Difference between revisions of "Quality management system"

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By 1994, the ISO 9000 standards saw a new iteration, putting a new focus on preventative action.<ref name="QMSIntISO16" /> At least 150 countries adopted the ISO 9000 standards by the end of 1999, with the associated third-party registration industry having a total economic impact of $4 billion. That number had climbed to 161 countries by the summer of 2002<ref name="SchlickmanISO09001_03b">{{cite book |url=https://books.google.com/books?id=FkQB4GRB7uwC |title=ISO 9001:2000 Quality Management System Design |author=Schlickman, J.J. |publisher=Artech House |page=xxii |year=2003 |isbn=9781580535960}}</ref>, after the major update of the ISO 9001:2000 standard, which merged 9002 and 9003 into it and added new process-based changes.<ref name="QMSIntISO16" /> Changes in 2008 were minor, but the 2015 revision saw major revisions in structure and how common requirements were aligned with other relevant standards, with more of a focus on risk-based thinking.<ref name="QMSIntISO16" />
By 1994, the ISO 9000 standards saw a new iteration, putting a new focus on preventative action.<ref name="QMSIntISO16" /> At least 150 countries adopted the ISO 9000 standards by the end of 1999, with the associated third-party registration industry having a total economic impact of $4 billion. That number had climbed to 161 countries by the summer of 2002<ref name="SchlickmanISO09001_03b">{{cite book |url=https://books.google.com/books?id=FkQB4GRB7uwC |title=ISO 9001:2000 Quality Management System Design |author=Schlickman, J.J. |publisher=Artech House |page=xxii |year=2003 |isbn=9781580535960}}</ref>, after the major update of the ISO 9001:2000 standard, which merged 9002 and 9003 into it and added new process-based changes.<ref name="QMSIntISO16" /> Changes in 2008 were minor, but the 2015 revision saw major revisions in structure and how common requirements were aligned with other relevant standards, with more of a focus on risk-based thinking.<ref name="QMSIntISO16" />


==QMS standards==
==QMS standards and elements==
Many standards are used internationally for designing and implementing quality management systems, though ISO 9001:2015 is the most well recognized and used. Other standards include<ref name="ASQWhatIs" />:
Many standards are used internationally for designing and implementing quality management systems, though ISO 9001:2015 is the most well recognized and used. Other standards include<ref name="ASQWhatIs" />:


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==Special cases==
==Special cases==
===Medical devices===
===Medical device industry===
The two primary, state of the art, guidelines for medical device manufacturer QMS and related services today are the ISO 13485 standards and the US FDA 21 CFR 820 regulations. The two have a great deal of similarity, and many manufacturers adopt QMS that is compliant with both guidelines.
The two primary guidelines for [[medical device]] manufacturer quality management systems in the United States are the ISO 13485 standard and the U.S. Food and Drug Administration's (FDA) 21 CFR Part 820 regulations. The two have a great deal of similarity, and many manufacturers adopt a QMS that is compliant with both guidelines. Outside the U.S., ISO 13485 is harmonized with the European Union medical devices directive (93/42/EEC) as well as the IVD and AIMD directives. The ISO standard is also incorporated in regulations for other jurisdictions such as Japan (JPAL) and Canada (CMDCAS).


ISO 13485 are harmonized with the European Union medical devices directive (93/42/EEC) as well as the IVD and AIMD directives. The ISO standard is also incorporated in regulations for other jurisdictions such as Japan (JPAL) and Canada (CMDCAS).
According to current good manufacturing practice (GMP), medical device manufacturers have the responsibility to use good judgment when developing their quality system and apply relevant sections standards, regulations, and guidelines that are applicable to their specific products and operations. As with GMP, operating within this flexibility, it is the responsibility of each manufacturer to establish requirements for each type or family of devices that will result in devices that are safe and effective, and to establish methods and procedures to design, produce, and distribute devices that meet the quality system requirements.


