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Pharmaceutical validation

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Muthu Maharaja Mla
Muthu Maharaja Mla

PHARMACEUTICAL VALIDATION IN TYPES OF VALIDATION SCOPE OF VALIDATION DEVELOPMENT OF VALIDATION VARIOUS TYPE OF DOSAGE FROM VALIDATION

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PHARMACEUTICAL VALIDATION Introduction The concept of validation was first proposed by two Food and Drug Administration (FDA) officials, Ted Byers and Bud Loftus, in the mid 1970’s in order to improve the quality of pharmaceuticals. The first validation activities were focused on the processes involved in making these products, but quickly spread to associated processes including environmental control, media fill, equipment sanitization and purified water production. In a guideline, validation is act of demonstrating and documenting that any procedure, process, and activity will consistently lead to the expected results. It includes the qualification of systems and equipment. The goal of the validation is to ensure that quality is built into the system at every step, and not just tested for at the end, as such validation activities will commonly include training on production material and operating procedures, training of people involved and monitoring of the system whilst in production. In general, an entire process is validated and a particular object within that process is verified. The regulations also set out an expectation that the different parts of the production process are well defined and controlled, such that the results of that production will not substantially change over time. Why Is Validation Required? will producethe productwe wanted or not.
pharmaceutical industry uses expensive materials, sophisticated facilities & equipments and highly qualified personnel. of the industry. The costof productfailures, rejects, reworks, and recalls, complaints are the significant parts of the total productioncost. -validation is necessary if failure to be reduced and productivity improved. The pharmaceutical industries are concerned about validation because of the following reasons. Department Responsible Prepare/execute/approve validation Studies batch documentations/procedures are in place, approves protocols and reports Responsible Authorities For Validation and ultimately, approve the entire effort, including all of the documentation generated. The working party would usually include the following staff members, preferably those with a good insight into the company's operation.
Importance of Validation  Assurance of quality  Time bound  Process optimisation  Reduction of quality cost.  Nominal mix-ups, and bottle necks  Minimal batch failures, improved  efficiently and productivity.  Reduction in rejections.  Increased output.  Avoidance of capital expenditures  Fewer complaints about process related  failures.  Reduced testing in process and in  finished goods.  More rapid and reliable start-up of  new equipments  Easier scale-up form development  work.  Easier maintenance of equipment.
 Improved employee awareness of  processes.  More rapid automation.  Government regulation (Compliance  with validation requirements is  necessary for obtaining approval to  manufacture and to introduce new  products) Scope of validation  To make that tha readings of equipment or instruments are consistent with other measurements and display the correct readings every single time  To determine tha accuracy, precision ,reliability and deviation of tha measurements produced by all tha instruments  To establish tha reliability of tha instrument being used and whether it can be trusted to deliver repeatable results each time  To map tha ‘drift’ as document instrument have a tendency to produce inaccurate measurements over a period of time following repeated use  Ensuring that tha industry standards, quality assurance benchmarks such as current good manufacturing practice (c GMP) government regulations are adhered to.
Planning for Validation All validation activities should be planned. The key elements of a validation programme should be clearly defined and documented in a validation master plan (VMP) or equivalent documents. The VMP should be a summary document, which is brief, concise and clear The VMP should contain data on at least the following: Validation policy, Organisational structure of validation activities. Summary of facilities, systems, equipment and processes to be validated. Documentation format: The format to be used for protocols and reports Planning and scheduling. Change control. Reference to existing document. In case of large projects, it may be necessary to create separate validation master plans.
MasterProduct Document An extensive quantity of documents is generated at each stage of the develop mentand validation of the final production process.Someof these documents will be directly related to the manufacture of the final products. Others may provide the basis for decisions that ultimately result in the final process. The documents that are required for manufacturing the productthen become the master productdocument. This document must be capable of providing all of the information necessary to set up the process to producea product consistently and one that meets specifications in any location. Items that will normally be included in the master productdocument are  Batch manufacturing record  Master formulation  Process flow diagram  Master manufacturing instructions  Master packaging instructions  Specifications  Sampling (location and frequency)  Test methods  Process validation data Each of the above items must contain sufficient detailed information to permit the complete master productdocument to become an independent, single package that will provide all information necessary to set up and producea product.
Elements Of Validation DesignQualification(DQ): - It is documented review of the design, at an appropriate stage of stages in the project, for conformance to operational and regulatory expectations. DQ Check Items:        
Installation Qualification(IQ): -  equipment that can affect productquality adhere to approved specifications and are correctly installed.  ns are:  utilities, and functionality)      and humidity) OperationalQualification (OQ): - It is documented verification that all aspects of a facility, utility or equipment that can affect productquality operate to Intend throughout all anticipated ranges. OQ considerations include:  speed and setup conditions)      
 es or control charts)  -caseconditions (Failure Mode and effects  Performance Qualification(PQ): - It is documented verification that all aspects of a facility, utility or equipment perform as intended in meeting predetermined acceptancecriteria. PQ considerations include:  OQ   ed in OQ  validation activities can be described in three stages. Stage 1 – ProcessDesign:The commercial process is defined during this stage based on 100 knowledge gained through development and scale-up activities. Stage 2 – ProcessQualification:During this stage, the process design is confirmed as 103 being capable of reproducible commercial manufacturing. Stage 3 – Continued ProcessVerification:Ongoing assurance is gained during routine production that the process remains in a state of control.
