f,AW OFFICES Keller and Heckman JOSEPH E. KELLER 1712 N STREET, S. W. JEKOMt H. HECKMAN CHARGES M. MEEHAN WILLIAM H.BOROHESANI.JR. ROBERT R. TIERNAN WAYNE WASHINGTON, D.C. £0030 TELEPHONE 290-2700 CABLE ADDRESS "KELMaN'* October 27, V. BLACK 1967 To the Members of the SPI Food Packaging Materials Committee Re: Food and Drug Administration Proposed Food Additives Procedural Regulations (32 Fed. Reg. 152, p. 11443) Gentlemen: The main purpose of this letter is to supply you with copies of some correspondence we have just received from Bob Miller of Hercules whereby Bob has advised us in detail about a set of comments filed by Dr. John Frawley in response to the Food and Drug Administration's Notice of Proposed Rulemaking referenced above. As you will note, we are herewith enclosing (1) a copy of Bob's letter to us of October 24, (2) a copy of Dr. Frawley's letter to the Food and Drug Administration dated October 23, and (3) a copy of Dr. Frawley's latest article which appears in the August 1967 issue of Food and Cosmetics Toxicology, and which is directly referenced in his comments to FDA. Generally speaking, we think you will find this material self-explanatory. Suffice it to say that we are most pleased to know about Dr. Frawley's filing and commend it to you. Indeed, we fully expect to add SPI's support to Dr. Frawley's recommendations in the comments we are now draft­ ing, and agree with Bob Miller that it could be very helpful if as many of you as possible see fit to support the point of view expressed by means of your own letters to the FDA Hearing Clerk. ASI-PR 0000438 T - 2 - While writing to inform you about the Hercules filing, let us also take this opportunity to bring you up to date on our own efforts. We have already had one meeting with your special Procedural Regulations Subcommittee and have made considerable progress in drafting the SPI comments. We are now anticipating a mailing to the Subcommittee of a semi-final draft of the comments over this coming weekend, after which we shall probably have another meeting on November 1. Our comments will be considerably more exten­ sive than Dr. Frawley's. As a matter of fact, with all of the presently projected attachments, the comments could constitute a submission of more than 100 pages since, among other things, our plan is to use this opportunity to make such items as the ACS papers and our Guidelines comments a matter of more formal record with the Food and Drug Administration. In other words, since this is really our first opportunity to put all relevant documentation about the difficulties industry experiences with the Food Additives Amendment into a formal FDA docket which will be more conveniently subject to future reference and possible follow-up proceedings, we plan to submit everything we have to support our objections to the way in which the law is being administered. In light of the way in which the Food and Drug Administration has limited the time available to submit comments, it is unlikely that we shall be able to pre-circulate our document other than to the Procedural Regulations Subcommittee. However, you may be assured that we shall send all Committee members copies of our final comments as soon as the filing has been completed. We hope that this letter will serve to bring you up to date while we are continuing our work on this project but please do not hesitate to let us know if you have any questions, or desire any further interim information. ASI-PR 0000439 HERCULES INCORPORATED MEDICAL DEPARTMENT HERCULES TOWER • 910 MARKET STREET • WILMINGTON. DELAWARE I989S • <3021 856-9811 October 2k, 1967 Mr. Jerome H. Heckman Keller and Heckman 1712 N Street, N. W. Washington, D. C. 20036 Dear Jerry: As we have discussed I am enclosing a copy of the letter we have sent to the Hearing Clerk of the Food and Drug Administration concerning the proposed changes in the Food Additives Procedural Regulations.. We agree that the SPI Food Packaging Materials Committee should submit its comments and objections to the proposed regulations and are very much in favor of those to be submitted. However, since FLA has opened the door for comments on changes in the procedural regulations, we believe this is an excellent opportunity to present Dr. Frawley's proposal and try to bring it into the open. We believe his letter to the Hearing Clerk complements the SPI comments and does not conflict in any way. As you know. Dr. Frawley's BIBRA paper containing his proposal was published in the August 1967 Food and Cosmetic Toxicology Journal and copies have been sent to the Hearing Clerk. We have received permission from the publisher to submit copies to members of the SPI Food Packaging Materials Committee. We also have submitted copies of the enclosed letter and the BIBRA paper to the American Paper Institute. We would like to have the members of the SPI Food Packaging Materials Committee be informed of our letter to the Hearing Clerk as well as Dr. Frawley's paper and you indicated you could distribute them to the membership. If any individual or company member of the Committee shares our concern and agrees with this proposal, we would welcome supporting letters to the Hearing Clerk. The deadline for receipt of comments is November 6. Sincerely, Robert M. Miller Technical Services Administrator RMM: wh Enclosure cc: G. W, W. Ingle ASI-PR 0000440 HERCULES INCORPORATED MEDICAL DEPARTMENT HERCULES TOWER • 910 MARKET STREET • WILMINGTON. DELAWARE 19899 • (302) 636-9811 October 23, 1967 Hearing Clerk Department of Health, Education, and Welfare Room S440 330 Independence Avenue, S. W. Washington, D. C, 20201 Re: Food and Drug Administrations' Proposed Food Additives Procedural Regulations (32 Fed. Reg. 152, p. 11443) Dear Sir: I wish to concur with the stated objective of the Food and Drug Administration that the Procedural Food Additive Regulations should be revised "to expedite their scientific review," and to reduce the "unnecessary burden that wastes the time and efforts of both Administration and industry scientists." Having been a scientist in the Administration, as well as in industry, I share the concern of the Administration over the increasing use of your experts on nonproductive assignments. This concern is one which scientists inside and outside government consider to be a major threat to a continued unblemished record of consumer health protection currently shared by the Administration and the industry. However, after careful review of the proposed