Quality System requirements for medical devices have been internationally recognized as a way to assure product safety and efficacy and customer satisfaction since at least 1983 and were instituted as requirements in a  [http://www.gmp1st.com/md96p.pdf final rule published on October 7, 1996]. The U.S. [[Food and Drug Administration]] (FDA) had documented design defects in medical devices that contributed to recalls from 1983 to 1989 that would have been prevented if Quality Systems had been in place. The rule is promulgated at [http://www.access.gpo.gov/nara/cfr/waisidx_05/21cfr820_05.html 21 CFR 820].
Because the FDA's 21 CFR Part 820 regulation covers a broad spectrum of devices and production processes, it allows some leeway in the details of quality system elements. It is left up to manufacturers to determine the necessity for, or extent of, some quality elements and to develop and implement procedures tailored to their particular processes and devices. For example, if it is impossible to mix up labels at a manufacturer because there is only one label to each product, then it's not necessary for the manufacturer to comply with all of the GMP requirements under device labeling.
 
According to current Good Manufacturing Practice (GMP), [[medical device]] manufacturers have the responsibility to use good judgment when developing their quality system and apply those sections of the FDA Quality System (QS) Regulation that are applicable to their specific products and operations, in [http://www.access.gpo.gov/nara/cfr/waisidx_05/21cfr820_05.html Part 820] of the QS regulation. As with GMP, operating within this flexibility, it is the responsibility of each manufacturer to establish requirements for each type or family of devices that will result in devices that are safe and effective, and to establish methods and procedures to design, produce, and distribute devices that meet the quality system requirements.
 
The FDA has identified in the QS regulation the 7 essential subsystems of a quality system. These subsystems include:
 
* Management controls;
* Design controls;
* Production and process controls
* Corrective and preventative actions
* Material controls
* Records, documents, and change controls
* Facilities and equipment controls
all overseen by management and quality audits.
 
Because the QS regulation covers a broad spectrum of devices and production processes, it allows some leeway in the details of quality system elements. It is left to manufacturers to determine the necessity for, or extent of, some quality elements and to develop and implement procedures tailored to their particular processes and devices. For example, if it is impossible to mix up labels at a manufacturer because there is only one label to each product, then there is no necessity for the manufacturer to comply with all of the GMP requirements under device labeling.


==Certifications and awards==
==Certifications and awards==

Revision as of 20:52, 9 November 2017

A quality management system (QMS) represents the collection of documented processes, management models, business strategies, human capital, and information technology that are used to plan, develop, deploy, evaluate, and improve a set of models, methods, and tools across an organization for the purpose of improving quality, particularly in-line with the organization's strategic goals. The successful development and deployment of a QMS requires the assessment of organizational resources, customer needs, industry product cycles, and more.[1] A QMS will attempt to establish organizational policy and objectives for resource management, assign responsibility and authority to personnel, and put into place an organizational structure among personnel.[2] The QMS will also be designed to focus on the core elements of quality management: planning, control, assurance, and improvement.[3] However, a QMS should not be confused with product and service standards, which tend to give "explicit requirements that specific products and services should conform to" rather than broad good management practices applicable to any product or service.[4]

A successful quality management system may drive competitiveness in the organization, but competitiveness is not the core goal of a QMS; rather, customer satisfaction and, to a lesser degree, financial performance are tied to a successful QMS implementation.[1] Additionally, a QMS may reduce waste, identify and facilitate training, and improve staff engagement.[5]

History

The concept of a "quality" as we think of it today first emerged from the Industrial Revolution. Previously, goods had been made from start to finish by the same person or team of people, with handcrafting and tweaking the product to meet quality criteria. Mass production brought huge teams of people together to work on specific stages of production where one person would not necessarily complete a product from start to finish. This mass production inevitably led to a decline in quality with its emphasis on driving down prices rather than quality. This led to "a neeed for a more regulated system both in ensuring that machines used by manufacturers were not the real problem for substandard goods as well as checking items as they came off the production line."[6]