Types of Validation The guidelines on general principles of process validation mentions four types of validation: 1. Prospective validation (or premarket validation) 2. Retrospective validation 3. Concurrent validation 4. Revalidation 1. Prospective validation: Establishing documented evidence prior to process implementation that a system does what it proposed to do based on preplanned protocols. This approach to validation is normally undertaken whenever the process for a new formula (or within a new facility) must be validated before routine pharmaceutical production commences. In fact, validation of a process by this approach often leads to transfer of the manufacturing process from the development function to production. Prospective validation should include, but not be limited to the following:  Short description of the process.Summary of the critical processing steps to be investigated.  List of the equipment/facilities to be used (including measuring, monitoring/recording equipment) together with its calibration status.  Finished productspecifications for release.
 List of analytical methods, as appropriate.  Proposed in-process controls with acceptance criteria.  Additional testing to be carried out, with acceptance criteria and analytical validation, as appropriate.  Sampling plan.  Methods for recording and evaluating results.  Functions and responsibilities.  Proposed timetable. 2.Retrospective validation: Retrospective validation is used for facilities, processes, and process controls in operation use that have not undergone a formally documented validation process. Validation of these facilities, processes, and process controls is possible using historical data to provide the necessary documentary evidence that the process is doing what it is believed to do. Therefore, this type of validation is only acceptable for well- established processes and will be inappropriate where there have been recent changes in the composition of product, operating processes, or equipment. This approach is rarely been used today because it’s very unlikely that any existing product hasn’t been subjected to the Prospective validation process. It is used only for the audit of a validated process.
3.Concurrentvalidation: Concurrent validation is used for establishing documented evidence that a facility and processes do what they purport to do, based on information generated during actual imputation of the process. This approach involves monitoring of critical processing steps and end product testing of current production, to show that the manufacturing process is in a state of control. 4.Revalidation: Revalidation means repeating the original validation effort or any part of it, and includes investigative review of existing performance data. This approachis essential to maintain the validated status of the plant, equipment, manufacturing processesand computer systems. Possible reasons for starting the revalidation process include:   cleaning process, orother changes that could affect productquality   batch size.  specifications.  es depends on the extent of the changes and the effect upon the product.
Change Control: Written procedures should be in place to describe the actions to be taken if a change is proposed to a product component, process equipment, process environment, processing site, method of production or testing or any other change that may affect product quality or support system operations. All changes must be formally requested, documented and accepted by the validation team. The likely impact / risk of the change on the product must be assessed and the need for the extent of re-validation should be determined. Commitment of the company to control all changes to premises, supporting utilities, systems, materials, equipment and processes used in the fabrication/packaging of pharmaceutical dosage forms is essential to ensure a continued validation status of the systems concerned. The change control system should ensure that all notified or requested changes are satisfactorily investigated, documented and authorized. Products made by processes subjected to changes should not be released for sale without full awareness and consideration of the change by the validation team. The team should decide if a re-validation must be conducted prior to implementing the proposed change.
Phases Of Process Validation The activities relating to validation studies may be classified into three phases: Phase 1: Pre-Validation Phase or the Qualification Phase, which covers all activities relating to productresearch and development, formulation, pilot batch studies, scale-up studies, transfer of technology to commercial scale batches, establishing stability conditions, storage and handling of in-process and finished dosage forms, equipment qualification, installation qualification, master production documents, operational qualification, process capability. Phase 2: ProcessValidation Phase (ProcessQualificationphase) designed to verify that all established limits of the critical process parameters are valid and that satisfactory products canbe produced even under the “worst case” conditions. Phase 3: Validation Maintenance Phase requiring frequent review of all process related documents, including validation audit reports to assure that there have been no changes, deviations, failures, modifications to the production process,and that all SOPs have been followed, including Change Control procedures. At this stage the validation team also assures that there have been no changes/ deviations that should have resulted in requalification and revalidation.
