Food Contact Rubbers 2 - Products, Migration and Regulation
The objective of Food Contact Rubbers 2 - Products, Migration and Regulation is to provide a comprehensive overview of the use of rubber as a food contact material, from an initial description of the types of rubber which are used in the industry, through the formulation of products, and the contact regulations and migration testing regimes, to the research that is on-going to improve its safety and the trends for the future.
Food Contact Rubbers 2 - Products, Migration, and Regulation are a completely revised and updated version of Rapra Review Report 119 published in 2000. Since that time a number of important developments have taken place, notably the beginning of the harmonisation of the legislation within Europe with the issuing of the Council of Europe (CoE) Resolution on rubber in 2004, and the FSA has commissioned a number of fundamental studies at Rapra into the potential migrants that are present in rubber products (FSA contracts FS2248, A03038 and A03046).
In contrast to plastics, rubbers are rarely used in the packaging of food products. Examples of where they are found include the use of rubber seals in flip top stoppers on beer bottles, rubber seals used in some jar tops, and the seal that is present in the ends of food cans. However, in the processing of food, there are a number of situations where significant contact of the food with rubber products can occur. This is due to the fact that the unique properties of rubber lead to it being used in a wide range of products, including conveyor belting, hosing, seals, gaskets, skirting and specific products such as milk liners. It is also the case that the range of contact conditions encountered (i.e., food type, contact temperature, time and area) mean that a wide variety of rubber types are employed. The contact times with food in processing situations tend to be short and the contact areas, apart from hose and belting, are small. This is in contrast to plastics which, when used as packaging materials, often have long contact times and large surface contact areas.
It is the need for knowledge in this area that has led the UK's Food Standards Agency (FSA) to fund a number of research projects at independent research organisations such as Rapra to look into the use of rubber as a food contact material.
Food Contact Rubbers 2 - Products, Migration, and Regulation comprises a concise, expert review, supported by an extensive bibliography compiled from the Polymer Library on the topic of rubbers in contact with food. This bibliography provides useful additional information on this topical field.
Food Contact Rubbers 2 - Products, Migration, and Regulation are a completely revised and updated version of Rapra Review Report 119 published in 2000. Since that time a number of important developments have taken place, notably the beginning of the harmonisation of the legislation within Europe with the issuing of the Council of Europe (CoE) Resolution on rubber in 2004, and the FSA has commissioned a number of fundamental studies at Rapra into the potential migrants that are present in rubber products (FSA contracts FS2248, A03038 and A03046).
In contrast to plastics, rubbers are rarely used in the packaging of food products. Examples of where they are found include the use of rubber seals in flip top stoppers on beer bottles, rubber seals used in some jar tops, and the seal that is present in the ends of food cans. However, in the processing of food, there are a number of situations where significant contact of the food with rubber products can occur. This is due to the fact that the unique properties of rubber lead to it being used in a wide range of products, including conveyor belting, hosing, seals, gaskets, skirting and specific products such as milk liners. It is also the case that the range of contact conditions encountered (i.e., food type, contact temperature, time and area) mean that a wide variety of rubber types are employed. The contact times with food in processing situations tend to be short and the contact areas, apart from hose and belting, are small. This is in contrast to plastics which, when used as packaging materials, often have long contact times and large surface contact areas.
It is the need for knowledge in this area that has led the UK's Food Standards Agency (FSA) to fund a number of research projects at independent research organisations such as Rapra to look into the use of rubber as a food contact material.
Food Contact Rubbers 2 - Products, Migration, and Regulation comprises a concise, expert review, supported by an extensive bibliography compiled from the Polymer Library on the topic of rubbers in contact with food. This bibliography provides useful additional information on this topical field.