In the early 1900s, pioneers such as Frederick Winslow Taylor and Henry Ford recognized the limitations of the methods being used in mass production at the time and the subsequent varying quality of output. Taylor, utilizing the concept of scientific management, helped separate production tasks into many simple steps (the assembly line) and limited quality control to a few specific individuals, limiting complexity.[7] Ford emphasized standardization of design and component standards to ensure a standard product was produced, while quality was the responsibility of machine inspectors, "placed in each department to cover all operations ... at frequent intervals, so that no faulty operation shall proceed for any great length of time."[8]

Post World War II saw statistician and mathematician William Edwards Deming (after whom the Deming Prize for quality is named), the father of the quality management movement, develop a theory of quality management that focused on the "joy in work," while placing emphasis on quality at each step of a process, not simply on the final inspection.[9] This led to several Japanese scientists and engineers inviting Deming to Japan in 1950 to share his ideas on statistical methods towards improved quality, with several companies seeing productivity and profit gains after adoption.[9] In 1951, engineer and management consultant Joseph M. Juran published the first edition of Juran's Quality Handbook, an influential guide to quality management that focused on "fitness for use by the customer" as a goal of quality. Juran's work, focusing on management's influence on quality, had a similar impact on the Japanese. The combination of Deming's and Juran's influence ultimately led to the Japanese developing their own take on quality management: Japanese Total Quality Control.[9]

In the mid-twentieth century, the focus on quality as a profession and a managerial process saw the quality profession grow from simple engineering controls to systems engineering that took quality into account at its various steps. This was most noticeable in the Japanese strategy to industry, though the U.S. didn't clearly recognize it until the early 1980s. With the decline in price competition and increase in quality competition in the 1970's putting American manufacturing in a difficult position, the early to mid-1980s saw the U.S.' industrial and government leaders recognize Japan's quality strategy[10], committing to a renewed emphasis on quality in order to stay relevant in an expanding and competitive world market. The Malcolm Baldrige National Quality Improvement Act of 1987 spawned the associated National Quality Program, commonly referred to as the Baldridge model[1], and an award program that acted as a standard of excellence to further drive quality innovation in the marketplace. That same year, the ISO 9001, 9002, and 9003 standards were published; based off work from previous British and U.S. military standards, the standard sought to "provide organizations with the requirements to create a quality management system (QMS) for a range of different business activities."[11] Other awards like the Deming Prize were set up by the Japanese, and the first non-Japanese company to win the prize was the U.S.'s Florida Light and Power in 1989.[12] The trend continued into Europe with the introduction of the European Foundation for Quality Management in 1991.[1]

By 1994, the ISO 9000 standards saw a new iteration, putting a new focus on preventative action.[11] At least 150 countries adopted the ISO 9000 standards by the end of 1999, with the associated third-party registration industry having a total economic impact of $4 billion. That number had climbed to 161 countries by the summer of 2002[13], after the major update of the ISO 9001:2000 standard, which merged 9002 and 9003 into it and added new process-based changes.[11] Changes in 2008 were minor, but the 2015 revision saw major revisions in structure and how common requirements were aligned with other relevant standards, with more of a focus on risk-based thinking.[11]

QMS standards and elements

Many standards are used internationally for designing and implementing quality management systems, though ISO 9001:2015 is the most well recognized and used. Other standards include[5]:

  • ISO 9000 and 9004
  • ISO 13485 for medical devices
  • ISO 14001 for environmental management
  • ISO 19011 for auditing management
  • ISO/TS 16949 for automotive manufacturing

QMS elements

While quality management systems may vary by industry and by company policy, most typically share the same base-level elements, including[5]:

  • organizational quality policy and objectives
  • quality manual
  • set of procedures, instructions, and records
  • data management
  • internal processes
  • product/service quality that leads to customer satisfaction
  • quality analysis
  • continuous improvement, including corrective and preventive action

Quality policy and objectives

These items should be an expression of senior management's desire to commit to a QMS, based on the standard(s) used and the company's vision and mission. The policy will largely focus on customers and other interested parties, using a process approach that uses evidence-based decision making and encourages improvement. Quality objectives are derived from the policy and cover all functional levels of the business.[14]