Validation Protocol : A written plan stating how validation will be conducted, including test parameters, product characteristics, production and packaging equipment, and decision points on what constitutes acceptable test results. This document should give details of critical steps of the manufacturing process that should be measured, the allowable range of variability and the manner in which the system will be tested. The validation protocol provides a synopsis of what is hoped to be accomplished. The protocolshould list the selected process and control parameters, state the number of batches to be included in the study, and specify how the data, once assembled, will be treated for relevance. The date of approval by the validation team should also be noted. In the case where a protocol is altered or modified after its approval, appropriate reasoning for such a change must be documented. The validation protocolshould be numbered, signed and dated, and should contain as a minimum the following information: 1. Title 2. Objective & Scope 3. Responsibility 4. ProtocolApproval 5. Validation Team 6. ProductComposition 7. Process FlowChart 8. Manufacturing Process 9. Review of Equipments / Utilities
10. Review of Raw Materials and Packing Materials 11. Review of Analytical and Batch Manufacturing Records 12. Review of Batch Quantities for Validation (Raw Materials) 13. Review of Batch Quantities for Validation (Packing Materials) 14. HSE Requirements 15. Review of Process Parameters 16. Validation Procedure 17. Sampling Location 18. Documentation 19. Acceptance Criteria 20. Summary 21. Conclusion
Validation MasterPlan A validation master plan is a document that summarizes the company’s overall philosophy, intentions and approaches to be used for establishing performance adequacy. The validation master plan should be agreed upon by management. Validation in general requires meticulous preparation and careful planning of the various steps in the process. In addition, all work should be
carried out in a structured way according to formally authorized standard operating procedures. All observations must be documented and where possible must be recorded as actual numerical results. The validation master plan should provide an overview of the entire validation operation, its organizational structure, its content and planning. The main elements include the list/inventory of the items to be validated and planning schedule. All validation activities relating to critical technical operations, relevant to product and process controls within a firm should be included in the validation master plan. It should comprise all prospective, concurrent and retrospective validations as well as re-validation. The validation master plan should be a summary document and should therefore be brief, concise and clear. It should not repeat information documented elsewhere but should refer to existing documents such as policy documents, SOP’s and validation protocols and reports. The format and content should include: introduction: validation policy, scope, location and schedule organizational structure: personnel responsibilities plant/ process /productdescription: rational for inclusions or exclusions and extent of validation specific process considerations that are critical and those requiring extra attention list of products/processes/systems to be validated, summarized in a matrix format, validation approach re-validation activities, actual status and future planning key acceptance criteria documentation format reference to the required SOP’s
Validation of Pharmaceutical Ingredients
U.S. Food and Drug Administration (FDA) for process validation of manufacturing pharmaceutical active ingredients(APIs) and inactive ingredients used in human and veterinary drug products. Active pharmaceutical ingredients belong essentially to one of the following four basic chemical classes: 1. Weak acids and their salts (sodium sulfacetamide, potassium guaiacolsulfonate, calcium fenoprofen, magnesium salicylate, etc.) approximately 30% 2. Weak bases and their salts (nortriptyline hydrochloride, phenelzine sulfate, chloroquine phosphate, scopolamine hydrobromide, tamoxifen citrate, etc.) approximately 45% 3. Organicnonelectrolytes (neutral molecules, chloral hydrate, hydrocortisone, testosterone, mannitol, etc.) approximately 15% 4. Quaternarycompounds (substituted ammonium salts, methacholine chloride, mepenzolate bromide, phospholine iodide, etc.) approximately 10% Pharmaceutical excipients (inactive ingredients) are substances other than the active drug substanceor the drug productthat have been evaluated for safety and are included in the pharmaceutical dosage form (drug delivery system) for one or more of the following functions: 1. Aid in the processing of the drug productduring manufacture (e.g., binder, disintegrant, lubricant, suspending agent, filtering aid) 2. Protect, support, or enhance stability, bioavailability, or patient acceptability (e.g., chelant, surfactant, sweetener) 3. Assist in productidentification (e.g., colorant, flavor, film former)
4. Enhance any other attribute of the overall safety and effectiveness of the drug during storage or use (e.g., inert gas, preservative, sunscreen) TransdermalProcess Validation Good manufacturing practices (CGMPs)are regulations established by the U.S. Food and Drug Administration (USFDA). These regulations not only serve as the operating “Bible” for drug manufacturers, but also provide operating directions in the area of manufacture, processing, packing, and holding of drugs Product/processcertification. Transdermal drug delivery systems are self-contained, discrete dosage forms that, when applied to intact skin, are designed to deliver the drug(s) through the skin to the systemic circulation. Systems typically comprise an outer covering (barrier), a drug reservoir, which may have a rate controlling membrane, a contact adhesive applied to some or all parts of the system and the system/skin interface, and a protective liner that is removed before applying the system. The activity of these systems is defined in terms of the release rate of the drug(s) from the system  Provide improved systemic bioavailability of the active ingredients  Permit slow, timed release of the active  Avoid the affect of a bolus drug dose  Provide for multiple daily doses with a single application  Provide a means to quickly terminate dosing  Provide instantaneous identification of medication in emergency
VALIDATION OF SOLID DOSAGE FORMS VALIDATION OF RAW MATERIALS The steps involved in the validation of a raw material or excipient follow those cited in the CGMPs and in the formal written documentation of those procedures and methods used. 1. Each raw material should be validated by performing checks on several batches (at least three) from the primary supplier as well as the alternate supplier. The batches chosenshould be selected to represent the range of acceptable specifications, both high and low 2. Depending on the susceptibility of the raw material to aging, physical, chemical, and/or microbiological stability should be assessed. This is especially true for liquid or semisolid ingredients, in which interaction with the container or permeability of the container to air and moisture could have a detrimental effect on the raw material.
