87. 87 Validation as discussed in Q7A Should extend to those operations determined to be critical to the quality and purity of the API
Critical parameters/attributes are normally identified during the development stage or from historical data, along with ranges necessary for reproducible operations
88. 88 Prospective Validation Q7A Normally performed for all API processes�
Validation of API process should be completed before commercial distribution of the final drug product manufactured from that API
89. 89 Concurrent Validation Q7A Conducted when data from replicate production runs are unavailable:
Limited number of API batches produced �
API batches produced infrequently
API batches produced by a validated process that has been modified
90. 90 Concurrent Validation Q7A Batches can be released and used in production of drug products for commercial distribution based on thorough monitoring and testing of the API batches
91. 91 Retrospective Validation Q7A Exception for well established processes used without significant changes to API quality due to changes in:
Raw materials
Equipment
Systems
Facilities
Production Process
92. 92 Retrospective Validation Q7A May be used where:�
Critical quality attributes and critical process parameters have been identified�
Appropriate in-process acceptance criteria and controls have been established
93. 93 Retrospective Validation Q7A May be used where (Continued):�
Process/product failures attributed mostly to operator error or sporadic equipment failures unrelated to equipment suitability
Impurity profiles have been established for existing API
94. 94 Validation Q7A Validation is NOT for exploration to design a process. It is for showing that an already established process does what it is supposed to do.
Validation approaches, protocols, execution, and reports are fully described.
Different from drug manufacturing: Only critical processes are usually validated, e.g.. at the following points of the processing:� - significant impurities may be introduced or removed� - no significant impurities will be removed� - all essential structural elements of the API are present
95. 95 New Equipment/System Milestones
96. 96 Commissioning/Qualification Transformation
97. 97 Qualification Program
98. 98 Qualification Program Attributes Completion Of Commissioning.
Test Protocol(s) With Pre-determined Acceptance Criteria Covering Installation and Operation.
Execution Under Pre-approved Procedures For:
Protocol and Report Development
Documentation Practices
Change Control (Pre-approval Of Changes)
Investigations (Deviations)
Approvals
99. 99 Commissioning Program Attributes Ability to ‘Fix’ Equipment/System as Required (Design Intent).
Documented Activities.
Tests That Have Pre-determined Expectations.
Execution Under Pre-approved Procedures For:
Test Plan Development
Test Execution
Documentation Practices
Change Management (Documented Audit Trail for Changes, including Approvals)
Approvals
100. 100 Proposed Qualification Program
101. 101 Test Documentation
102. 102 PROJECT RESPONSIBILITIES� THE RESPONSIBILITIES OF THE VALIDATION TEAM Writing and approving the Master Plan.
Writing protocols
Providing validation engineers
Providing supervisory assistance
Generation of summary reports
Preparation of designated Standard Operating Procedures (SOP).
Training to construction and operation personnel as needed for the validation activities.
Review, assistance and support as outlined in the project approach section of this Master Plan for the Engineering/Construction/Validation interface.
103. 103 PROJECT RESPONSIBILITIES� THE RESPONSIBILITIES OF THE GENERAL CONTRACTOR Reviewing and approving the Master Plan and appropriate protocols.
Review, approval and implementation of Validation’s checklists.
Establish and maintain the document control procedures and administration for this project.
Transmission of all design drawings, specifications, purchase documents and vendor literature
Execution of the Protocols as defined.
Assembly of the turn-over and construction support documentation.
Coordination of Calibration, certification activities and supervision of the subcontractors execution of validation activities.
Support activities as outlined in the project approach section of the Master Plan for the Engineering/Construction/Validation interface.
104. 104 PROJECT RESPONSIBILITIES� THE RESPONSIBILITIES OF ENGINEERING CONTRACTOR Write up the Basis of Design for all systems and sections of the facility and have them approved by the responsible operations personnel.
Preparation of all design drawings and specifications necessary for the completion of the scope of work by Validation.
Support activities as outlined in the project approach section of the Master Plan for the Engineering/Construction/Validation interface.
Reviewing and approving the Master Plan.
105. 105 PROJECT RESPONSIBILITIES� THE RESPONSIBILITIES OF OPERATIONS Supplying all procedures and documentation necessary for the generation of the Master Plan and execution of the protocols.
Reviewing and approving the Basis of Design and the Master Plan and all other documentation such as protocols, the executed protocol data packages and the final reports produced by Validation.
Preparation of designated Operation, Calibration, and Maintenance Standard Operating Procedures (SOP). Providing personnel, when necessary, to assist in the sampling and operating of equipment and equipment systems during the execution of qualification studies.
Coordination of all other Validation Team requirements and responsibilities.
Providing Validation personnel with adequate office and specified Quality Control laboratory support and test methods as required for the execution of the scope of work.
Support activities as outlined in the project approach Section of the Master Plan for the Engineering/Construction/Validation interface.
106. 106 List and Compare Break Down of Scope
Categorize the Packages
Keep Like Items Together
Define Boundaries
107. 107 Integrated E,P,C,V,SI Timeline Research and Development: Process Requirements, Critical Process Parameters, Cleaning Toxicology, Analytical Testing
Conceptual Design: Project Approach and Integration Plan
Basic Engineering: Review of critical systems and philosophies
Detailed Engineering: Validation/GMP Input, Procurement, Vendor documents, Specifications, Acceptance Criteria, P/Os, Drawings, FAT & VTOP
Construction: FAT/SAT, Training, Installation Qualification, Ongoing Audit/Review, SOPs, “As-built Drawings”Research and Development: Process Requirements, Critical Process Parameters, Cleaning Toxicology, Analytical Testing
Conceptual Design: Project Approach and Integration Plan
Basic Engineering: Review of critical systems and philosophies
Detailed Engineering: Validation/GMP Input, Procurement, Vendor documents, Specifications, Acceptance Criteria, P/Os, Drawings, FAT & VTOP
Construction: FAT/SAT, Training, Installation Qualification, Ongoing Audit/Review, SOPs, “As-built Drawings”
108. 108 Integrated Validation The purpose of integrated validation is to provide assurance and documented evidence that a facility will consistently produce pharmaceutical substances which meet the owner’s specifications that are their interpretation of the regulatory requirements for the products they are going to manufacture. Integrated validation will assure that the equipment and facilities are installed, constructed and operate per the manufacturing requirements and that they provide an environmentally and physically safe work area for employees.
Integrated validation requires all vendors and suppliers of equipment, contractors and sub contractors responsible for construction and installation of plant systems and equipment, all departments and disciplines which are confronted with cGMP requirements to participate and understand their role in the implementation of the regulatory requirements of the operation. Integrated validation incorporates the use of the expertise and documentation of skilled personnel hired to perform functions in a project and to transfer the necessary technology to the on going operations.
The integrated validation will be organized following the modular or system approach, mimicking the design methods used, when performing Installation Qualification (IQ) and Operational Qualification (OQ).
What follows is an outline of a methodology using integrated validation at an inspected and qualified facility. The methodology developed in the project is the methodology still in place for both on-going operations and new projects.