Quality manual

A quality manual is the first set of documentation primary to a QMS, and it's used to communicate management's expectations towards quality, how to conform to them, and how to measure that conformity. The manual typically contains a full description of the QMS, describing the standard-based requirements, quality procedures, exclusions, interactions, and granular quality policies. A successful quality manual further guides a business towards continuous improvement.[15][16]

Procedures, instructions, and records

Quality procedures don't have a set format but should include a series of consistent elements, including title, purpose, scope, responsible parties, resulting records, document controls, activity descriptions, and appendices. Any instructions should be similarly structured but also include "details of activities that need to be realized, focusing on the sequencing of the steps, tools, and methods to be used and required accuracy."[17] A record of proofs provide traceability of the various actions taken to comply with those quality procedures and instructions, providing tools for continuous improvement and corrective action.[18]

Data management

From creating the policies and procedures to tracking conformance to them, files records of various sorts are inevitably created. Being able to integrate those documents and related data across the enterprise can be tricky but beneficial. Strong data management policies applied to quality data help businesses can not only mitigate risk and determine trends but also help them maintain regulatory compliance. Setting up data management policies and systems requires planning, however, including determining data types, data ownership, data quality, and metadata availability. Additional, any quality data management policy and system should meet organizational goals while identifying what should be included and excluded, and they should include a clear roadmap for how it will be implemented. Quality data management systems should be able to hand normalization, versioning, archiving, and compliance-related security.[19]

Internal processes

Keeping a QMS process-based allows the various inputs and outputs of a business stay connected and unified in quality. By recognizing that "the output of one process becomes the input of another process,"[14] a single integrated process that depends on quality is revealed. Derived from procedures and instructions, a process map is built, detailing resources, authority, risks, and evaluation methods that are associated with those processes.[20]

Focus on customers

Product and/or service quality that leads to customer satisfaction is a primary goal of a QMS. This focus often comes down from senior leadership, who encourages personnel to take a similar focus through the management of relevant requirements, the management of relevant risks and opportunities, and the commitment to improving customer satisfaction.[20] Overall company policies should include this focus, which should then make it's way into more effective process management, and by extension, higher customer satisfaction, measured using a set of principles that include data collected directly from customers and an additive formula that aggregates all that data into a global picture of satisfaction.[21]

Quality analysis

A major part of a QMS is evaluating and improving processes and procedures to improve overall quality. Part of this process may include defect analysis for products, customer satisfaction analysis for services, and corrective action planning. Also included is overall product testing, tests that, for a product, may measure material, electrical, stressed, etc. characteristics to ensure functionality for the end-user. Even the business' own operations may be scrutinized to identify points in the system where physical or economical impact is most negatively felt.

Continuous improvement

Continuous improvement recognizes that customer needs change over time and that an incremental innovation process should always be in place to address those changing needs. "Small steps, high frequency and small change cycles seen separately have small impacts but, added up can bring a significant contribution to the company’s performance."[22] Optimally the idea of continuous improvement should also be promoted by senior leadership, finding its way not only into the quality manual but ultimately also into the work culture.[22]

Special cases

Medical device industry

The two primary guidelines for medical device manufacturer quality management systems in the United States are the ISO 13485 standard and the U.S. Food and Drug Administration's (FDA) 21 CFR Part 820 regulations. The two have a great deal of similarity, and many manufacturers adopt a QMS that is compliant with both guidelines. Outside the U.S., ISO 13485 is harmonized with the European Union medical devices directive (93/42/EEC) as well as the IVD and AIMD directives. The ISO standard is also incorporated in regulations for other jurisdictions such as Japan (JPAL) and Canada (CMDCAS).

According to current good manufacturing practice (GMP), medical device manufacturers have the responsibility to use good judgment when developing their quality system and apply relevant sections standards, regulations, and guidelines that are applicable to their specific products and operations. As with GMP, operating within this flexibility, it is the responsibility of each manufacturer to establish requirements for each type or family of devices that will result in devices that are safe and effective, and to establish methods and procedures to design, produce, and distribute devices that meet the quality system requirements.