1 Introduction
2 Rubber Materials and Products used in Contact with Food
2.1 Polymers Used in Food Contact Rubbers
2.1.1 Natural Rubber (i.e., cis-1,4-polyisoprene)
2.1.2 Nitrile Rubber
2.1.3 Ethylene-propylene Rubber
2.1.4 Fluorocarbon Rubber
2.1.5 Silicone Rubber
2.1.6 Thermoplastic Elastomers
2.1.7 Other Types of Rubbers
2.2 Additives Used in Food Contact Rubbers
2.2.1 Plasticisers/Process Oils and Fillers
2.2.2 Curatives and Antidegradants
2.2.3 Miscellaneous Additives
2.3 Rubber Products Used in the Food Industry and the Contact Conditions
2.3.1 Types of Rubber Product
2.3.2 Contact Areas
2.3.3 Contact Times
2.3.4 Contact Temperatures
3 Regulations Covering the Use of Rubber as a Food Contact Material
3.1 European Union Legislation
3.2 Council of Europe (CoE) Resolution on Rubber Products
3.2.1 Technical Documents
3.2.2 Product Categories
3.2.3 R Factors
3.2.4 Silicone Rubbers
3.3 Food and Drug Administration (FDA) in the USA
3.4 Bundesinstitut für Risikobewertung (BfR) German Regulations
3.4.1 Categories of Use
3.4.2 Silicone Rubbers
3.5 Other European legislation
3.5.1 Requirements in France
3.5.2 Requirements in the Netherlands
3.5.3 Requirements in Italy
3.5.4 Requirements in the United Kingdom
4 Assessing the Safety of Rubber as a Food Contact Material
4.1 Special Considerations When Using Rubber as a Food Contact Material
4.2 Migration Tests
4.2.1 Overall Migration Tests
4.2.1.1 FDA Regulations
4.2.1.2 BfR Regulations
4.2.1.3 CoE Resolution
4.2.2 Specific Migration Tests
4.3 Fingerprinting Potential Migrants from Rubber Compounds
4.3.1 Use of Gas Chromatography-Mass Spectrometry (GC-MS) to Fingerprint Food Contact Rubber Samples
4.3.1.1 Rubber Formulations
4.3.1.2 Experimental Conditions
4.3.2 Use of Liquid Chromatography-Mass Spectrometry (LC-MS) to Fingerprint Food Contact Rubber Samples
4.4 Determination of Specific Species in Rubbers and Migrants in Food Simulants and Food Products
4.4.1 Monomers
4.4.2 Plasticisers and Process Oils
4.4.3 Cure System Species, Accelerators, and their Reaction Products
4.4.4 Antidegradants and their Reaction Products
4.4.5 Oligomers
4.5 Research Studies Carried out at Rapra for the FSA
4.5.1 FSA Project FS2219 - Migration Data on Food Contact Rubbers
4.5.1.1 Introduction
4.5.1.2 Standard Rubber Compounds
4.5.1.3 Migration Experiments Carried out on the Standard Rubber Compounds
4.5.1.4 Results of the Migration Experiments
4.5.2 FSA Project FS2248 - Further Migration Data on Food Contact Rubbers
4.5.2.1 Introduction
4.5.2.2 Standard Rubber Compounds
4.5.2.3 Tests Carried out on the Seven Rubber Compounds
4.5.2.4 Results Obtained During the Course of the Project
4.5.3 Project A03038 - Rubber Breakdown Products
4.5.3.1 Introduction
4.5.3.2 Listing of the Breakdown Products for the CoE Curatives and Antidegradants
4.5.3.3 Factors Affecting the Formation of the Breakdown Products
4.5.3.4 Fingerprinting of the Breakdown Products
4.5.3.5 Migration Behaviour of the Breakdown Products
4.5.3.6 Overall Summary of the Migration Data
4.5.3.7 Overall Conclusions
4.5.4 Project A03046 - Silicones
4.5.4.1 Introduction
4.5.4.2 Potential Migrants in Silicone Rubbers - Stage 1 of the Project
4.5.4.3 Data Obtained on Commercial Silicone Rubber Products - Stage 2 of the Project
4.5.4.4 Overall Summary of the Project Findings
4.6 Published Migration Data
4.6.1 Food Contact Products
4.6.1.1 Teats and Soothers
4.6.1.2 Meat Netting
4.6.1.3 Rubber Gloves for Handling Food
4.6.2 Specific Chemical Migrants from Rubber Compounds
4.6.2.1 Alkylphenol and Bisphenol A