109. 109 Develop Standard IQ Protocol Write One IQ Protocol that is General and has a Method of Being Uniquely Identified so Specific Attachments for Qualification can be Attached
Develop Appropriate Checkout Sheets
Accept Vendor Documentation
Accept Contractor Verification
110. 110 Documentation Clear, Concise Prose
Tables and Drawings, Rather than Words
Summaries not Narratives
Plagiarism Should Be Encouraged
Put Repetitive Elements in Procedures
Don’t Rewrite War and Peace
111. 111 Approvals Minimize the Number of Approvers
Maximum of 4-6
Must Include the “Quality Control Unit”
Approvers Must Have Technical Understanding
112. 112 Approach to IQ Verification The Appropriate Engineer to Walk Down and “Red Line” the P&IDs
Validation Personnel to Develop Checkout Sheets from Engineering Drawings and Specifications
Vendor Documentation for Their Specific Required Specifications of Their System or Equipment
Contactor Verification of Installation per Vendor Requirements or Drawings
113. 113 Approach to IQ Verification Terminations and Connections Verified per Contractor Verification Forms or Checkout Sheets
CM to Verifies the System was Checked and No Blind Flanges, Start Up Strainers or other Temporary Items were Found or were Identified as Necessary For OQ.
114. 114 Approach to IQ Verification CM verifies that all extraneous tags are removed - electrical and mechanical
CM verifies that the identification of all items is correct and completed
Proper safety and caution notices are placed on pressurized lines and rotating equipment. Restriction notices for the module or System are in place.
115. 115 Approach to IQ Verification Overall installation was found correct:
Correct Ordering
Inlet/Outlet Damping Distances (if applicable)
Accessibility for Operation
Accessibility for Maintenance
Dead Ends / Insertion Depth
Freedom for Expansion (No Stress)
All Internal Equipment Components Installed where Required
All Manual Equipment is Functional
116. 116 Develop Standard OQ Protocol Write One OQ Protocol for Each Type of Package that is General and Has a Method of being Uniquely Identified so Specific Attachments for Qualification can be Attached
Develop Appropriate Checkout Sheets
Follow the FAT Model
Define Test to Assure Operational Requirements are Met
117. 117 Transition IQ to OQ Verification by Validation of the Completion of IQ or Authority to Proceed with OQ
Pre-OQ Verifications
Calibration
Start-Up/Commissioning
Documentation Complete
Vendor Start-Up
Procedures Identified
Qualified Personnel Identified
Exceptions/Deviations Noted and Approved
118. 118 Pre-OQ Verification Report For Completion of the Building and/or Area and the Required Support Areas or Systems are Attached or Referenced in PRE-OQ Checkout Sheet.
Required Package Start-Up Preparation is Performed (If Applicable).
Cleaning of Area / Room and Equipment Externals is Completed.
Inspection of Equipment Internals is Completed (If Applicable).
An Appropriate Safety Inspection has been Performed and Found Acceptable for OQ Activities.
The Device Calibrations are Complete and the Calibration Data Documented in the Appropriate System.
119. 119 Pre-OQ Verification Confirmation of Availability of the Tag Checkout Forms, Loop Tuning Checkout Sheets and 72 Hour Motor Runs and Checkout Sheets.
BOPs To Be Tested are Identified, Downloaded and Ready to be Started.
BOP Requirement Specifications and Test Matrices are Available.
Sequence of BOPs to be Tested are Identified.
BOP Test Procedures are Available for Each "Typical" Package.
Partial Recipes - Water are Identified, Downloaded and Ready to be Started.
Synthetic Recipes - Water are Identified, Downloaded and Ready to be Started
120. 120 Calibration Calibration of all Instruments which Require Calibration will be Performed.
A List by Module or System of all Instruments that Must be Calibrated which belong to the Package will be Prepared and Attached to the Package OQ Protocol.
This List will Identify the Instruments which Require Calibration as well as the Applicable Calibration SOPs.
Confirmed on Package Pre-OQ
121. 121 Start-Up/Commissioning All Systems and Equipment in a Package to be Started Up will be Identified.
Procedures to Perform Start-Up/Commissioning will be Written and Approved
Adjustments and/or Modifications will be Allowed And Documented Appropriately
122. 122 Vendor Start-Up Vendor Start-Up Procedures and Requirements will be Met and Verified by CM
Documentation will be Part of the Protocol
123. 123 Procedures Written Procedures for all Operational Functions will be in Place in at Least Draft Form before OQ Begins
Approved Procedures for Support Packages will be in Place Before Operational or Follow on Packages Proceed with OQ
124. 124 Qualified personnel Personnel Performing the Required Functions will have Verification of Their Ability to do the Qualification Work.
Training Records
Education
Resumes
Contractor Certifications
Etc.
125. 125 Tag Checkout The main objective of tag checkout is to test the communication and correctness of an input signal from a calibrated field device to the computer console and an output signal from the computer console to a calibrated field device.
Specific procedures are developed for Tag Checking of Instruments which are DCS or FMS controlled. Depending on the Instrument type, one of the following forms will be completed for each of the Instrument Tags:
- "VFD controlled motors";
- "Analog Inputs";
- "Analog Outputs";
- "Digital Inputs";
- "Digital Outputs";
- "One Speed Motor";
- "Two speed Motor".
The appropriate procedure to follow when performing Tag Checkouts, is described on the forms mentioned above.
A list of instruments to be tag checked will be attached to the package OQ Protocol.
The completion of Instrument tag checkout for a specific package is confirmed on package OQ Checkout Sheet.
126. 126 Construction Cleaning - Process & Facility A reference to the construction cleaning - process and facility (external equipment, pipe lines, vessel internals, miscellaneous construction equipment removed, etc...) applicable to the proposed package will be confirmed on the OQ Checkout Sheet.
The cleaning will be completed by the responsible contractors and verified by Construction Management/Start up.
127. 127 Loop Tuning The objective of loop tuning is to adjust a controller in order to make it able to maintain process variable stability under any combination of internal or external disturbances which may reasonably occur to the process.
The control loops will be tuned according to a SOP and may be performed more than once and at several stages of OQ in order to fine tune the controller.
A list of the controllers to be tuned will be attached to the package OQ Protocol.
128. 128 Execution Use Appropriately Trained Operational Personnel
Use Validation Teams for Larger Tasks
Maintain Some Internal Expertise
Use Contractors for Peak Demand and Special Tasks
Use Prepared Forms For Data Gathering
129. 129 BOP Testing Each BOP for each typical package will be operated and tested for proper performance within the package.
Where possible, the performance of the individual components of the package or module will be tested using water as the process media.
Documentation of performance will be recorded, where possible, via the DCS and acceptance provided by a sign off, on hard copy, by the performer and the user, if required.
Additional testing results will also be recorded directly on the testing procedure being part of the OQ Protocol for that package.
The package specific OQ Protocol will list the BOPs that are applicable to the package.
The documentation of testing compliance is reported on OQ Checkout Sheet and confirmed on OQ Summary
130. 130 72 Hour Test The 72 hour run in of rotating equipment will be performed per a specific SOP.
Results will be documented on the appropriate checkout sheet performed for recording 72 hour test.
The documentation of testing compliance is reported on OQ Checkout Sheet and confirmed on OQ Summary
131. 131 Partial Recipe Testing - Water Each Partial Recipe for the package will be operated and tuned for proper performance within the package.