Because the FDA's 21 CFR Part 820 regulation covers a broad spectrum of devices and production processes, it allows some leeway in the details of quality system elements. It is left up to manufacturers to determine the necessity for, or extent of, some quality elements and to develop and implement procedures tailored to their particular processes and devices. For example, if it is impossible to mix up labels at a manufacturer because there is only one label to each product, then it's not necessary for the manufacturer to comply with all of the GMP requirements under device labeling.

Certifications and awards

Organizations can participate in a continuing certification process to ISO 9001:2008 to demonstrate their compliance with the standard, which includes a requirement for continual (i.e. planned) improvement of the QMS, as well as more foundational QMS components such as failure mode and effects analysis (FMEA).[23]

The Baldrige Performance Excellence Program educates organizations in improving their performance and administers the Malcolm Baldrige National Quality Award. The Baldrige Award recognizes U.S. organizations for performance excellence based on the Baldrige Criteria for Performance Excellence. The Criteria address critical aspects of management that contribute to performance excellence: leadership; strategy; customers; measurement, analysis, and knowledge management; workforce; operations; and results.

The European Foundation for Quality Management's EFQM Excellence Model supports an award scheme similar to the Baldrige Award for European companies.

In Canada, the National Quality Institute presents the Canada Awards for Excellence on an annual basis to organizations that have displayed outstanding performance in the areas of Quality and Workplace Wellness, and have met the Institute's criteria with documented overall achievements and results.

The European Quality in Social Service (EQUASS) is a sector-specific quality system designed for the social services sector and addresses quality principles that are specific to service delivery to vulnerable groups such as empowerment, rights, and person-centredness.

The Alliance for Performance Excellence is a network of state and local organizations that use the Baldrige Criteria for Performance Excellence at the grassroots level to improve the performance of local organizations and economies. browsers can find Alliance members in their state and get the latest news and events from the Baldrige community.

Notes

This article reuses a few elements from the Wikipedia article.