3. Once the samples of raw materials have been selected as having fallen into an established, acceptable range of specifications and stability, it should be used to manufacture a batch of the final dosageform. It may be appropriate to manufacture several lots of final productwith raw material at the low and high ends of the specification limit. Such testing would be especially useful when it is known that the product may be sensitive to small changes in the characteristics of the excipients or active ingredient. 4. The final step of raw material validation should involve an on-site inspection of the supplier to review the vendor’s manufacturing operations and controlprocedures. The reliability of each vendor and how well each conforms to regulatory requirements must also be determined. ANALYTICAL METHODS VALIDATION 1. Accuracy of method: The ability of a method to measure the true value of a sample. 2. Precision of method: The ability of a method to estimate reproducibility of any given value, but not necessarily the true value. 3. Specificity:The ability to accurately measure the analyte in the presence of other components. 4. In-day/out-of-dayvariation:Does the precision and accuracy of the method change when conducted numerous times on the same day and repeated on a subsequent day?
5. Between-operatorvariation:Repeat of the precision and accuracy studies within the same laboratory using the same instrument but different analysts to challenge the reproducibility of the method. 6. Between-instrumentvariation:How will different instruments within the same laboratory run by the same analyst affect the accuracy and precision of the method? 7. Between-laboratoryvariation:Will the precision and accuracy of the method be the same between the development and quality control laboratories? EQUIPMENT/FACILITYVALIDATION The productdevelopment of a pharmaceutical producthas its origins in a systematic approachto formulation, process and manufacture, and the analytical testing that is necessary to monitor quality and reproducibility. Once development scale activities (productdevelopment, early toxicology, and clinical evaluation) provide encouragement that the development compound could become a commercial product, a multi departmental team is usually formed with product development, production, and engineering staff to plan a life-cycle approachrelated to the manufacture of the product. In-Process Tests 1. Moisture content of “dried granulation”:Loss on drying (LOD) can be used to determine whether or not the granulation solvent has been removed to a sufficient level during the drying operation (usually less than 2% moisture).
2. Granulation particlesizedistribution:An extremely important parameter that can affect tablet compressibility, hardness, thickness, disintegration, dissolution, weight variation, and content uniformity. This parameter, which can be done by sieve analysis, should be monitored throughout the tablet validation process. 3. Blend uniformity:Samples of the blend are taken and analyzed to ensure that the drug is uniformly dispersed throughout the tablet/capsule blend. The properblend time must be established so that the blend is not under- or overmixed. The sampling technique is critical for this test to be valid [45]. 4. Individual tablet/capsuleweight:The weight of individual tablets or capsules is determined throughout compression/encapsulation to ensure that the material is flowing properly and the equipment is working consistently. The individual weight should be within 5% of the nominal weight. Weight fluctuations or frequent machine adjustments suggest that the formulation/process (e.g., poorgranulation flow) is not optimized and/or that the equipment may need maintenance. 5. Tablethardness:Tablet hardness is determined periodically throughout the batch to ensure that the tablets are robust enough for coating, packing, and shipping and not too hard to affect dissolution. 6. Tabletthickness: Tablet thickness is also determined periodically throughout the batch and is indirectly related to the hardness. It is another indication of whether or not the formulation has properflow and compressionproperties. 7. Disintegration:Disintegration is determined during the manufacture as a predictor of tablet performance (e.g., dissolution). B. Finished Product Tests
1. Appearance:The tablets should be examined for such problems as tablet mottling, picking of the monogram, tablet filming, and capping of the tablets. If the tablets are colored, the color quality needs to be examined. 2. Assay: This test will determine whether or not the productcontains the labeled amount of drug. 3. Contentuniformity: Samples are taken across the batch profile (beginning, middle, and end) and analyzed to ensure that the dosage forms more stringent internal limits. It will indicate whether there is demixing during the manufacturing operation (i.e., segregation during flow of granulation from a storage bin). 4. Tablethardness:A critical parameter for dosageform handling and performance. 5. Tabletfriability: Friability is an important characteristic on the tablets’ ability to withstand chipping, cracking, or “dusting” during the packaging operations and shipping. 6. Dissolution: Dissolution is important to ensure proper drug release characteristics (in vitro availability) and batch-to-batch uniformity.