The capacity of the components of the package will be tested for the ranges outlined in the specifications.
These ranges will be listed in the package OQ Protocol.
Documentation of performance will be recorded, where possible, via the DCS and acceptance provided by a sign off, on hard copy, by the qualification team , if required.
The documentation of testing compliance is reported on OQ Checkout Sheet and confirmed on OQ Summary.
Additional testing results will also be recorded directly on the testing procedure being part of the OQ Protocol for that package.
132. 132 OQ Checkout and Summary Complete the Package OQ Checkout Sheet which documents the hand over of the package from the qualification team to the user in order to certify:
The required package preparation for operational condition runs is performed.
Equipment calibration is complete and calibration data documented.
Tag checkout is completed and documented
Loop tuning is completed and documented
72 hour run test is completed and documented.
Water batch testing is completed and documented.
Safety inspection has been performed and found acceptable for operational runs.
Passivation procedure is available (if applicable).
Availability of instrument calibration SOPs is noted and referenced within the system.
Availability of maintenance SOPs is noted and referenced within the system.
Availability of the operating procedures is noted.
Specific sequence of BOPs to be tested for operational runs is identified.
Partial recipes for operational runs are identified, downloaded and ready to be started.
Availability of approved cleaning SOPs are noted for rooms and equipment which are not cleaned through automated controlled cleaning procedures and that the cleaning is performed.
133. 133 Methods of Performing Validation The above methodology was followed in detail to achieve an efficiency that allowed the facility to quickly start production and to expand the operations under controlled procedures.
134. 134 Part Seven:�Technical Content Requirements
135. 135 Process Parameters Diagram
136. 136 Validation Protocol Provide an outline of the validation effort
Include a clear definition of what will be validated
Is uniquely identified
Is dated
Approved by competent individuals in responsible areas
Are suitable for review by regulatory agencies Introduction/abstract
Description of process or system
Responsibilities
Challenge criteria
Acceptance criteria
Append data sheets, etc.
137. 137 Operational Qualification (OQ) OQ documents that the equipment:
Can operate as designed and intended
Is capable of repeatable operation over the entire operating range of process variables
OQ implemented after equipment has been started up or commissioned
138. 138 PAR Approach To Process Validation This is perhaps the most important concept in process validation. It is necessary for the developmental function to participate fully in guiding the validation on the production scale.
In the developmental phase, the control parameters which are critical to the process and the quality of the product are determined. Some of these, such as solvent quality, agitation rate, etc. may be fixed. Others may be variable over an acceptable range. This is important to the production scale , so that production has the greatest degree of flexibility in running the process. Development should attempt to learn as much about the effects of the process control parameters as possible. Edge of failure need not be reached as long as a firm understanding of the PAR is gained.
In addition, developmental work is needed to explore the effects that the process parameters have on each other. Does running at high temperature and high pH have a detrimental effect, whereas independently they are OK?This is perhaps the most important concept in process validation. It is necessary for the developmental function to participate fully in guiding the validation on the production scale.
In the developmental phase, the control parameters which are critical to the process and the quality of the product are determined. Some of these, such as solvent quality, agitation rate, etc. may be fixed. Others may be variable over an acceptable range. This is important to the production scale , so that production has the greatest degree of flexibility in running the process. Development should attempt to learn as much about the effects of the process control parameters as possible. Edge of failure need not be reached as long as a firm understanding of the PAR is gained.
In addition, developmental work is needed to explore the effects that the process parameters have on each other. Does running at high temperature and high pH have a detrimental effect, whereas independently they are OK?
139. 139 Process Qualification (PQ) PQ documents that:
Processes operate as required at the normal operating limits of critical parameters
Systems operate consistently and reliably
Appropriate challenges are employed
140. 140 Automation / System Integration Business Management Automation = SAP, MRP, People softBusiness Management Automation = SAP, MRP, People soft
141. 141 IQ Verification
Engineering Documentation
Engineering Drawings
Equipment and Filter List
Instrument List and Calibration
Construction Completion
SOPs Review
Room Finishes (optional)
Lubricant List
Trainings
Preventive Maintenance Program
Variance Summary Report OQ Verification
Control System Checkouts
Room Air Changes
Power Failure
Air Flow Direction
Air Make-up
HEPA Filter Integrity Test Report
Air Balance Report
Monitoring of Environmental Conditions
Qualification Test Equipment and Instruments
Variance Summary Report
142. 142 IQ Verification
Engineering Documentation
Engineering Drawings
Utilities List
Dust Collectors Inspection
Spare Parts List
SOPs Reviews
Preventive Maintenance Program
Instruments Calibration / Certification Records
Variance Summary Report OQ Verification
Alarm System Verification
Dust Collectors Motors Checkout
Back Flow Prevention
Dust Collection Capture Velocity at Use Point
Variance Summary Report
143. 143 IQ Verification
Engineering Drawings
Engineering Specifications
Room Design Verification
Utilities List
Preventive Maintenance Program
Variance Summary Report OQ Verification
Checkout: Drawings, Specification, Instrument, Equipment and Utilities
Room Layout is effective for material and personnel flow
Room Surfaces meet the specifications and designed to be easily sanitized and clean
Floor,Walls and Ceiling finish meet specifications
Variance Summary Report
144. 144 PQ Verification
Evaluation and Selection of Chemical Solution or Agent
Determination of label validity or concentration
Application of analytical methods
Chemical Solution or Agent residual
Compatibility with surfaces
Methods of cleaning application
Frequency of use
Effectiveness and Reproducibility of the cleaning process
Non-toxic Chemical Solution or Agent Documentation of the obtained results
SOPs preparation
Training
Variance Summary Report
145. 145 IQ Verification
Engineering Documentation
Equipment and Filter List
Instrument List and Calibrations
Lubricant List
Utilities
SOPs & Trainings Review
Preventive Maintenance Program
Variance Summary Report OQ Verification
Control System Checkouts
Pump Checkouts
Filter Integrity Test Report
System Operational Data
Qualification Test Equipment and Instruments
Variance Summary Report
PQ Verification
Bioburden & Endotoxin
Washing Test & Inspection
Qualification Test Equipment
Variance Summary Report
146. 146 IQ Verification
Engineering Documentation
Equipment and Filter List
Instrument List and Calibrations
Lubricant List
Material Product Contact
Utilities
SOPs & Trainings Review
Preventive Maintenance Program
Variance Summary Report OQ Verification
Control System Checkouts
Equipment Operational Data
Qualification Test Equipment and Instruments
Variance Summary Report