References

  1. 1.0 1.1 1.2 1.3 Rocha-Lona, L.; Garza-Reyes, J.A.; Kumar, V. (2013). Building Quality Management Systems: Selecting the Right Methods and Tools. CRC Press. pp. 202. ISBN 9781466564992. https://books.google.com/books?id=i0sriCb7tLYC&pg=PA1. 
  2. Schlickman, J.J. (2003). ISO 9001:2000 Quality Management System Design. Artech House. p. 14. ISBN 9781580535960. https://books.google.com/books?id=FkQB4GRB7uwC. 
  3. Nanda, V. (2016). Quality Management System Handbook for Product Development Companies. CRC Press. pp. 352. ISBN 9781420025309. https://books.google.com/books?id=guizsuAAyR4C&pg=PA1. 
  4. ISO/TC 176 (2016). "ISO 9001:2015 for Small Enterprises: What to do?" (PDF). ISO. ISBN 9789267106946. https://www.iso.org/files/live/sites/isoorg/files/archive/pdf/en/iso_9001_2015_for_small_enterprises-preview.pdf. 
  5. 5.0 5.1 5.2 "What Is A Quality Management System (QMS)? ISO 9001 & Other Quality Management Systems". American Society for Quality. http://asq.org/learn-about-quality/quality-management-system/. Retrieved 03 November 2017. 
  6. Hendrickson, K.E. (2014). "Quality Assurance and Control". The Encyclopedia of the Industrial Revolution in World History. 3. Rowman & Littlefield. ISBN 9780810888883. https://books.google.com/books?id=EdwsCgAAQBAJ&pg=PA758. 
  7. Papp, J. (2014). Quality Management in the Imaging Sciences. Elsevier Health Sciences. pp. 372. ISBN 9780323261999. https://books.google.com/books?id=1akTBQAAQBAJ&pg=PA3. 
  8. Wood, J.C.; Wood, M.C., ed. (2003). Henry Ford: Critical Evaluations in Business and Management. 1. Taylor and Francis. pp. 384. ISBN 9780415248259. https://books.google.com/books?id=3XXxhbDU9P4C&pg=PA300. 
  9. 9.0 9.1 9.2 Gitlow, H.S. (2000). Quality Management Systems: A Practical Guide. CRC Press. pp. 296. ISBN 9781574442618. https://books.google.com/books?id=O5aq0HMyXOcC&pg=PA1. 
  10. "Total Quality". Learn About Quality. American Society for Quality. http://asq.org/learn-about-quality/history-of-quality/overview/total-quality.html. Retrieved 27 October 2017. 
  11. 11.0 11.1 11.2 11.3 "ISO 9002 and 9003: Is ISO 9001 a suitable replacement?". QMS International. 9 December 2017. https://www.qmsuk.com/news/iso-9002-and-9003-is-iso-9001-a-suitable-replacement. Retrieved 02 November 2017. 
  12. Cole, R.E. (1999). "Chapter 3: How Much Did You Know and When Did You Know It?". Managing Quality Fads: How American Business Learned to Play the Quality Game. Oxford University Press. pp. 63–81. ISBN 9780198028604. https://books.google.com/books?id=uBN7CYnaT74C&pg=PA67. 
  13. Schlickman, J.J. (2003). ISO 9001:2000 Quality Management System Design. Artech House. p. xxii. ISBN 9781580535960. https://books.google.com/books?id=FkQB4GRB7uwC. 
  14. 14.0 14.1 "ISO 9000 2015 Plain English Definitions". ISO Standards (In Plain English). Praxiom Research Group Limited. 4 February 2017. http://www.praxiom.com/iso-definition.htm. Retrieved 09 November 2017. 
  15. Payne, G.C.. "ISO 9001 Quality Manual". American Society for Quality. https://asq.org/quality-resources/iso-9001-quality-manual. Retrieved 09 November 2017. 
  16. "What is an ISO 9001 Quality Manual?". 9000 Store. Standards Stores. http://the9000store.com/articles/iso-9000-tips-what-is-a-quality-manual/. Retrieved 09 November 2017. 
  17. Meskovska, A. (23 October 2014). "How to structure quality management system documentation". ISO 9001 Knowledge Base. Advisera Expert Solutions Ltd. https://advisera.com/9001academy/knowledgebase/how-to-structure-quality-management-system-documentation/. Retrieved 09 November 2017. 
  18. Besterfield, D.H.; Besterfield–Michna, C.; Bestefield, G.H. et al. (2011). "Chapter 10: Quality Management Systems". Total Quality Management (Revised 3rd ed.). Pearson Education India. pp. 205–238. ISBN 9788131732274. 
  19. Lewis, M. (10 August 2015). "Data Quality Management for Better Big Data Analytics". Sciente Consulting Pte. Ltd. http://www.scienteconsulting.com/blogs/785/data-quality-management-big-data-analytics/. Retrieved 09 November 2017. 
  20. 20.0 20.1 "ISO 9001 Translated Into Plain English". Praxiom Research Group Limited. 16 August 2017. http://www.praxiom.com/iso-9001.htm. Retrieved 09 November 2017. 
  21. Siskos, Y.; Grigoroudis, E. (2002). "Measuring Customer Satisfaction for Various Services Using Multicriteria Analysis". In Bouyssou, D.; Jacquet-Lagrèze, E.; Perny, P. et al.. Aiding Decisions with Multiple Criteria. International Series in Operations Research & Management Science. 44. Springer Boston. doi:10.1007/978-1-4615-0843-4_20. ISBN 9781461508434. 
  22. 22.0 22.1 Fatima Chiaradia Valadão, A. de; Silva Campos, P.H. da; Turrioni, J.B. (2013). "Relationship between the Maturity of Continuous Improvement and the Certification of Quality Management System in Automotive Sector in Brazil". Independent Journal of Management & Production 4 (1): 96–110. doi:10.14807/ijmp.v4i1.61. 
  23. Poksinska, Bozena; Dahlgaard, Jens Jörn; Antoni, Marc (2002). "The state of ISO 9000 certification: A study of Swedish organizations". The TQM Magazine 14 (5): 297. doi:10.1108/09544780210439734.