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Pharmaceutical validation

  • 1. PHARMACEUTICAL VALIDATION Introduction The concept of validation was first proposed by two Food and Drug Administration (FDA) officials, Ted Byers and Bud Loftus, in the mid 1970’s in order to improve the quality of pharmaceuticals. The first validation activities were focused on the processes involved in making these products, but quickly spread to associated processes including environmental control, media fill, equipment sanitization and purified water production. In a guideline, validation is act of demonstrating and documenting that any procedure, process, and activity will consistently lead to the expected results. It includes the qualification of systems and equipment. The goal of the validation is to ensure that quality is built into the system at every step, and not just tested for at the end, as such validation activities will commonly include training on production material and operating procedures, training of people involved and monitoring of the system whilst in production. In general, an entire process is validated and a particular object within that process is verified. The regulations also set out an expectation that the different parts of the production process are well defined and controlled, such that the results of that production will not substantially change over time. Why Is Validation Required? will producethe productwe wanted or not.
  • 2. pharmaceutical industry uses expensive materials, sophisticated facilities & equipments and highly qualified personnel. of the industry. The costof productfailures, rejects, reworks, and recalls, complaints are the significant parts of the total productioncost. -validation is necessary if failure to be reduced and productivity improved. The pharmaceutical industries are concerned about validation because of the following reasons. Department Responsible Prepare/execute/approve validation Studies batch documentations/procedures are in place, approves protocols and reports Responsible Authorities For Validation and ultimately, approve the entire effort, including all of the documentation generated. The working party would usually include the following staff members, preferably those with a good insight into the company's operation.
  • 3. Importance of Validation  Assurance of quality  Time bound  Process optimisation  Reduction of quality cost.  Nominal mix-ups, and bottle necks  Minimal batch failures, improved  efficiently and productivity.  Reduction in rejections.  Increased output.  Avoidance of capital expenditures  Fewer complaints about process related  failures.  Reduced testing in process and in  finished goods.  More rapid and reliable start-up of  new equipments  Easier scale-up form development  work.  Easier maintenance of equipment.
  • 4.  Improved employee awareness of  processes.  More rapid automation.  Government regulation (Compliance  with validation requirements is  necessary for obtaining approval to  manufacture and to introduce new  products) Scope of validation  To make that tha readings of equipment or instruments are consistent with other measurements and display the correct readings every single time  To determine tha accuracy, precision ,reliability and deviation of tha measurements produced by all tha instruments  To establish tha reliability of tha instrument being used and whether it can be trusted to deliver repeatable results each time  To map tha ‘drift’ as document instrument have a tendency to produce inaccurate measurements over a period of time following repeated use  Ensuring that tha industry standards, quality assurance benchmarks such as current good manufacturing practice (c GMP) government regulations are adhered to.
  • 5. Planning for Validation All validation activities should be planned. The key elements of a validation programme should be clearly defined and documented in a validation master plan (VMP) or equivalent documents. The VMP should be a summary document, which is brief, concise and clear The VMP should contain data on at least the following: Validation policy, Organisational structure of validation activities. Summary of facilities, systems, equipment and processes to be validated. Documentation format: The format to be used for protocols and reports Planning and scheduling. Change control. Reference to existing document. In case of large projects, it may be necessary to create separate validation master plans.
  • 6. MasterProduct Document An extensive quantity of documents is generated at each stage of the develop mentand validation of the final production process.Someof these documents will be directly related to the manufacture of the final products. Others may provide the basis for decisions that ultimately result in the final process. The documents that are required for manufacturing the productthen become the master productdocument. This document must be capable of providing all of the information necessary to set up the process to producea product consistently and one that meets specifications in any location. Items that will normally be included in the master productdocument are  Batch manufacturing record  Master formulation  Process flow diagram  Master manufacturing instructions  Master packaging instructions  Specifications  Sampling (location and frequency)  Test methods  Process validation data Each of the above items must contain sufficient detailed information to permit the complete master productdocument to become an independent, single package that will provide all information necessary to set up and producea product.
  • 7. Elements Of Validation DesignQualification(DQ): - It is documented review of the design, at an appropriate stage of stages in the project, for conformance to operational and regulatory expectations. DQ Check Items:        
  • 8. Installation Qualification(IQ): -  equipment that can affect productquality adhere to approved specifications and are correctly installed.  ns are:  utilities, and functionality)      and humidity) OperationalQualification (OQ): - It is documented verification that all aspects of a facility, utility or equipment that can affect productquality operate to Intend throughout all anticipated ranges. OQ considerations include:  speed and setup conditions)      
  • 9.  es or control charts)  -caseconditions (Failure Mode and effects  Performance Qualification(PQ): - It is documented verification that all aspects of a facility, utility or equipment perform as intended in meeting predetermined acceptancecriteria. PQ considerations include:  OQ   ed in OQ  validation activities can be described in three stages. Stage 1 – ProcessDesign:The commercial process is defined during this stage based on 100 knowledge gained through development and scale-up activities. Stage 2 – ProcessQualification:During this stage, the process design is confirmed as 103 being capable of reproducible commercial manufacturing. Stage 3 – Continued ProcessVerification:Ongoing assurance is gained during routine production that the process remains in a state of control.