changes in the procedural regulations for food additives, I have concluded that the Administration has overlooked one of the major obstacles to efficient and effective use of industry and-Administration scientists, because no recognition has been given to the inherent safety ofcertain uses of incidental food additives and no procedure has been provided to eliminate such uses from the same exhaustive scientific evaluation and administrative review required of more hazardous applications. If we are to provide the public the degree of protection to health which we are morally and legally dictated to provide, we must find some mechanism for expending our limited resources, both manpower and finances, in a manner appropriate to the relative risk. Under the current regulations and the proposed revisions, no opportunity is provided for this. In the field of food packaging I do not think we should direct any criticism toward any individual or group for failure to incorporate such provisions into the existing regulations adopted in 1959. At that time the potential health hazard from food packaging was poorly defined and scientists in industry and government, including myself, were unwilling to assign a lower risk to any use of a food packaging component. However, after many years and ASI-PR 0000441 Hearing Clerk Page 2 October 23, 1967 many millions of dollars for research, the potential hazard from food packaging has been clearly defined as remote and in some cases nonexistent, and to continue to perpetuate this wasteful endeavor is beneath the dignity of a scientist and contrary to the best interest of public health. As a first step toward elimination of this waste of our resources on predictably nonprofitable research, I conducted a review and analysis of as much of the biological and other research bearing on food packaging as I could obtain. I was assisted in this endeavor by scientists in industry and govern­ ment who contributed published and unpublished reports for this review. In September 1966, I summarized my conclusion at a symposium on food packaging held by the American Chemical Society and in January of this year I presented more extensive evidence in support of my conclusion at the Annual Scientific Meeting of the British Industrial Biological Research Association in*London. This latter presentation together with a complete documentation of supporting data has now been published in Food and Cosmetics Toxicology Journal, Volume 5, No. 3, page 293, 1967. Copies of these papers are enclosed. The basic conclusion which can be drawn from our experience is that any material, suitable for use as a functional component in a food package or container, at a level of 0.2% or less cannot become a component of food at an unsafe level. Consequently, uses of such materials are generally recognized as safe and exempt from the Food Additives Amendment. The overwhelming support which I have received from scientists in government, university, and industry, not only indicates the general concern of the scientific community, over the waste of scientific talent, but justifies the conclusion that these uses are exempt on the grounds that they are "generally recognized, among experts qualified by scientific training and experience-----to be safe." Therefore, I encourage the Administration to concur with the scientific community on this conclusion and recommend that the Administration on its own initiative exempt food additive components used at 0.2% or less from the new administrative procedures. Specifically, this can be accomplished by publishing an amendment to Regulation 121.2500 to include a new subparagraph (2) (d) (5) as cited below. Such action will satisfy many of the objections already filed with the Hearing Clerk by others regarding the proposed changes in the Regulation. The suggested change in subparagraph (2) (d) is presented below with the only change being the addition of subparagraph (5) as underlined. (d) Substances that under conditions of good manufacturing practice may be safely used as components of articles that contact food include the following, subject to any prescribed limitation: (1) Substances generally recognized as safe in or on food. (2) Substances generally recognized as safe for their intended use in food packaging. (3) Substances used in accordance with a prior sanction or approval. HERCULES ASI-PR 0000442 Hearing Clerk Page 3 October 23, 1967 (4) Substances permitted for use by regulations in this Subpart F. (5) Substances used at a level of no more than 0.2% by weight of the container or no more'than' 0.2% by weight of the coating or other surface treatment, provided tnese substances are not heavy metals, as defined in Foofl"ChemicVlsToHex, or pesticides, as defined in the Federal lnsecticrde","RodenticicTe and Fungicide Act. Addition of this new subparagraph to regulation 121.2500 appears logical because it automatically incorporates the other restrictions of good manufacturing practice to the food packaging uses of these trace components; for example, that the amount used in the container shall not exceed that which is "reasonably required to accomplish the intended physical or technical effect," that the purity shall be "suitable for its intended use" and that the uses shall not violate any other provision of the Federal Food, Drug and Cosmetic Act. I submit this proposal for your careful study and consideration and recommend its adoption. Sincerely, John P, Frawley, Ph.D. Chief Toxicologist JPF/eaw Attachments ASI-PR 0000443 Mfincuusm Fd Cosmet. Toxicol. Vol. 5, pp. 293-308. Pcrgamon Press 1967, Printed in Great Britain ( 1 BIBRA Annual Scientific Meeting* * ; ; ■ ] , i Scientific Evidence and Common Sense as a Basis for Food-Packaging Regulations J. P. Frawley 4 Hercules Incorporated, Wilmington, Delaware 19899, USA , A I am honoured by your invitation to meet with you tonight and to discuss with you some of the problems associated with assuring the safety of food-packaging materials. However, I am equally humbled by my own inadequacies to discuss our subject matter-as expertly as it deserves. Unfortunately for all of us, there is no individual who can be considered an expert on all aspects of food packaging. Although essentially all of the individual components used in food packaging originate in a chemical plant, the technology for formulating and converting these materials into useful containers varies with every substrate, whether it is plastics, paper or metal. Moreover, the