PQ Verification
Heat Distribution Cycles
Heat Penetration Cycles
Process Parameters
Load Configuration and Thermocouple Placement
Qualification Test Equipment
Variance Summary Report
147. 147 IQ Verification
Engineering Documentation
Equipment and Filter List
Instrument List and Calibrations
Lubricant List
Material Product Contact
Utilities
SOPs & Trainings Review
Preventive Maintenance Program
Variance Summary Report OQ Verification
Control System Checkouts
Sensors Operation
Equipment Operational Data
Qualification Test Equipment and Instruments
Variance Summary Report
PQ Verification
Process Parameters
Particulate Test
Product in process checkout
Qualification Test Equipment
Variance Summary Report
148. 148 IQ Verification
Engineering Documentation
Equipment and Filter List
Instrument List and Calibrations
Lubricant List
Material Product Contact
Utilities
SOPs & Trainings Review
Preventive Maintenance Program
Variance Summary Report OQ Verification
Control System Checkouts
Sensors Operation
Equipment Operational Data
Qualification Test Equipment and Instruments
Variance Summary Report
PQ Verification
Leak Test & Inspection
Product in process checkout
Particulate Test
Qualification Test Equipment
Variance Summary Report
149. 149 IQ Verification
Engineering Documentation
Equipment and Filter List
Instrument List and Calibrations
Lubricant List
Material Product Contact
Utilities
SOPs & Trainings Review
Preventive Maintenance Program
Variance Summary Report OQ Verification
Control System Checkouts
Sensors Operation
Equipment Operational Data
Qualification Test Equipment and Instruments
Variance Summary Report
PQ Verification
Torque Test & Inspection
Product in process checkout
Qualification Test Equipment
Variance Summary Report
150. 150 IQ Verification
Engineering Documentation
Equipment and Filter List
Instrument List and Calibrations
Lubricant List
Material Product Contact
Utilities
SOPs & Trainings Review
Preventive Maintenance Program
Variance Summary Report OQ Verification
Control System Checkouts
Equipment Operational Data
Qualification Test Equipment and Instruments
Variance Summary Report
151. 151 IQ Verification
Engineering Documentation
Equipment List
Utilities
SOPs & Trainings Review
Preventive Maintenance Program
Variance Summary Report OQ Verification
Control System Checkouts
Equipment Operational Data
Qualification Test Equipment and Instruments
Variance Summary Report
152. 152 IQ Verification
Engineering Documentation
Equipment List
Utilities
SOPs & Trainings Review
Preventive Maintenance Program
Variance Summary Report OQ Verification
Control System Checkouts
Equipment Operational Data
Qualification Test Equipment and Instruments
Variance Summary Report
153. 153 IQ Verification
Station Drawings
Utilities
Environmental Conditions
Inspector List
SOPs & Trainings Review
Variance Summary Report OQ Verification
Sampling Plan
Inspection Test
Data Analysis
Qualification Test Equipment and Instruments
Variance Summary Report
154. 154 IQ Verification
Engineering Documentation
Material in Product Contact
Engineering Drawings
Equipment and Filter List
Utilities
SOPs & Trainings Review
Preventive Maintenance Program
Variance Summary Report OQ Verification
Control System Checkouts
Agitator Checkout and minimum operational volume
Pump and Spray ball Checkout
Pressure and Vacuum Test
Heating and Cooling Test
Filter Integrity Test Report
Qualification Test Equipment and Instruments
Variance Summary Report
155. 155 IQ Verification
Engineering Documentation
Equipment and Filter List
Material in Product Contact
Lubricant List
Instrument & Calibration List
Utilities
Loop Verification
SOPs & Trainings Review
Piping System Cleaning and Flushing Checklist
Welding and Passivation Reports
Variance Summary Report OQ Verification
Piping System Leak Test
Application Software Audit
Security Capability
Emergency Power
Cycle Control Studies
Cycle Monitoring
Qualification Test Equipment and Instruments
Variance Summary Report
PQ Verification
Cycle Monitoring and Microbial Test
Detergent & Active Ingredient residue
Variance Summary Report
156. 156 IQ Verification
Engineering Documentation
Equipment and Filter List
Material in Product Contact
Lubricant List
Utilization List
Instrument & Calibration List
Utilities
SOPs & Trainings Review
Piping System Cleaning and Flushing Checklist
Passivation Reports
Piping Leak Test Report
Variance Summary Report OQ Verification
SIP OQ Log Sheet
Digistrip Data Logger Recording
SIP Station Diagram
Qualification Test Equipment and Instruments
Variance Summary Report
PQ Verification
SIP Cycle Monitoring
Temperature Analysis and Microbial Checkout
Clean Steam Analysis
Qualification Test Equipment and Instruments
Variance Summary Report
157. 157 IQ Verification
Engineering Documentation
Engineering Drawings
Electrical Utility
SOPs Review
Environmental Conditions
Installation Verification
Configuration & Wiring Checkout
Software Verification
Radio Frequency and Electromagnetic Interference Tests
Variance Summary Report OQ Verification
Functional Verification
Alarm Test
Security Test
Input/Output Verification
Power Failure Test
Reports Verification
Load and Backup Test
Variance Summary Report
158. 158 IQ Verification
Engineering Documentation
Engineering Drawings
Equipment and Filter List
Lubricant List
Material Product Contact
Utilities
SOPs Review
Training Records
Variance Summary Report OQ Verification
Controls Verification
Instrument Checkout
Functional Verification
Alarm Test
Power Failure Test
Operational Settings Documentation
Variance Summary Report
159. 159 IQ Verification
System Related Manuals
Critical Equipment Installation
Configuration Verification
Power & Fusing
Hardware Maintenance
Software Program Version
Software Configuration
SOPs Review
System Securities
Software Backup and Archiving Provisions
Variance Summary Report OQ Verification
Functional Branching Test
Functional Key Availability and Operational Test
Field Specification Tests
Power Failure Test
Printing Verification
Variance Summary Report
160. 160 PQ Verification
Setting Parameters Checkout
Speed Verification
Reject Station Test
Equipment Functional Verification
Sampling Plan
Inspection
Qualification Equipment and Instruments
Variance Summary Report
161. 161 IQ Verification
Engineering Documentation
Engineering Drawings
Equipment List
Instrument List and Calibration
Lubricant List
Electrical Utility
SOPs Review
Variance Summary Report OQ Verification
Control Verification
Instrument Checkout
Digistrip Data Logger Recording
Qualification Test Equipment and Instruments
Variance Summary Report
162. 162 IQ Verification
Engineering Documentation
Engineering Drawings
Equipment List
Instrument List and Calibration
Electrical Utility
SOPs Review
Variance Summary Report OQ Verification
Control Verification
Instrument Checkout
Digistrip Data Logger Recording
Qualification Test Equipment and Instruments
Variance Summary Report
163. 163 IQ Verification
Engineering Documentation
Construction Completion
Engineering Drawings
Equipment and Filter List
Instruments List
SOPs Reviews
Preventive Maintenance Program
Variance Summary Report OQ Verification
Qualification Test Equipment and Instruments
Use Points Utilization List
Use Point Pressure Testing
Operational Performance Checkout
System Functional Checkout
Hydrocarbons Verification Test
Dew Point Record
Viable and Non Viable Particulate Test
Variance Summary Report
164. 164 IQ Verification
Construction Completion
Engineering Documentation
Engineering Drawings
Equipment and Filter List Specifications
Instruments List and Calibrations
Spare Parts List
SOPs Review
Preventive Maintenance Program
Trainings
Variance Summary Report OQ Verification
Major Equipment Performance Checkout
Controls Verification
Instrument Functionality Verification
Piping Cleaning System and Flushing
Steam Supply Pressure Verification