  • 10. Types of Validation The guidelines on general principles of process validation mentions four types of validation: 1. Prospective validation (or premarket validation) 2. Retrospective validation 3. Concurrent validation 4. Revalidation 1. Prospective validation: Establishing documented evidence prior to process implementation that a system does what it proposed to do based on preplanned protocols. This approach to validation is normally undertaken whenever the process for a new formula (or within a new facility) must be validated before routine pharmaceutical production commences. In fact, validation of a process by this approach often leads to transfer of the manufacturing process from the development function to production. Prospective validation should include, but not be limited to the following:  Short description of the process.Summary of the critical processing steps to be investigated.  List of the equipment/facilities to be used (including measuring, monitoring/recording equipment) together with its calibration status.  Finished productspecifications for release.
  • 11.  List of analytical methods, as appropriate.  Proposed in-process controls with acceptance criteria.  Additional testing to be carried out, with acceptance criteria and analytical validation, as appropriate.  Sampling plan.  Methods for recording and evaluating results.  Functions and responsibilities.  Proposed timetable. 2.Retrospective validation: Retrospective validation is used for facilities, processes, and process controls in operation use that have not undergone a formally documented validation process. Validation of these facilities, processes, and process controls is possible using historical data to provide the necessary documentary evidence that the process is doing what it is believed to do. Therefore, this type of validation is only acceptable for well- established processes and will be inappropriate where there have been recent changes in the composition of product, operating processes, or equipment. This approach is rarely been used today because it’s very unlikely that any existing product hasn’t been subjected to the Prospective validation process. It is used only for the audit of a validated process.
  • 12. 3.Concurrentvalidation: Concurrent validation is used for establishing documented evidence that a facility and processes do what they purport to do, based on information generated during actual imputation of the process. This approach involves monitoring of critical processing steps and end product testing of current production, to show that the manufacturing process is in a state of control. 4.Revalidation: Revalidation means repeating the original validation effort or any part of it, and includes investigative review of existing performance data. This approachis essential to maintain the validated status of the plant, equipment, manufacturing processesand computer systems. Possible reasons for starting the revalidation process include:   cleaning process, orother changes that could affect productquality   batch size.  specifications.  es depends on the extent of the changes and the effect upon the product.
  • 13. Change Control: Written procedures should be in place to describe the actions to be taken if a change is proposed to a product component, process equipment, process environment, processing site, method of production or testing or any other change that may affect product quality or support system operations. All changes must be formally requested, documented and accepted by the validation team. The likely impact / risk of the change on the product must be assessed and the need for the extent of re-validation should be determined. Commitment of the company to control all changes to premises, supporting utilities, systems, materials, equipment and processes used in the fabrication/packaging of pharmaceutical dosage forms is essential to ensure a continued validation status of the systems concerned. The change control system should ensure that all notified or requested changes are satisfactorily investigated, documented and authorized. Products made by processes subjected to changes should not be released for sale without full awareness and consideration of the change by the validation team. The team should decide if a re-validation must be conducted prior to implementing the proposed change.
  • 14. Phases Of Process Validation The activities relating to validation studies may be classified into three phases: Phase 1: Pre-Validation Phase or the Qualification Phase, which covers all activities relating to productresearch and development, formulation, pilot batch studies, scale-up studies, transfer of technology to commercial scale batches, establishing stability conditions, storage and handling of in-process and finished dosage forms, equipment qualification, installation qualification, master production documents, operational qualification, process capability. Phase 2: ProcessValidation Phase (ProcessQualificationphase) designed to verify that all established limits of the critical process parameters are valid and that satisfactory products canbe produced even under the “worst case” conditions. Phase 3: Validation Maintenance Phase requiring frequent review of all process related documents, including validation audit reports to assure that there have been no changes, deviations, failures, modifications to the production process,and that all SOPs have been followed, including Change Control procedures. At this stage the validation team also assures that there have been no changes/ deviations that should have resulted in requalification and revalidation.