marketing relationship between producer, formulator, converter and the food industry is notably different for each segment of this complex industry, Consequently, it is a formidable task to become an expert for even one aspect. Each of you here this evening possesses expert knowledge in one or more aspects which I wish I had. It is unfortunate that telepathic communication has not reached my level of intellectual development, so I could benefit from your experience. In fact, the only thought waves reaching me suggest that many of you should be delivering this lecture rather than I. Therefore, if you will consider me to be a substitute speaker, you may be a little more tolerant towards my remarks. When was the last time you sat down in the solitude of your study and attempted to write out a geometrical proof that the shortest distance between two points is a straight line ? Most of us would have a difficult time doing it today because, as you recall, it is not sus­ ceptible to proof. It must be accepted. Indeed, some of the most difficult things in life to prove are the obvious ones. A number of months ago, I sat down to try to prove something which was obvious to me—that there are some uses of food-packaging materials which cannot involve any hazard to health of the consumer of food. I had no preconceived idea of the end point I would reach, but it seemed like it would be fun. Sometimes now I wish I had resisted the temptation and invested my time in some other form of recreation. My main exercise was to try to determine a level of use of any food-packaging component which could be considered safe regardless of its degree of toxicity. Many of you know the conclusion I reached; namely, that any component of a food container or coating which is •Editor’s note: This paper was delivered to the Fifth Annual Scientific Meeting of the British Industrial Biological Research Association (BIBRA), held in London on 25 January 1967. The Annua) Scientific Meeting, instituted in 1962, provides an opportunity for members and guests of the Association to receive an address from an eminent toxicologist on a topic related to BIBRA’s field of intetest. Previous speakers have been Professor H. C. Hodge, Dr. A. J. Lehman, Professor L. J, Goldwater and Dr. J. M. Barnes. 293 HM ASI-PR 0000444 294 1. T. I'KAWLI'.Y present at 0-2% or less is safe beyond any reasonable doubt, and consequently, should not be subject to government regulations. When I first advanced this proposal, it was presented within the framework of existing legislation in my country, as a mechanism for correcting some of our mistakes. Tonight, 1 shall cast my remarks in a different vein, since your country has not yet committed itself to a regulatory procedure on packaging materials. I do not pretend to be able to propose the best regulatory procedure for Great Britain. There are too many aspects of your business and government operations which I do not understand. However, { can review some of the evolutionary history of our regulatory procedure and suggest some ways to avoid the mistakes we have made. According to the title of my lecture, 1 am scheduled to talk about scientific evidence and common sense. For no particularly good reason, I am going to reverse this order and address myself to the common-sense aspects of food-packaging regulations first. It has always seemed axiomatic to me that in all matters of environmental health, the degree of hazard should define the degree of control. The amount of attention devoted to each problem should be in relation to the hazard. To distribute our limited efforts on any Mother basis is a form of gambling with public health. Unfortunately, in this decade of doubt, the scientific community has little control over the area of its explorations. For the most part, the decision is made by national governments as to which area of environmental health should receive concerted attention and at least in the United States, these decisions are not always made on the basis of relative hazard to health. This certainly has been the case for food-packaging materials and it appears that many countries are prepared to follow in our footsteps. In order to give a certain degree of perspective (which 1 believe is the foundation of com­ mon sense) in this matter, let us reflect on a few of the sources of environmental exposure to chemicals. Obviously the overwhelming majority of the chemicals to which we are exposed are the natural ones which constitute our diet. We tend to overlook these and seem to be content in assuring society that synthetic chemicals will not cause more disease than we already have. Reluctantly, I shall dismiss any further comments on these natural products except to note that it is refreshing to have Dr. L. Goiberg and the BIBRA staff occasionally remind us of our prejudice. If we restrict ourselves to a consideration of synthetic chemicals contributed to our environment, certain obvious sources come to mind: drugs, pesticides, food additives, air pollutants, water pollutants, cosmetics, occupational exposures, household chemicals and food-packaging. As I have already suggested, logically, the amount of time and attention devoted to each of these areas should be in relation to the hazard to health. Sometimes the hazard to health is difficult to evaluate until a significant amount of time and money has been invested. However, after the degree of hazard has been defined, we have the responsi­ bility of accepting the facts and of adjusting our effort accordingly. In recent years, in the United States, we have invested more industry, government and university time and money on food-packaging materials than on any environmental health problem other than pesticides and drugs. At the same time we have constructed a complex and restrictive maze of government controls which is too involved to be understood by the regulated industries. After 8 yr of effort we have now clearly demonstrated that the fetum on our investment has been negligible and that the health hazard is slight in comparison with other sources of chemical exposure. Consequently, I believe we have a responsibility to the public of restoring a more equitable balance to our programme. By an equitable balance, I do not mean that we should ignore ail aspects of food packaging, but find some ASI-PR 0000445 FOOD-PACKAGING CONTROL 293 common-sens* approach to allow us to concern ourselves with potential hazards and not with predictably safe practices. It is to this assignment