Alarm & Interlock System Verification
Test Supply for all Use Points
Steam Quality Verification
Variance Summary Report
165. 165 IQ Verification
Engineering Documentation
Engineering Drawings
Equipment and Filter List
Instrument List and Calibrations
Lubricant List
Construction Completion
Utilities
SOPs & Trainings Review
In Process Maintenance List
Preventive Maintenance Program
Variance Summary Report OQ Verification
Control System Checkouts
Utilization List
Pump Checkouts
Filter Integrity Test Report
System and Loop Operational Data and Monitoring
Qualification Test Equipment and Instruments
Variance Summary Report
PQ Verification
Sampling Plan
Water Quality Report
Variance Summary Report
166. 166 IQ Verification
Engineering Documentation
Engineering Drawings
Major Equipment Specification & Calibrations
Lubricant List
Filters List and Specifications
Utilities List
SOPs Trainings & Review
Preventive Maintenance Program
Variance Summary Report OQ Verification
Control System Checkouts
Major Equipment Checkout
Filter Integrity Test Report
Sanitization Program
Variance Summary Report
PQ Verification
Sampling Plan
Water Quality Verification
Variance Summary Report
167. 167 IQ Verification
Construction Completion
Engineering Documentation
Engineering Drawings
Utilities List
Equipment Specifications
Spare Parts List
Instruments Calibrations
SOPs Reviews
Preventive Maintenance Program
Variance Summary Report OQ Verification
Utilization List
System Operational Data and Monitoring
Qualification Test for Equipment and Instruments
Alarms Verification
System Flush Verification
Use Points Sampling Plan
Quality Tests
Variance Summary Report
168. 168 Chromatography –�Validation Considerations
Column Packing
Pressure
Flow Rate
pH
Buffer Concentration
HETP
Efficiency
169. 169 Bioreactions - Validation Considerations
Cell Line Integrity
Temperature
pH
Agitation
Dissolved Oxygen
Maintenance Of Sterility
Mutation
170. 170 Organic Synthesis Design & Construction
-Reactor
- Pumps
-Agitator
-Materials Of Construction
-Controls
-Jacket Services
-Venting
-Cleaning Operation
-Temperature
-Agitation Rate
-Pressure
-Raw Materials
-Step Times
-Concentration of Reagents
-Yield
-Impurities
171. 171 Purification and Drying Operation
-Agitation Rate
-Time
-Temperature
-Ph
-Drying Temperature Distribution
-Dryer Air Flow
-Activated Carbon Type & Mesh
172. 172 Multi-product Facility: Areas of Concern People and Material Flow
Cross-contamination
Cleaning Validation
Cleanability
Environmental Contamination
Lubricant Contamination
Housekeeping Written Procedures/Records
Equipment Qualification
Technology Transfer
Process Validation
Analytical Method Validation
API Impurity Profiles (Identify > 0.1%)
Computer System Validation
173. 173 People Must Be Considered In Design Phase
Presented In Master Plan
Direction Of Movement
Validated Gowning Procedures
Documentation Of Training
174. 174 Material Flow Clean Vs. "Dirty" Corridors
Methods For Moving Equipment
Storage and Staging Areas
Decontamination Areas
Tagging/Labeling Procedures
175. 175 Equipment - Primarily a Cleaning Validation Concern, But Want to Ensure Gasket Materials, O-rings, Etc,. will not be a Source for Cross -Contamination
Utilities- Multipurpose
HVAC - Easiest Way for Contaminants to be Dispersed Throughout a Facility Cross-Contamination
176. 176 Cross-Contamination: Utilities Direct Connection
Check Valves
Backflow Preventers
Interlocked Valves
Alarms Indirect Connections
Proper Safeguards
SOPs
177. 177 Part Eight: Execution
178. 178 HVAC Validation IQ - During Construction Phase
OQ
TAB Report
Retest Critical Areas
DOP Testing
Laminar Flow
Pressure Differentials
BAS (Separate Validation Program?)
Environmental Baseline
179. 179 Environmental Baseline Test HVAC System Operation As An Integrated System
Temperature, Humidity *
Bioburden *
Non Biological Particulate
30 Days (Typical) - OQ
30 Days (Typical) - PQ
180. 180 Air System Qualification Pressure Differential
Air Changes
Flow Patterns
Sound Level
Lighting
Temperature
Relative Humidity
HEPA Filter Qualification
Non-viable Counts
181. 181 HEPA Filter Qualification DOP or Alternative testing
Velocity Testing
Recommended Practices:
- Laminar Flow
- Testing Clean Rooms
- HEPA Filters Dioctyl phthalate aerosol particle size is around 0.3 micrometers. It is the traditional material used to challenge HEPA filters, which are better than 99.9% effective in removing particles of this size. This activity requires a scanning photometer is usually left to specialists.
Velocity testing should follow IES standards. These require a HEPA filter to be checked within one foot of its face, at several different spots.
The IES standards listed are available from the: Institute for Environmental Sciences
Mount Prospect, IL 60056
312-255-1561
It is valuable to understand these and to require certifying contractors to comply with them.Dioctyl phthalate aerosol particle size is around 0.3 micrometers. It is the traditional material used to challenge HEPA filters, which are better than 99.9% effective in removing particles of this size. This activity requires a scanning photometer is usually left to specialists.
Velocity testing should follow IES standards. These require a HEPA filter to be checked within one foot of its face, at several different spots.
The IES standards listed are available from the: Institute for Environmental Sciences
Mount Prospect, IL 60056
312-255-1561
It is valuable to understand these and to require certifying contractors to comply with them.
182. 182 Non-viable monitoring hiac-royco
climet
met-one
particle measurement systems
etc.
183. 183 Viable Organisms Monitoring Slit To Agar
Swabs
RCS Sampler
Settling Plates
Anderson Sampler
Sartorius Sampler
Rodac Plates
184. 184 Cleaning Validation GOAL: Confirm the effectiveness of the cleaning procedures
CIP (Clean In Place)
Manual Cleaning
185. 185 What Items are being Removed Active Ingredients
Decomposition Products
Excipients
Detergent/Cleaning Agents
Microbial Contamination
Endotoxin
Particulate
Sanitizing Agents
Lubricants
186. 186
187. 187 Sampling Methods Swabs in Open Areas
Swabs in Inaccessible Areas
Step Rinses
Final Rinse
Placebo Product
Next Production Lot
Visual Examination
188. 188 Priority Of Cleaning Validation All Products
Least Soluble
Most Potent
Most Toxic
Least Soluble and Most Potent (or Most Toxic)
Hardest To Clean
Family Approach
New Products
189. 189 Limitation Of Rinse Sampling Only Valid When Applied To Highly Soluble Contaminant
Requires Rigorous Qualification of Cleaning Solution
Requires Rigorous Qualification of Mechanical Systems (Especially Spray Coverage)
“Baby in the Bathwater”
190. 190 “Baby in the Bathwater” The Cleanliness of the Bathwater (rinse sample) may not be Indicative of the Cleanliness of the Baby
Contaminants may be Poorly Soluble in the Cleaning Solution
Cleaning Solution may not Contact all Contaminated Areas
Both Cleaning and Evaluation Methods may be Inadequate
191. 191 Permissible Residuals LTD - Lowest Therapeutic Dose
TIEL - Toxicologically Insignificant Exposure Limit
PIEL - Pharmacologically Insignificant Exposure Limit
Lowest Marketed Dose
NOEL - No Observable Effect Limit
EPA, OSHA, USDA, Other Published Limits
Log Reduction
“None Detectable”
192. 192 WFI Design Recommendations Polished Stainless
Proper Piping System Sloping
Machine Welding
Flush Type Diaphragm Seals
Rupture Discs
Diaphragm Valves
Temperature Record For Critical Points
WFI Pressure Higher than Cooling Water Pressure
Low Flow and Low Temperature Alarms
"6d Rule"
Turbulent Flow Of these, there are some differences for Purified Water. The WFI standards consider the highly corrosive nature of hot pure water. Since Purified water is ambient, design specs are not so stringent. Nevertheless, the quality of installation for Purified Water should not be taken lightly.