4.6.2.2 Peroxide Breakdown Products
4.6.2.3 Dimethyl Siloxanes and Other Components from Silicone Rubbers
4.6.2.4 Accelerators and Antidegradants
4.6.3 General Surveys
4.6.4 Analytical Techniques
5 Improving the Safety of Rubber as a Food Contact Material
5.1 Nitrosamines
5.2 Amines
5.3 Polyaromatic Hydrocarbons
5.4 Use of Alternative Compounds
6 Future Trends in the Use of Rubber with Food
6.1 Increased Use of Thermoplastic Rubbers and High Performance Rubbers
6.2 Developments in Additives
6.3 Surface Coatings and Modifications
6.4 Developments in Analytical Techniques
7 Conclusion
7.1 Sources of Further Information and Advice
7.1.1 Professional, Research, Trade and Governmental Organisations
7.1.2 Commercial Abstract Databases
7.1.3 Key Reference Books and Journals
7.1.4 Food Standards Agency Research Projects
Appendix 1
References
Abbreviations and Acronyms
Abstracts from the Polymer Library Database
Subject Index
Company Index
2 Rubber Materials and Products used in Contact with Food
2.1 Polymers Used in Food Contact Rubbers
2.1.1 Natural Rubber (i.e., cis-1,4-polyisoprene)
2.1.2 Nitrile Rubber
2.1.3 Ethylene-propylene Rubber
2.1.4 Fluorocarbon Rubber
2.1.5 Silicone Rubber
2.1.6 Thermoplastic Elastomers
2.1.7 Other Types of Rubbers
2.2 Additives Used in Food Contact Rubbers
2.2.1 Plasticisers/Process Oils and Fillers
2.2.2 Curatives and Antidegradants
2.2.3 Miscellaneous Additives
2.3 Rubber Products Used in the Food Industry and the Contact Conditions
2.3.1 Types of Rubber Product
2.3.2 Contact Areas
2.3.3 Contact Times
2.3.4 Contact Temperatures
3 Regulations Covering the Use of Rubber as a Food Contact Material
3.1 European Union Legislation
3.2 Council of Europe (CoE) Resolution on Rubber Products
3.2.1 Technical Documents
3.2.2 Product Categories
3.2.3 R Factors
3.2.4 Silicone Rubbers
3.3 Food and Drug Administration (FDA) in the USA
3.4 Bundesinstitut für Risikobewertung (BfR) German Regulations
3.4.1 Categories of Use
3.4.2 Silicone Rubbers
3.5 Other European legislation
3.5.1 Requirements in France
3.5.2 Requirements in the Netherlands
3.5.3 Requirements in Italy
3.5.4 Requirements in the United Kingdom
4 Assessing the Safety of Rubber as a Food Contact Material
4.1 Special Considerations When Using Rubber as a Food Contact Material
4.2 Migration Tests
4.2.1 Overall Migration Tests
4.2.1.1 FDA Regulations
4.2.1.2 BfR Regulations
4.2.1.3 CoE Resolution
4.2.2 Specific Migration Tests
4.3 Fingerprinting Potential Migrants from Rubber Compounds
4.3.1 Use of Gas Chromatography-Mass Spectrometry (GC-MS) to Fingerprint Food Contact Rubber Samples
4.3.1.1 Rubber Formulations
4.3.1.2 Experimental Conditions
4.3.2 Use of Liquid Chromatography-Mass Spectrometry (LC-MS) to Fingerprint Food Contact Rubber Samples
4.4 Determination of Specific Species in Rubbers and Migrants in Food Simulants and Food Products
4.4.1 Monomers
4.4.2 Plasticisers and Process Oils
4.4.3 Cure System Species, Accelerators, and their Reaction Products
4.4.4 Antidegradants and their Reaction Products
4.4.5 Oligomers
4.5 Research Studies Carried out at Rapra for the FSA
4.5.1 FSA Project FS2219 - Migration Data on Food Contact Rubbers
4.5.1.1 Introduction
4.5.1.2 Standard Rubber Compounds
4.5.1.3 Migration Experiments Carried out on the Standard Rubber Compounds
4.5.1.4 Results of the Migration Experiments
4.5.2 FSA Project FS2248 - Further Migration Data on Food Contact Rubbers
4.5.2.1 Introduction
4.5.2.2 Standard Rubber Compounds
4.5.2.3 Tests Carried out on the Seven Rubber Compounds