that I applied myself last summer—to try to develop a scientific basis for a start, and only a start, towards a common-sense approach to food-packaging regulation. However, before proceeding with the scientific evidence I have collected and the conclusions I have drawn, I have made two statements which require documentation. First, that the return on our investment has been negligible and second, that our regulatory scheme has been too complex to serve its intended purpose. Following enactment of our law, the major task facing the industry was evaluation of current industry practices. Many of you are familiar with some of the larger research programmes undertaken by different segments of the industry, for example, the petroleum wax studies by the American Petroleum Institute, the can enamel studies by the can pro­ ducers and the rosin product studies by Hercules. Many other programmes which received less publicity were conducted on regenerated cellulose, polyethylene and other polymers, paper coatings and wet strength resins, to mention only a few. The net result of this invest­ ment of millions of pounds has been that more than 90% of the prior industry practices have been confirmed as safe, through a combination of low toxicity and low migration, and have been endorsed by our Food and Drug Administration (FDA), by inclusion on our permissive list. This general endorsement of the vast majority of industry practices testifies to the fact that most uses of packaging materials are inherently safe. However, before sufficient facts were accumulated to confirm the low degree of hazard associated with packaging materials, we had committed ourselves to an "omnibus” per­ missive list, containing every conceivable chemical which might even remotely come in contact with food. We now have 94 separate food-packaging regulations or lists dealing with different uses of packaging chemicals, from 967 ingredients* for adhesives to 8 ingre­ dients for zinc-silicon dioxide matrix coatings. These regulations contain over 43,000 words, about 10,000 words more than the regulations for all intentional food additives. In 1966 alone, the 8th yr of the law’s existence, over 200 new uses of packaging chemicals were approved and published in our Federal Register. Even a superficial examination of these regulations reveals that the vast majority of these words are devoted to the enumeration of thousands of chemicals for one or more specific uses under which most cannot migrate to food at an unsafe level, regardless of their degree of toxicity. Unless you work with these regulations on a daily basis, are familiar with the multiple cross-references and have sufficient technical training to understand what chemicals are covered by some of the vague generic terms, it is almost impossible to determine the approved uses of a given chemical. We have created a complex maze of regulations, too lengthy and involved to be understood by most of the regulated industry, with the unanticipated result of a growing apathy towards correct interpretation. This type of “omnibus” permissive list came about in the United States at the insistence of some segments of industry, coupled with a change in interpretation of our laws by the FDA—a change which revoked the long-established principle of de minimis non curat lex (the law does not concern itself with trifles) by claiming that the law does not recognize any level of a chemical as insignificant. This denial of the existence of a toxicologically-insignificant level or biological zero is analagous to a denial of the existence of night, on the grounds that you cannot prove the absence of light. In all countries outside the United *967 does not count the numerous reaction products cleared for one or more of these chemicals. If these are counted, the number exceeds 3800. ASI-PR 0000446 296 J. P. FRAWLEY States, the term toxicological insignificance has real meaning and significance. I believe it is a sound scientific principle which must be preserved and eventually I hope will be restored in my country. It is this principle which I believe is the very crux of intelligent commonsense regulation of food-packaging materials. Let us take stock. Experience has taught us that most uses of food-packaging materials are safe beyond any reasonable doubt. Experience has also taught, at least in the United States, that an “omnibus” permissive list not only diverts the energies of our corporations, government and universities into predictably unprofitable research, but can lead to some, if not general disregard for the law. This leaves us with the conclusion that some mechanism should be found for subjecting to a permissive list only those uses of packaging materials which pose a potential hazard to health; that is, constructing a “non de minimis list” or “relevant” list. Here is where I invite each and everyone of you to sit down and define those uses which can be assumed to be safe. As I stated earlier this exercise sounds like fun, but it is just plain hard work. I am not certain that my solution is the best, but I assure you it is the result of many hours of reflection and analysis. In its briefest form, I believe that any chemical suitable for use in food-packaging is safe for man at a level of 0-1 ppm in the total diet. Extrapolating this dietary concentration to a practical and meaningful guideline for regulatory purposes, use of a chemical in a container at a level of 0-2 % or less will contribute less than 0T ppm to man’s diet. On the surface, this may not appear to propose a major improvement, but application of this guideline would permit deletion of 75% of the citations in the United States regula­ tions and I am certain would permit more efficient use of manpower, in establishing permissive lists in other countries. I do not ask that you accept this conclusion on faith. So, as briefly as possible, I should like to review the scientific basis for this conclusion. First of all, what level of a compound, which is suitable for use in food packaging, but of unknown toxicity, can be assumed to be safe in the human diet? I know of no better approach to answering this question titan to examine our toxicological experience and tabulate the experimentally determined safe level for all the compounds which have been studied. Because 90-day toxicity studies are-generally considered inadequate for calculation of safe levels and because only a small number of these are published, I decided to review as many 2-yr chronic