Polished stainless tubing is the recommended material. Purified Water systems have made use of sanitary design plastic systems (e.g.. , PVDF, SaniTech) PVC is not recommended and industrial PE and other plasticsOf these, there are some differences for Purified Water. The WFI standards consider the highly corrosive nature of hot pure water. Since Purified water is ambient, design specs are not so stringent. Nevertheless, the quality of installation for Purified Water should not be taken lightly.
Polished stainless tubing is the recommended material. Purified Water systems have made use of sanitary design plastic systems (e.g.. , PVDF, SaniTech) PVC is not recommended and industrial PE and other plastics
193. 193 The '6d' Rule "The system shall be constructed with minimal distance (no greater than six pipe diameters) as measured from the end of the leg to the point of connection to the adjoining header.”
194. 194 Turbulence "Rule Of Thumb" 5 Ft./Sec. Applies To Lines 1" - 2" Diameter
Design Recommendation to Ensure Adequate Turbulence Reynolds Number at least 20,000 Turbulence, as measured by Reynolds number, is important because of the difference in flow pattern between turbulent and laminar flow. The fluid velocity profile in laminar flow is parabolic, that is flow is fastest in the center of the pipe, diminishing as it approaches the walls. Along the walls there is a region of virtual stagnation, known as a boundary layer, which can harbor microbial growth. This then becomes a "biofilm".
In turbulent flow the velocity profile is flat, with velocity near the walls nearly the same as in the center. In addition, turbulent flow is highly mixed, with eddies and currents across the profile. The boundary layer is very thin, inadequate to harbor microorganisms.
Turbulence may be calculated by measuring velocity with a flow meter, or by estimating velocity from the pump curve.
Cooling is a special problem with hot WFI. It is important that terminal heat exchangers, as shown in the first figure following, do not act as dead legs. Thus they must be designed for a constant flow, through, when not in use.
The second figure shows a system where a cold loop is kept in constant use. Note that the storage tank is maintained hot. The cold loop is affixed with a dual purpose heat exchanger to heat the loop to sanitizing temperatures on a regular basis, when not in use. Experience has shown that a daily sanitization of four hours at 80 C is adequate to maintain microbial quality. It is not necessary to dump the water in the cold loop under these conditions.
Turbulence, as measured by Reynolds number, is important because of the difference in flow pattern between turbulent and laminar flow. The fluid velocity profile in laminar flow is parabolic, that is flow is fastest in the center of the pipe, diminishing as it approaches the walls. Along the walls there is a region of virtual stagnation, known as a boundary layer, which can harbor microbial growth. This then becomes a "biofilm".
In turbulent flow the velocity profile is flat, with velocity near the walls nearly the same as in the center. In addition, turbulent flow is highly mixed, with eddies and currents across the profile. The boundary layer is very thin, inadequate to harbor microorganisms.
Turbulence may be calculated by measuring velocity with a flow meter, or by estimating velocity from the pump curve.
Cooling is a special problem with hot WFI. It is important that terminal heat exchangers, as shown in the first figure following, do not act as dead legs. Thus they must be designed for a constant flow, through, when not in use.
The second figure shows a system where a cold loop is kept in constant use. Note that the storage tank is maintained hot. The cold loop is affixed with a dual purpose heat exchanger to heat the loop to sanitizing temperatures on a regular basis, when not in use. Experience has shown that a daily sanitization of four hours at 80 C is adequate to maintain microbial quality. It is not necessary to dump the water in the cold loop under these conditions.
195. 195 Water System Operational Qualification Capacity
Resistivity
Feedwater Quality
Temperature Control
Flow Rate
Frequency Of Sanitization
Frequency Of Regeneration
196. 196 Water System Performance Qualification Minimum 30 Day Sampling (60 Days Referred)
Every Use Point Once/Wk
Sample Every Working Day
Minimum Allowable Operating Conditions
Temperature
Sanitization / Regeneration Frequency
Emphasis On Micro Testing
Establish Action / Alert Limits
197. 197 Execution Use Calibrates equipment (both on the System and the Validation/Commissioning Testing Equipment)
Use process instruments
Use qualified personnel and procedures
The Validation is intended to prove the Reliability and Consistency of the Process not to be a Detailed Academic Study.
198. 198 Part Nine: Flow of Work
199. 199 Integrated E,P,C,V,SI Timeline Research and Development: Process Requirements, Critical Process Parameters, Cleaning Toxicology, Analytical Testing
Conceptual Design: Project Approach and Integration Plan
Basic Engineering: Review of critical systems and philosophies
Detailed Engineering: Validation/GMP Input, Procurement, Vendor documents, Specifications, Acceptance Criteria, P/Os, Drawings, FAT & VTOP
Construction: FAT/SAT, Training, Installation Qualification, Ongoing Audit/Review, SOPs, “As-built Drawings”Research and Development: Process Requirements, Critical Process Parameters, Cleaning Toxicology, Analytical Testing
Conceptual Design: Project Approach and Integration Plan
Basic Engineering: Review of critical systems and philosophies
Detailed Engineering: Validation/GMP Input, Procurement, Vendor documents, Specifications, Acceptance Criteria, P/Os, Drawings, FAT & VTOP
Construction: FAT/SAT, Training, Installation Qualification, Ongoing Audit/Review, SOPs, “As-built Drawings”
200. 200 Flow of work Research Data/Product Specifications and Requirements
Facility and Equipment Specifications and Requirements
Validation Master Planning
Writing Protocols
Execution of Protocols
Summary Reports
Maintenance of Validation
201. 201 Summary Reports
202. 202 Evaluating the Data
203. 203 Summary reports A written report that summarizes the validation study, including any data gathered under amendments to the protocol. Any out of parameter data should be identified and fully explained. If data is acceptable, the summary report is approved or “certified” by the same departments (preferably individuals) that approved the protocol.
204. 204 Summary reports Data, Analysis and results – (Procedure, documentation, Acceptance Criteria, IQ, OQ and/or PQ Analysis) The procedure followed to validate the system will be briefly described and the results obtained summarized. Usually the IQ analysis will be listed using a tabulated form that reflects the results. The OQ and/or PQ analysis must be written in concise detailed form (tabulated, results list, graphs, etc.) and the specific results compared with the acceptance criteria will be presented. In addition, any deviations in terms of procedure or results from those originally defined in the protocol will be documented and discussed as to their impact upon the validation study.