4.5.2.4 Results Obtained During the Course of the Project
4.5.3 Project A03038 - Rubber Breakdown Products
4.5.3.1 Introduction
4.5.3.2 Listing of the Breakdown Products for the CoE Curatives and Antidegradants
4.5.3.3 Factors Affecting the Formation of the Breakdown Products
4.5.3.4 Fingerprinting of the Breakdown Products
4.5.3.5 Migration Behaviour of the Breakdown Products
4.5.3.6 Overall Summary of the Migration Data
4.5.3.7 Overall Conclusions
4.5.4 Project A03046 - Silicones
4.5.4.1 Introduction
4.5.4.2 Potential Migrants in Silicone Rubbers - Stage 1 of the Project
4.5.4.3 Data Obtained on Commercial Silicone Rubber Products - Stage 2 of the Project
4.5.4.4 Overall Summary of the Project Findings
4.6 Published Migration Data
4.6.1 Food Contact Products
4.6.1.1 Teats and Soothers
4.6.1.2 Meat Netting
4.6.1.3 Rubber Gloves for Handling Food
4.6.2 Specific Chemical Migrants from Rubber Compounds
4.6.2.1 Alkylphenol and Bisphenol A
4.6.2.2 Peroxide Breakdown Products
4.6.2.3 Dimethyl Siloxanes and Other Components from Silicone Rubbers
4.6.2.4 Accelerators and Antidegradants
4.6.3 General Surveys
4.6.4 Analytical Techniques
5 Improving the Safety of Rubber as a Food Contact Material
5.1 Nitrosamines
5.2 Amines
5.3 Polyaromatic Hydrocarbons
5.4 Use of Alternative Compounds
6 Future Trends in the Use of Rubber with Food
6.1 Increased Use of Thermoplastic Rubbers and High Performance Rubbers
6.2 Developments in Additives
6.3 Surface Coatings and Modifications
6.4 Developments in Analytical Techniques
7 Conclusion
7.1 Sources of Further Information and Advice
7.1.1 Professional, Research, Trade and Governmental Organisations
7.1.2 Commercial Abstract Databases
7.1.3 Key Reference Books and Journals
7.1.4 Food Standards Agency Research Projects
Appendix 1
References
Abbreviations and Acronyms
Abstracts from the Polymer Library Database
Subject Index
Company Index
Dr. Martin Forrest started his career in 1977 with James Walkers & Co. Ltd, and during this time he progressed to the position of Rubber Technologist, having obtained his first degree in Polymer Technology at the London School of Polymer Technology (LSPT). In 1983 he started a full time Master of Science course in Polymer Science and Technology at the LSPT.
After being awarded his MSc in 1984, he completed a PhD in Polymer Chemistry at Loughborough University in 1988. He then joined Rapra Technology as a Consultant in the Polymer Analysis section and remained in that section until 2006, rising to the position of Principal Consultant. During his time in the Polymer Analysis section, Dr. Forrest was the main contact at Rapra for consultancy projects involving the analysis of rubber compounds and rubber based products. During his 20 years at Rapra he has also managed a number of FSA, TSB, and EU funded research projects, and since 2006 he has been a Project Manager for the Research Projects Group.
After being awarded his MSc in 1984, he completed a PhD in Polymer Chemistry at Loughborough University in 1988. He then joined Rapra Technology as a Consultant in the Polymer Analysis section and remained in that section until 2006, rising to the position of Principal Consultant. During his time in the Polymer Analysis section, Dr. Forrest was the main contact at Rapra for consultancy projects involving the analysis of rubber compounds and rubber based products. During his 20 years at Rapra he has also managed a number of FSA, TSB, and EU funded research projects, and since 2006 he has been a Project Manager for the Research Projects Group.