toxicity studies as I could find and to tabulate tKe"“no-effect” level confirmed for each. I can make no claim that I have found every 2-yr chronic toxicity study which has been conducted. I can only claim that I have tabulated the “no-effect” levels from every chronic study which I could find, without any selection or rejection except irradiated foods. In total, I was able to locate 2-yr chronic toxicity studies on 220 different substances (see Appendix), and although this may seem like a modest number, it represents between 4 and 7 million pounds in toxicolpgical research. Last September I had been able to locate only 143 such studies, but with the co-operation of many of my colleagues in the field of toxicology, I estimate that I now have collected about 90% of all such studies which have been conducted. Table 1 presents the distribution of "no-effect” levels for all of the 220 compounds. It is apparent from Table 1 that a small percentage of compounds will be extremely toxic—having a “no-effect” level in experimental animals below 1 ppm, but that the majority will exhibit no toxic effect even at 100 ppm. Only 19 of the 220 compounds demonstrated ASI-PR 0000447 POOD-PACKAGING CONTROL 297 Table 1. Distribution of "no-effect" levels in 2-yr chronic studies •‘No-effect" level (ppm) All compounds (220) <1 <10 <100 <1000 <10,000 5 19 40 101 151 any toxic effect below 10 ppm. We might conclude that the odds of detecting a toxic effect at 10 ppm from any “unknown” compound are approximately 1 in 10. Let us now look at Table 1 a little more closely and examine the nature of these 19 compounds which had a “no-effect” level at 10 ppm or less. Table 2 shows the same in­ formation as Table 1, except two additional columns have been added which subdivide these 220 compounds into two categories: (1) a “heavy metals and pesticides” category and (2) an "all other compounds” category. I believe this breakdown is worthy of careful examination. The most apparent conclusion is that all 19 of the compounds, which were toxic below 10 ppm, were pesticides and heavy metal compounds. Equally significant is the fact that 39 of die 40 compounds, which had “no-effect” levels below 100 ppm in experi­ mental animals, were also pesticides or heavy metal compounds. The only compound in the “all other compounds” category which was toxic below 100 ppm was acrylamide. Table 2. Distribution of “no-effect" levels in 2-yr chronic studies "Norfleet” level_ (ppm) <1 <10 <100 <1000 <10,000 _ All compounds (220) _ ___ Heavy metals and pesticides (88) Others (132) J 19 40 101 151 5 19 39 72 86 0 0 1 29 65 It is obvious that the degree of toxicity of pesticides and heavy metals (which were used as pesticides at one time) is quite different from that of other commercial chemicals. This should represent no surprise because pesticides are synthesized, screened and selected for their toxicity to one or more forms of life before becoming commercial products. This contrast is more clearly shown by Fig. 1 which depicts the distribution of “no-effect” levels for the two categories of chemicals. It is obvious that the average toxicity of a pesticide is about 100 times as great as the average for other chemicals. ASI-PR 0000448 298 S. P. FRAWLEY Therefore, if we exclude heavy metals and pesticides from our consideration, experience has indicated that only a very occasional (fewer than 1 out of 100) commercial compound will have a "no-effect” level below 100 ppm and that an infinitely small number will exhibit any toxicity at 10 ppm or less. Olttary no - flftcf Igval, ppm Fio, 1. Histogram showing distribution of “no-effect” levels in 2-yr chronic studies on 220 compounds. Shaded areas denote pesticides and heavy metals, and blank spaces other chemicals. Now if we apply the conventional 100-fold margin of safety to these experimentally determined “no-effect” levels, all 132 of the non-pesticidal chemicals are safe for man’s diet at a dietary concentration of 0-1 ppm or higher. Many of these materials are used at much higher levels in food, but had we assumed that they were all safe at 0-1 ppm and permitted their use up to that level without toxicity studies, we would have been correct in 100% of the cases and would not have exposed the public to any health hazard. For accuracy, I should point out that in the above calculation I have dealt only in orders of magnitude. If these “no-effect” levels are subdivided into small groups as 10, 30,100 or 300 ppm, it can be concluded that all were safe to animals at 30 ppm. Moreover, I did not take into consideration the larger food consumption per kg of body weight of rats and dogs versus man. Combined, these additional calculations show that the 0-1 ppm level in the human diet provides less than 1/1000th the mg/kg/day intake of the most toxic of the 132 compounds. Some may argue that I have been unnecessarily conservative, and perhaps I have been. Now let me consider briefly the other aspect of our problem—migration t6 food—and attempt to develop some guidelines which will tell us which uses may contribute more than 0-1 ppm to the diet of man, and which uses cannot. First of all, it is .obvious to everyone that any major component of a food container must be assumed to possess the capability of migrating to food at a level in excess of 0-1 ppm, unless proven otherwise. However, it is equally obvious, that some uses will not contribute 0-1 ppm to the diet. Our problem is to And this dividing iine. Undoubtedly, this dividing line is different for each type of substrate. It will be different for films than for bottles. It will be different for one polymer than for another. We could establish a whole series of levels for each food-packaging substrate and its intended use, but most of these differences are not sufficient to justify complication of regulations. Therefore, in order to determine the level of addition which would contribute less than 0-1 ppm to the diet with all types of substrates, I selected the substrate which is the most permeable and susceptible to extraction by food, namely, papei. In addition I have selected ASI-PR 0000449 299 FOOD-PACKAGING CONTROL an additive which is very readily extracted from its substrate, namely, rosin size. This combination of substrate and additive, I believe, represents the most extreme case of migration and values determined from rosin sized paper should represent a maximum for any component of any packaging media. Indeed, such data would be excessive for most uses of