205. 205 Summary reports It is recommended that all Validation Summary Reports will be in the first section of the validation package file or Binder. The validation package binder will have the following sections:
First Section - Summary Report
Second Section - IQ/OQ/PQ Protocol (original written document)
Third Section - IQ/OQ/PQ Execution (raw data and documentation)
Fourth Section - Standard Operating Procedures (when applicable)
Fifth Section - General Additional Information (when applicable)
206. 206 Storage and Usage
207. 207 Where Is The Validation Data Kept?
208. 208 Documentation: Records of . . .
209. 209 Storage and Usage Controlled for Security
Available for Review
Part of the Operations
210. 210 Part Ten: Change Control
211. 211 Change Control "Who needs it? The process is validated. Just read the report."
Change Control Necessary To Perpetuate Validation
When should change control begin?
- After the validation report is approved?
- After qualification?
- Before qualification begins? A workable way to institute change control is to use it informally during qualification. As such, it must be strictly controlled by the validation team. The informal program does not require the same level of review as in an operating plant. Any changes made during IQ or OQ will be documented in the validation report and on "as built" drawings. These, of course, will be approved.
Once qualification is complete, the formal change control program may take effect. A workable way to institute change control is to use it informally during qualification. As such, it must be strictly controlled by the validation team. The informal program does not require the same level of review as in an operating plant. Any changes made during IQ or OQ will be documented in the validation report and on "as built" drawings. These, of course, will be approved.
Once qualification is complete, the formal change control program may take effect.
212. 212 Planned Changes Propose Change, Document Reason (Manufacturing, Development, Etc.)
File Formal Request
Determine Need For Validation Of Process With Change Implemented
Implement Change
Execute and Report Validation Testing
Review and Approve
Update Drawings, SOPs and Operating Records
213. 213 Emergency Changes Only To Save Product In Process
Impound Product Pending Evaluation Of Change
Document Change - Formal Request Form
Determine Need For Validation Of Change
Determine If Change Should Be Permanent
Validation Testing, If Necessary
Accept Or Reject Impounded Product
Update Drawings and Procedures, As Required Responsibility for making emergency changes must be assigned in an SOP. Like for like replacements are not considered changes.
An example change control SOP is included. Change control must cover process, equipment and material changes.Responsibility for making emergency changes must be assigned in an SOP. Like for like replacements are not considered changes.
An example change control SOP is included. Change control must cover process, equipment and material changes.
214. 214 Change Control Systems Needed To Assure That :
All Changes Are Reviewed and Approved
Changes Potentially Affecting Product Specifications, Controls, and/or Processing Parameters Are Reacted to Appropriately
No Unintentional Changes Are Made
215. 215 Change Control Change =
A Planned or Unplanned Alteration or Replacement of:
Buildings/Facilities
Equipment
Production Process Controls and Procedures
Storage & Distribution Procedures
Regulatory Commitments
Master Formulas Etc.
216. 216 Change Control Substances
Raw Materials
Synthesis
Purification
Solvents
217. 217 Change Control Products
Excipients
Equipment Operating Principles
218. 218
Master & Batch Formulas
Sops - Written Procedure
Specifications (Changes beyond filed/validated parameters)
Test Procedures
219. 219 Change Control An Effective System Facilitates Change in Support of Continuous Improvement.
Assures Change is Thoroughly Reviewed and Documented in a Traceable Manner, Providing a Complete Historical Record
220. 220 Change Control Changes Made Outside of a Change Control Process May Result in Processes and/or Products Outside of:
Validated Ranges
Application Commitments
Bioburden Limits
New (Undocumented) Process
221. 221 Change Control Require Approval of Authorized Personnel
21CFR211.22(c) Quality Unit Responsible
222. 222 Change Control A Written Change Control Procedure Is Required
All Changes Must Be Documented
System Should Manage All Documents That Control Operations and Quality Functions
Best to Tie in Annual Reviews and Internal Audits
223. 223 Establish Change Control Procedures Identify and Address Significant Process Changes
Equipment
SOPs
Manufacturing Instructions
Environment
Any Aspect That May Affect the State of the Process All of these items are addressed through the change control but not necessarily in one procedure.All of these items are addressed through the change control but not necessarily in one procedure.
224. 224 Maintaining a Validated Process Proposed Changes to CGMPs Link Change Control With Revalidation
225. 225 Maintaining a Validated Process Process Validation - Establish Change Control Procedures
Identify and Address Significant Process Changes
Equipment
SOPs
Manufacturing Instructions
Environment
Any Aspect that May Affect the State of the Process
226. 226 PROCESS VALIDATION Document All Changes, Any Revalidation Performed and/or Rationale When Revalidation Deemed Unnecessary
Annual Process Reviews: Process Changes; Production Problems; Production Failures
227. 227 CGMP Annual Review 21 CFR 211.180(e)
Requires a Retrospective Overall Evaluation of the Adequacy of the Quality Standards
At Least Annually
Drug Products Directly Impacted
Drug Substances Impacted Per Preamble (1978)
228. 228 CGMP Annual Review ‘95 Retrospective Review
Representative # of Batches for Ea. Product
If Check Reveals an Adverse Quality Go to 100% Review
Computers Use Encouraged As a Compliment to Human Judgment & Intervention
229. 229 CGMP Annual Review ‘95 Proposed Revisions -Validation
Implement Revalidation Procedures Whenever There Are Changes, Including Reprocessing, That Could Affect Product Effectiveness or Characteristics
230. 230 Planned Changes Propose Change, Document Reason (Manufacturing, Development, Etc.)
File Formal Request
Determine Need For Validation Of Process With Change Implemented
Implement Change
Execute and Report Validation Testing
Review and Approve
Update Drawings, SOPs and Operating Records
231. 231 Emergency Changes Only To Save Product In Process
Impound Product Pending Evaluation Of Change
Document Change - Formal Request Form
Determine Need For Validation Of Change
Determine If Change Should Be Permanent
Validation Testing, If Necessary
Accept Or Reject Impounded Product
Update Drawings and Procedures, As Required Responsibility for making emergency changes must be assigned in an SOP. Like for like replacements are not considered changes.
An example change control SOP is included. Change control must cover process, equipment and material changes.Responsibility for making emergency changes must be assigned in an SOP. Like for like replacements are not considered changes.
An example change control SOP is included. Change control must cover process, equipment and material changes.
232. 232 Part Eleven: Revalidation, etc Calibration Program
Preventative Maintenance
Change Control Program
Software
Equipment Logs
SOPs
Regular QA Reviews
233. 233 Revalidation Validation of a Previously Validated System that has been Changed or Modified
Need to perform is Established in the Change Control Program
Event Based
Time Based
234. 234 Calibration Define Critical Process Variables
- Effect On Quality
- Effect On Yield Or Accountability
- Effect On Operator Safety
SOP
- General Procedure For Critical Variables
- Specific Procedure For Each Instrument
- Acceptable Range Definition
- Frequency Of Recalibration
- Exception Reporting
Traceability
- NIST Traceable Standards
- Recalibration Of Standards Definition of critical process variables is a joint effort involving development, QA, production, maintenance, etc. Always ask, "Does it effect the safety or efficacy of the product?"