  • 15. Validation Protocol : A written plan stating how validation will be conducted, including test parameters, product characteristics, production and packaging equipment, and decision points on what constitutes acceptable test results. This document should give details of critical steps of the manufacturing process that should be measured, the allowable range of variability and the manner in which the system will be tested. The validation protocol provides a synopsis of what is hoped to be accomplished. The protocolshould list the selected process and control parameters, state the number of batches to be included in the study, and specify how the data, once assembled, will be treated for relevance. The date of approval by the validation team should also be noted. In the case where a protocol is altered or modified after its approval, appropriate reasoning for such a change must be documented. The validation protocolshould be numbered, signed and dated, and should contain as a minimum the following information: 1. Title 2. Objective & Scope 3. Responsibility 4. ProtocolApproval 5. Validation Team 6. ProductComposition 7. Process FlowChart 8. Manufacturing Process 9. Review of Equipments / Utilities
  • 16. 10. Review of Raw Materials and Packing Materials 11. Review of Analytical and Batch Manufacturing Records 12. Review of Batch Quantities for Validation (Raw Materials) 13. Review of Batch Quantities for Validation (Packing Materials) 14. HSE Requirements 15. Review of Process Parameters 16. Validation Procedure 17. Sampling Location 18. Documentation 19. Acceptance Criteria 20. Summary 21. Conclusion
  • 17. Validation MasterPlan A validation master plan is a document that summarizes the company’s overall philosophy, intentions and approaches to be used for establishing performance adequacy. The validation master plan should be agreed upon by management. Validation in general requires meticulous preparation and careful planning of the various steps in the process. In addition, all work should be
  • 18. carried out in a structured way according to formally authorized standard operating procedures. All observations must be documented and where possible must be recorded as actual numerical results. The validation master plan should provide an overview of the entire validation operation, its organizational structure, its content and planning. The main elements include the list/inventory of the items to be validated and planning schedule. All validation activities relating to critical technical operations, relevant to product and process controls within a firm should be included in the validation master plan. It should comprise all prospective, concurrent and retrospective validations as well as re-validation. The validation master plan should be a summary document and should therefore be brief, concise and clear. It should not repeat information documented elsewhere but should refer to existing documents such as policy documents, SOP’s and validation protocols and reports. The format and content should include: introduction: validation policy, scope, location and schedule organizational structure: personnel responsibilities plant/ process /productdescription: rational for inclusions or exclusions and extent of validation specific process considerations that are critical and those requiring extra attention list of products/processes/systems to be validated, summarized in a matrix format, validation approach re-validation activities, actual status and future planning key acceptance criteria documentation format reference to the required SOP’s
  • 20. U.S. Food and Drug Administration (FDA) for process validation of manufacturing pharmaceutical active ingredients(APIs) and inactive ingredients used in human and veterinary drug products. Active pharmaceutical ingredients belong essentially to one of the following four basic chemical classes: 1. Weak acids and their salts (sodium sulfacetamide, potassium guaiacolsulfonate, calcium fenoprofen, magnesium salicylate, etc.) approximately 30% 2. Weak bases and their salts (nortriptyline hydrochloride, phenelzine sulfate, chloroquine phosphate, scopolamine hydrobromide, tamoxifen citrate, etc.) approximately 45% 3. Organicnonelectrolytes (neutral molecules, chloral hydrate, hydrocortisone, testosterone, mannitol, etc.) approximately 15% 4. Quaternarycompounds (substituted ammonium salts, methacholine chloride, mepenzolate bromide, phospholine iodide, etc.) approximately 10% Pharmaceutical excipients (inactive ingredients) are substances other than the active drug substanceor the drug productthat have been evaluated for safety and are included in the pharmaceutical dosage form (drug delivery system) for one or more of the following functions: 1. Aid in the processing of the drug productduring manufacture (e.g., binder, disintegrant, lubricant, suspending agent, filtering aid) 2. Protect, support, or enhance stability, bioavailability, or patient acceptability (e.g., chelant, surfactant, sweetener) 3. Assist in productidentification (e.g., colorant, flavor, film former)
  • 21. 4. Enhance any other attribute of the overall safety and effectiveness of the drug during storage or use (e.g., inert gas, preservative, sunscreen) TransdermalProcess Validation Good manufacturing practices (CGMPs)are regulations established by the U.S. Food and Drug Administration (USFDA). These regulations not only serve as the operating “Bible” for drug manufacturers, but also provide operating directions in the area of manufacture, processing, packing, and holding of drugs Product/processcertification. Transdermal drug delivery systems are self-contained, discrete dosage forms that, when applied to intact skin, are designed to deliver the drug(s) through the skin to the systemic circulation. Systems typically comprise an outer covering (barrier), a drug reservoir, which may have a rate controlling membrane, a contact adhesive applied to some or all parts of the system and the system/skin interface, and a protective liner that is removed before applying the system. The activity of these systems is defined in terms of the release rate of the drug(s) from the system  Provide improved systemic bioavailability of the active ingredients  Permit slow, timed release of the active  Avoid the affect of a bolus drug dose  Provide for multiple daily doses with a single application  Provide a means to quickly terminate dosing  Provide instantaneous identification of medication in emergency
  • 22. VALIDATION OF SOLID DOSAGE FORMS VALIDATION OF RAW MATERIALS The steps involved in the validation of a raw material or excipient follow those cited in the CGMPs and in the formal written documentation of those procedures and methods used. 1. Each raw material should be validated by performing checks on several batches (at least three) from the primary supplier as well as the alternate supplier. The batches chosenshould be selected to represent the range of acceptable specifications, both high and low 2. Depending on the susceptibility of the raw material to aging, physical, chemical, and/or microbiological stability should be assessed. This is especially true for liquid or semisolid ingredients, in which interaction with the container or permeability of the container to air and moisture could have a detrimental effect on the raw material.