packaging components. In our initial efforts to study the migration of rosin size from paper, we used typical simulated solvents: various aqueous solutions, hexane, maize (or com) oil, etc. This was wasted effort because, in water and oil, the extraction was a direct function of time and temperature and did not plateau until essentially 100% of the rosin size was extracted and the integrity of the paper sheet was destroyed. Nevertheless a century and a half of experience has shown paper to be a satisfactory packaging material. Although these studies clearly demonstrated that rosin sized paper would be an appropriate choice for developing maximum migration data, they contributed nothing to the evaluation of safety of rosin size which was our principal motive at that time. As a consequence of this failure of the simulated solvents test to help define the amount actually migrating to food, we prepared radioactive samples of rosin size, incorporated them into typical commercial paper and paperboard at known levels, packaged a yride variety of food in contact with these paper samples at typical package ratios, stored them at typical storage temperatures for typical storage times and determined the rosin size content of each food by counting the radioactivity. The study was far more extensive than I shall describe, because we used several types of paper (greaseproof, waxed, unwaxed, etc.), containing three different levels of- rosin size, 24 different types of food (water, ice-cream, oysters, apricots, green beans, dry breakfast f i I \ % * K ri t t i Table 3. Maximum migration of rosin size• from uncoaitd paper under typical storage conditions Food Milk products Water Ice-cream Vegetables Green beans Green beans Lettuce Potatoes Meats Ground beef Chicken Beefsteak Sausage Fruits Apricots Apples Grain products Puffed rice Wheaties Flour Doughnuts Others Sugar Butter Temperature (°F) Time (days) Migration (ppm) 34 10 14 28 59 0-3 34 72 34 72 7 14 7 28 1-3 41 2-4 0-2 34 34 34 34 5 3 7 5 8-7 7-2 49 124-0 72 72 28 28 0-1 1-2 72 34 72 72 14 28 28 3 5-8 7-0 0-2 0-9 72 34 28 14 0-2 32 8 9*V. in paper. ■ ASI-PR 0000450 J. P. FRAWLBY 300 { food, sugar, doughnuts, ground beef, butter, bacon, sausage, to name just a few) and anal­ ysed each sample at several different storage intervals and temperatures. For our purposes, I have selected only the uncoated and unwaxed paper and only the maximum migration levels obtained for the 18 commodities packaged in these uncoated papers under typical commercial storage conditions. Admittedly this gives unrealistically high values for rosin size which are not typical of industry practice, but for our present purposes, the worst case must be presented. K Table 4. Calculation of maximum migration of rosin size* to total diet Commodity group Milk products Vegetables Meats Fruits Grain products Sugar Butter, oils Percentage of diet 31 20 18 13 10 5 3 Average migration (ppm) ' 31 20 38-2 0-5 3-5 02 32-8 Contribution to total diet (ppm) 10 0-4 69 01 04 00 0-9 Total ... 9-7 •4% in paper. .. i i : / ■'t i Table 3 shows the maximum migration value for 18 food commodities at various typical storage times and temperatures when exposed to paper containing an average of 4% rosin size. It is obvious from some of these values that high levels of migration can occur with some foods, whereas other foods contain much less rosin size. The data in Table 3 can be quickly considered since the individual values are of no great significance, but the com­ posite of these values can be helpful. Table 4 shows the average consumption of these various commodity groups in the USt, the average migration to that commodity group and a calculation of the maximum level of rosin size in the average total diet, if 100% of the diet were packaged in uncoated paper containing 4% rosin size. Undoubtedly there are some differences in dietary habits between our countries, but I doubt that they would significantly alter the calculation. As I mentioned previously, three different sizing levels were used in these studies. Table 5 shows the final dietary calculations for the same foods, under the same conditions for paper containing 2 or 1 % rosin size. The extrapolation is remarkably good. The last column shows the migration in ppm expressed on the basis of a unit of 1 % rosin size in the paper or container. For each per cent addition to the container, man’s diet would contain a maximum of 2 ppm of the additive, if the entire diet was in contact with that container. One further calculation is necessary in order to arrive at a realistic determination of the ff r f Tabic S. Maximum migration of rosin size to diet 0 Level of sire in paper (%) 4 2 1 Migration (ppm) 9-7 4-4 19 ppm1% 2-4 2-2 19 fU.S. Department of Agriculture Dietary Evaluation of Food Used in Houaeholds in * ^ ■ 1961. " k I* ASI-PR 0000451 ; FOOD-PACKAGING CONTROL 301 level of addition which will contribute no more than 01 ppm to the diet. Obviously, 100% of man’s diet is not in contact with paper, or any other single type of food container. There are five major types of food container substrates, glass, metal, paper, plastics and regenerated cellulose. In addition, there is a significant portion of food which is not packaged or is packaged in bulk so that most of the individual units are never in contact with the container. It is impossible to get reliable figures revealing the percentage of the food-pack­ aging market shared by each type. However, it is conservative to assume that no more than 25 % of man’s diet is in contact with any given type of food packagejpr packaging additive. Table 6 shows this final calculation of the maximum migration to the diet which would result from the use of a component at a level of 1 % in the container (as directly measured from the rosin size experiments) and the maximum migration from a level in the container of 0-2 %. Undoubtedly, this calculation is an exaggeration for most uses of packaging com­ ponents which possess greater insolubility or which are used in substrates more resistant to penetration than paper. Nevertheless, it permits the conservative conclusion that any compon­ ent of an article contacting food which is present in the article itself or its coating at a level of 0-2 % or less by weight will contribute to the diet a level which can be of no possible public health significance. Consequently, such trivial uses should not be included on lists of components permitted in food packaging. Table 6. Calculation of maximum