Non-critical or reference instruments are usually not recorded and are not part of the batch record. They still need to be calibrated, but not against NIST standards, and not as often as critical instruments.
NIST is National Institute of Standards and Testing, formerly the Nation Bureau of Standards.
NIST traceable standards can be purchased or are available at contract laboratories who subscribe to NIST.Definition of critical process variables is a joint effort involving development, QA, production, maintenance, etc. Always ask, "Does it effect the safety or efficacy of the product?"
Non-critical or reference instruments are usually not recorded and are not part of the batch record. They still need to be calibrated, but not against NIST standards, and not as often as critical instruments.
NIST is National Institute of Standards and Testing, formerly the Nation Bureau of Standards.
NIST traceable standards can be purchased or are available at contract laboratories who subscribe to NIST.
235. 235 Essential Parts of a Calibration Program Statement Of Purpose and Scope
Criteria For Training Personnel
Written Calibration Procedures
Metrology Laboratory
Calibration Records
System For Instrument Recall For Calibration
Alert Procedure For Out Of Calibration Instruments
236. 236 Maintenance
237. 237 Preventative Maintenance
238. 238 Software Changes made to correct errors and faults in the software are corrective maintenance. Changes made to the software to improve the performance, maintainability, or other attributes of the software system are perfective maintenance. Software changes to make the software system usable in a changed environment are adaptive maintenance.
When changes are made to a software system, either during initial development or during post release maintenance, sufficient regression analysis and testing should be conducted to demonstrate that portions of the software not involved in the change were not adversely impacted. This is in addition to testing that evaluates the correctness of the implemented change(s).
239. 239 Equipment Logs A written record of major equipment cleaning, maintenance (except routine maintenance such as lubrication and adjustments), and use shall be included in individual equipment logs that show the date, time, product, and lot number of each batch processed.
If equipment is dedicated to manufacture of one product, then individual equipment logs are not required, provided that lots or batches of such product follow in numerical order and are manufactured in numerical sequence.
In cases where dedicated equipment is employed, the records of cleaning, maintenance, and use shall be part of the batch record.
The persons performing and double-checking the cleaning and maintenance shall date and sign or initial the log indicating that the work was performed. Entries in the log shall be in chronological order.
240. 240 SOPs Established to Ensure that Activities are Performed the Same Way at all Times
Periodic Review and Updating
Defined Approval Process, which includes Signatory Responsibility
Training on the SOP Content
A System of Archiving and Version Control
241. 241 Regular QA Reviews There shall be a quality control unit that shall have the responsibility and authority to approve or reject all components, drug product containers, closures, in-process materials, packaging material, labeling, and drug products, and the authority to review production records to assure that no errors have occurred or, if errors have occurred, that they have been fully investigated. The quality control unit shall be responsible for approving or rejecting drug products manufactured, processed, packed, or held under contract by another company.
242. 242 Regular QA Reviews All drug product production and control records, including those for packaging and labeling, shall be reviewed and approved by the quality control unit to determine compliance with all established, approved written procedures before a batch is released or distributed. Any unexplained discrepancy (including a percentage of theoretical yield exceeding the maximum or minimum percentages established in master production and control records) or the failure of a batch or any of its components to meet any of its specifications shall be thoroughly investigated, whether or not the batch has already been distributed. The investigation shall extend to other batches of the same drug product and other drug products that may have been associated with the specific failure or discrepancy. A written record of the investigation shall be made and shall include the conclusions and follow up.
243. 243 QA Reviews�21 CFR 211.180(e), General requirements �[Subpart J - Records and Reports] The cGMP regulations call for at least an annual evaluation of each drug product's quality standards to determine the need for changes in product specifications or manufacturing or control procedures.
The rule also requires firms to establish and follow written procedures for conducting those evaluations. Such an evaluation would be incomplete if the standard operating procedures for production and process controls were themselves not reviewed.
During Your establishment inspections, when auditing for compliance with section 211.180, determine if the firm has established, and is following, those evaluation procedures.
Also check to see if the procedures call for reviewing SOPs.
244. 244 Part Twelve: SHOWSTOPPERS
245. 245 SHOWSTOPPERS�General Quality Assurance The failure to have written procedures in place that have been approved by the quality unit.
Personnel performing critical operations who lack adequate training or experience
The failure to have a quality unit review for product release that includes review of failures, yield discrepancies, and deviations from procedures.
246. 246 SHOWSTOPPERS�Laboratory Controls Analytical method not validated
Not Stability Indicating
Related compounds not distinguished
Failure to test finished product
Stability program inadequate/not observed
Poor investigation of out of spec. findings
Analysts and/or equipment not qualified
Preservative/media effectiveness testing
247. 247 SHOWSTOPPERS�Facilities and Equipment No cleaning validation
No environmental monitoring
Obvious avenues of contamination
Equipment operating parameters not documented
Batch size exceeds capacity of equipment
Water and air systems not validated
248. 248 SHOWSTOPPERS�Production and Process Controls Process not validated
Components not independently check weighed
Process deviations and rejected products not adequately controlled/investigated
Yields not checked or investigated if out of range
Reprocessing without approval or control
249. 249 SHOWSTOPPERS�Packaging and Labeling Failure to check incoming labels against masters or specifications
Uncontrolled storage of labeling materials
Inadequate clearance of lines
Failure to electronically examine or visually double check finished package labeling, unless dedicated lines used
250. 250 SHOWSTOPPERS�Records and Reports Master/batch records that fail to include substantial information required by rules
Inability to trace products to materials
Failure to investigate complaints and provide appropriate follow up.
Missing records for critical operations
Falsification of production or control records
251. 251 Myth #1 Validation is a project related activity, which once completed can be largely ignored.
252. 252 Truth Validation is a journey,
not a destination!
Validation is best performed when it is practiced in a life-cycle model, using a cradle-to-grave approach. This provides the maximum benefit in compliance and finance.
253. 253 Myth #2 Validation can be accomplished by a small cadre of individuals with minimal intrusion on the rest of the organization
254. 254 Truth Validation is everyone’s job.
Each portion of the organization must contribute to the overall effort to insure success. No single organization unit can hope to satisfy all the requirements [and reap the benefits] alone.
255. 255 Myth #3 Too much is made of validation in this industry. If we are GMP compliant, follow procedures and make quality products, we shouldn’t have to spend as much time, money and energy on validation!
256. 256 Truth Absolutely correct.
Validation doesn’t replace the need to do any of those things, it merely helps us do them in a more structured way. It’s not the tail which is wagging the dog, it is part of the dog!
257. 257 Some References used by an API Manufacturer Guideline on General Principles & Process Validation FDA – May 1987
Pharmaceutical Inspection Convention (PIC) “Internationally Harmonized Guide for Active Pharmaceutical Ingredients” 9/97
ICH-Q7A
“Guide to the Inspection of Bulk Pharmaceutical Chemicals” FDA –1994
FDA Compliance Programs:
Bulk Pharmaceutical Chemicals 7356.002F
Sterile Drug Process Inspections 7356.002F
Drug Product cGMPs 1978 preamble
EPA Standards for potable water (at minimum)
“Bulk Pharmaceutical Chemicals Baseline? Guide” ISPE – 6/96