  • 23. 3. Once the samples of raw materials have been selected as having fallen into an established, acceptable range of specifications and stability, it should be used to manufacture a batch of the final dosageform. It may be appropriate to manufacture several lots of final productwith raw material at the low and high ends of the specification limit. Such testing would be especially useful when it is known that the product may be sensitive to small changes in the characteristics of the excipients or active ingredient. 4. The final step of raw material validation should involve an on-site inspection of the supplier to review the vendor’s manufacturing operations and controlprocedures. The reliability of each vendor and how well each conforms to regulatory requirements must also be determined. ANALYTICAL METHODS VALIDATION 1. Accuracy of method: The ability of a method to measure the true value of a sample. 2. Precision of method: The ability of a method to estimate reproducibility of any given value, but not necessarily the true value. 3. Specificity:The ability to accurately measure the analyte in the presence of other components. 4. In-day/out-of-dayvariation:Does the precision and accuracy of the method change when conducted numerous times on the same day and repeated on a subsequent day?
  • 24. 5. Between-operatorvariation:Repeat of the precision and accuracy studies within the same laboratory using the same instrument but different analysts to challenge the reproducibility of the method. 6. Between-instrumentvariation:How will different instruments within the same laboratory run by the same analyst affect the accuracy and precision of the method? 7. Between-laboratoryvariation:Will the precision and accuracy of the method be the same between the development and quality control laboratories? EQUIPMENT/FACILITYVALIDATION The productdevelopment of a pharmaceutical producthas its origins in a systematic approachto formulation, process and manufacture, and the analytical testing that is necessary to monitor quality and reproducibility. Once development scale activities (productdevelopment, early toxicology, and clinical evaluation) provide encouragement that the development compound could become a commercial product, a multi departmental team is usually formed with product development, production, and engineering staff to plan a life-cycle approachrelated to the manufacture of the product. In-Process Tests 1. Moisture content of “dried granulation”:Loss on drying (LOD) can be used to determine whether or not the granulation solvent has been removed to a sufficient level during the drying operation (usually less than 2% moisture).
  • 25. 2. Granulation particlesizedistribution:An extremely important parameter that can affect tablet compressibility, hardness, thickness, disintegration, dissolution, weight variation, and content uniformity. This parameter, which can be done by sieve analysis, should be monitored throughout the tablet validation process. 3. Blend uniformity:Samples of the blend are taken and analyzed to ensure that the drug is uniformly dispersed throughout the tablet/capsule blend. The properblend time must be established so that the blend is not under- or overmixed. The sampling technique is critical for this test to be valid [45]. 4. Individual tablet/capsuleweight:The weight of individual tablets or capsules is determined throughout compression/encapsulation to ensure that the material is flowing properly and the equipment is working consistently. The individual weight should be within 5% of the nominal weight. Weight fluctuations or frequent machine adjustments suggest that the formulation/process (e.g., poorgranulation flow) is not optimized and/or that the equipment may need maintenance. 5. Tablethardness:Tablet hardness is determined periodically throughout the batch to ensure that the tablets are robust enough for coating, packing, and shipping and not too hard to affect dissolution. 6. Tabletthickness: Tablet thickness is also determined periodically throughout the batch and is indirectly related to the hardness. It is another indication of whether or not the formulation has properflow and compressionproperties. 7. Disintegration:Disintegration is determined during the manufacture as a predictor of tablet performance (e.g., dissolution). B. Finished Product Tests
  • 26. 1. Appearance:The tablets should be examined for such problems as tablet mottling, picking of the monogram, tablet filming, and capping of the tablets. If the tablets are colored, the color quality needs to be examined. 2. Assay: This test will determine whether or not the productcontains the labeled amount of drug. 3. Contentuniformity: Samples are taken across the batch profile (beginning, middle, and end) and analyzed to ensure that the dosage forms more stringent internal limits. It will indicate whether there is demixing during the manufacturing operation (i.e., segregation during flow of granulation from a storage bin). 4. Tablethardness:A critical parameter for dosageform handling and performance. 5. Tabletfriability: Friability is an important characteristic on the tablets’ ability to withstand chipping, cracking, or “dusting” during the packaging operations and shipping. 6. Dissolution: Dissolution is important to ensure proper drug release characteristics (in vitro availability) and batch-to-batch uniformity.