contribution to the diet 2 ppm/each % Maximum total diet migration Maximum diet in contact Concn in Maximum concn package in diet (ppm) <50 0-5 10 0-2 01 As most of you know, I submitted this conclusion to the profession and to the industry in the United States last September. It was worded differently, by describing a level of 0*2% as GRAS*, because of the particular structure of our law. It has received overwhelming and gratifying support and only a few questions have been raised. Our own Food and Drug Administration has authorized me to tell you that they are giving it serious consideration, but could not reach a decision prior to this meeting. At this point, I can only say that after 6 months, I am even more convinced that the conclusion is sound and conservative; and, that it offers a common-sense approach to a reduction in the extensive waste of time and money of both industry and government on problems which can be of no possible public health significance. From a regulatory point of view, I believe it offers one mechanism of avoiding preparation and constant modification of an omnibus permissive list which experience has shown becomes so unwieldy and com­ plicated as to invite disregard. I do not believe that type of situation is in the best interest of the consumer, industry or government. Now I have intentionally reserved for my closing remarks a discussion of the few questions and mental reservations about this proposal which have been raised by groups throughout the world. Perhaps, some of these points will answer some of the questions you would like to raise. ■•Generally recognized as safe. l• ASI-PR 0000452 302 J. P. FRAWLEY The most frequent comment is a concern that despite our toxicological experience to date, we cannot assume that the next compound will not be toxic at 0.1 ppm. The same basic concern has been expressed in another way, by expressing doubt that toxicity data from 2-yr chronic studies represent a valid cross-section of chemicals, since some of the more toxic ones are rejected by short-term toxicity tests. It is, of course, possible that some chemical may be synthesized at some time in the future which would be toxic at 0-1 ppm in the diet. However, it is almost impossible for such a compound to become an intentional component of a food container. For a compound to be toxic for man at 0-1 ppm presumes that it will be as toxic or more toxic than any commercial pesticide. For it to be used as a component of a food container presumes that it must be manufactured, packaged, distributed, and in other ways handled several times before contacting the food. It is inconceivable that a compound as toxic as this could pass through so many hands, in an industry not accusLomcd to handling highly toxic substances, without revealing its toxicity through injury to personnel. Once recognized, safe handling of such a compound would require such extreme industrial hygiene precautions as to be incompatible with converting operations and food-packaging practices. It seems to me that in order to produce an unsafe food package, due to incorporation of a toxic ingredient at a level of 0-2% or less, it would require a deliberate or intentional act on the part of a manu­ facturer to poison the public, without at the same time poisoning his own workers. No amount of legislation or regulation can protect against such insanity. It has been suggested by a few of my colleagues that the extreme toxicity of such materials as aflatoxin rules out an assumption that any chemical is safe at even one part in a thousand million unless it has been tested. I believe that such an assumption is valid, if we limit our discussion to certain uses or industries. Again, I believe common sense tells us that it is inconceivable that anyone could manufacture millions of pounds of aflatoxin, or any substance of extreme toxicity and distribute it for use as a stabilizer in plastics or wetstrength resins for paper without finding out that it was too toxic for that industry. No company can afford to lose customers that way. Accidental contamination with aflatoxin or other extremely toxic substances is another matter, but this is outside the considerations of a permissive list. Whether a permissive list contains 200 or 20,000 substances, accidental contamination is no more or less likely. Quality control, inspection, and personal attention to details in manufacture are all necessary ingredients to the prevention of contamination of any product. A few individuals have questioned the validity of my estimate that no more than 25% of the diet will be in contact with the same packaging substrate or chemical. In rare circum­ stances, of course, some individuals may eat canned foods almost exclusively and some may eat fresh or unpackaged food almost exclusively. These variations in dietary habits, along with other intraspecies differences have been taken into consideration as part of the basic concept of our 100-fold margin of safety. Moreover, as mentioned above, the conservative calculations used above provide a 1000-fold margin of safety. The principal objection to this proposal in the United States has been administrative. Adoption of this proposal would obviate the need for many of our packaging regulations and would suggest a complete rewriting of Subpart F, For example, the “general adhesives” and “defoamer in paper manufacture” regulations would be replaced by a statement of good manufacturing practice that adhesives should not contact the food (as is already provided despite the fact that thousands of chemicals are enumerated) and that defoamers may be used only prior to and during sheet-forming process (as is also already provided). ASI-PR 0000453 t. .1 N \ toon-r XCtwXGtNC, t.ONTTOL 303 I think the time necessary to accomplish hns task would lie time .veil spent ami would be rapidly recovered in reduced administrative cost .. Let me close with this concept. Your countrv ar e mi,.e cave a limited number of com­ petent specialists in the field of environmental health 1 here arc many problems facing our society which arc competing for their time and attention, as well as for financial support. Included arc community air and water pollution, industrial exposures, household chemicals, pesticides, drugs, cosmetics, food additives, confined environments of space cabins and submarines and food-packaging. Having some professional icsponsibility in all of these segments, I am convinced that food packaging cn vthmes (lie least hazard to health of all of these. Yet in recent years it has co rummded ' tune ml attention than any oilier area other than drugs and pesticides. It r> oar ,v.. ui ar.d piofcssioual responsibility to invest our time and money in research which is likely to provide the greatest protection to health. I suggest that my proposal is a start tow aid tedomtioii of a proper balance. ATFENDI v No-effcct levels established bj 2-yr feeding studies Compound No-elTcct level (ppm) Compound No-effect level (ppm) Acrylamide1 40 Aldrin1 . 0 5* 1000 Alkyl ketene dimer1 Allcthrin4 4000* Amibcn (2,5-Dichloro-3-ammobcnzoic acid)1 10,000* Ammonium sulphamalc* 500 Antimony chloride’ <500f Arsonic acid1 50* 7-Ascorbyl palmitate* 2500 Barium chloride’ 2000|10* Benzene hexachloride, technical (BI1Q’ a-Benzcne hexachloride (a-BHC)’ 10* ^-Benzene hexachloride (P-BHC)’ <10* /■-Benzene hexachloride (y-BHQ’ 50* <800* c5-Benzene hexacitloridc (6-BHC)’ Benzoic acid11 5000 Biurea11 7500 Butoxypolypropylene glycol (mol wt 800)1 640 5000 Butylated hydroxyanisole (BHA)10 Butylated hydroxy toluene (BUT)1*’1' 1000 Butyl 3,4-dihydro-2,2-dimethylH-oxo-l, 2//-pyran-6-carboxylate (Indalouc)14 40,000 1,3-Butylene glycol11 30,000 2-fp-/ert-Butylphenoxy) isopropyl i'-chloroethyl sulphite (Aramitc)1* 100* /er/-Butylphenyl salicylate1 2000 Cadmium chloride7 <101 Calcium disodium cthylenediamiue5000 tetraacetate1'17 Captan* 1000* Caibarsoite fp-Ureidobcnzencarsonic acid)11 1000 C.n boxvmcthylceilulose (CMQ1* 10,000 /l-Caiotcnc10 1000 I250T CWcchoi" Cliloi henside (p-Chlorobenzyl /’-chlorophcnyl sulphide)4 20* Ch'orbensidc, sulphonc derivative1 20* Chlord.iue7 2-5* bi:,( p-Clilorplienoxylmctiianc1 300 p-Ch!orophenyl p-chlorobcuzcnesulphonatc1 25* Chlorpropamide” 1250 Chlortetracvclme11 10,000 Citrus Red No. 2 (C.I. (1956) No, 12,150) “ 500 Copper chromate4 500* Cube25 50* Cupric chloride4 500t Dalapon* 300* D & C Orange No. 5" 10,000 D & C Orange No. 10“ 10,000 D irc C Red No. 9” 500 D iV C Red No. 10** 300 D &, C Red No. 21“ 10,000 D A C Red No. 27” 10,000 ODD HDE)' to* DDT’ 1* Ochydioacetic acid1 1000 JDiuzincn4 075* Dichione' <500* 1,1 -DYi!oro-2,2-bis(y?-eUiylpltenyl)ethnne (Pcrthane)4 too* •Pesticide 1-Heavy metal t—Tumours at higher levels. ASI-pR 0000454 J. P. FRAWLEY 304 Appendix (contd) Compound I No-effect level (ppm) 2,4-Dichloro-6-o-chloroanilino-s3000* triazine (Dyrene)4 2,4-Dichlorophenoxyethyl sulphate, 200* sodium salt1 4,4Dich loro-«-trichloromethyl20* benzhydrol (Kelthane)4 2500 Dicyandiamide" 0-5* Dieldrin* 0,0-Diethyl 0-3-chloro-4-methyl-Ioxo-2 H-1 -bcnzopy ran-7-yl 2* phosphorothioatc (Co-Ral)4 1300 Di(2-ethylhexyl) phthalate1 5000 Di-n-hexyl azelate*0 5000 Di-isobutyl adipate1 30,000 Dtlauryl thiodipropionic acid*1 10,000 Dimethyl carbate14 2,4-Dimethyl-2-methylene-l ,2,4100* thiadiazolidine-5-thione1 20,000 Dimethyl phthalate14 3,5-Dimethyltetrahydro-l,3,5,2if<10* thiadiazine-2-thione (Mylone)*1 0,0-Dimethyl-0-(2,4,5-trichlorophenyl) 10* phosphorothioate (Ronnel)4 600* 3,5-Dinitrobenzamide** 62* 3,5-Dinitro-o-toluamide1 500* Diphenyl4’** 100* Diphenylamine4 2000 3-(2-Dipheny iy loxy)- 1,2-epoxypropane1 30,000 Distearyl thiodipropionic acid*1 125* Diuron4 Dodecyl benzene sodium suiphonate 2000 (Santomerse no. 3)*4 _ 350 Dodecyl gallate10 50* Dodine4’** 30* Endosulphan4 5* EPN4 Epoxidized soybean oil (Paraplex 25,000 G-60)** Epoxidized soybean oil (Paraplex 5000 G-62)** 4*Ethoxyphcnylurea (Sucrol, dulcin)*’ <1000 120* Ethoxyquin4 100 Ethyl acrylate" 50* Ethyl 4,4'-dichlorobenzilate4 40,000 2-Ethyl hexancdiol-1,314 2-Ethylhexyl diphenyl phosphate 1250 (Santicizer 141)" 5000 Ethyl phthalyl ethyl glycolate1 10,000 Fast Green FCF** 5000 FD & C Blue No. 1“ 1000 FD & C Blue No. 241 200* Ferbam4 100,000 Glycerol4* 250,000 Glycerol monostearate4* 5000 Gum guaiac44 500 Gum rosin, pale4* 0-5* Heptachlor epoxide4 Compound No-effect level (ppm) 2-Heptadecyl glyoxalidine acetate (Glyodin)4 210* rt-Heptyl-p-hydroxybenzoate44 1500 l-[5-(3a,4,5,6,7,7a-Hexahydr<>4,7methanoindanyl)]-3,3-dimethylurea (Herban)* 500* 10,000 Hydroxyethylcellulose** Hydroxypropylmethylcellulose1 50,000 Hydroquinone*1 10,000r d-Isoascorbic acid*1 10,000 d-Isoascorbyl palmitate*1 2500 Isopropyl N-(3 chlorophenyl) carbamate (CIPC)4* 2000* 4,4'-Isopropylidene bis(2-Isopropylphenol)1 1000 Light Green SF Yellowish40 10,000 Malathion4 100* Maleic hydrazide4 20.000* 25* Maneb4 Melamine-formaldehyde resin (Parez 607)** 50,000 Mercaptobenzothiazole4 120* Mercury acetate* 2-5* Methoxychlor*’4* 200* 0-Methyl-0-(4-ferr-butyl-2-chlorophenyl) methylphosphoroamidothioate 30* (Ruclene)1’40 0-Methyl-0-(2,4-dichlorophenyl) isopropylphosphoramidothioate1 10* 20,000 Methyl p-hydroxy benzoate*1 100 Methyl methacrylate** Methyl naphthaleneacetic acid* 2500* Methylpolysiloxane1 3000 10,000 Methyl salicylate** 250* Monuron4 1 -Naphthyl-/V-methyl carbamate* 200* 50* a-Naphthylthiourea** Nicotine4 62 2500 Nordihydroguaiaretic acid*1 100,000 Nylon (Zytel)*4 500 Octadecylamine" 350 Octyl gallate10 p-tert-Qcty1 phenoxy-polyethoxy 14,000 cthanols (Triton X-405)" 1* Parathion4 50,000 Petrolatum** Petroleum wax no. 2*° 100,000 100,000 Petroleum wax no. 8** 100,000 Petroleum wax no. 12‘* Petroleum wax no. 15** 100,000 100,000 Petroleum wax no. 20** 630 Phenacetin** 10,000 Phenol*1 01* Phenyl mercuric acetate* 2000* o-Phenylphenol" 500 Pimaricin*1 Pipcronyl butoxide* 700* ASI-PR 0000455 FOOD-PACKAGING CONTROL 305 Appendix (conld) Compound No-cffcct level (ppm) Polyacrylamide (Separan AP30)** 10,000 Polyacrylamide (Separan NP10)** 10,000 Polyethylene glycol (mol wt 200)1 40,000 Polyethylene glycol (mol wt 400)1 3 20,000 Polyethylene glycol (mol wt 1500)1 2000 Polyethylene glycol (mol wt 1540)1 40,000 Polyethylene glycol (mol wt 4000)1 40,000 Polymerized turpentine resin* 2000 Polyoxyethylene(20)sorbitan monolaurate (Tween 20)** 50,000 Polyoxyethylene(20)sorbitan 50,000 monoolcate (Tween 80)** Polyoxyethylene(20)sorbitan monopalmitate (Tween 40)** 50,000 Polyoxycthylene(20) sorbitan monostearate (Tween 60)** 50,000 Polyoxyethylene(20)sorbitan tristearate (Tween 65)** 50,000 Polyoxyethylene(8)stearate (Myrj 45)** 20,000 Polyoxyethylene(40)stearate (Myrj 52)“ 50,000 Ponceau 3R (C.I. (1956) No. 16,155)“ 5000 Ponceau SX (C.I. (1956) No. 14,700)" 50,000 Potassium bromate** 627 1 -n-Propoxy-2-amino-4-nitrobenzene (P-tOOO)77 <1000 Propyl gallate*1 10,000 Propyl p-hydroxybcnzoate*1 20,000 Pyrethrum7 ~~ - -1000* Rosin, disproportionated** 500 Rosin, fully dimerized** 500 Rosin, partially dimerized4* 500 Rotenone7 2* Saccharin*7 10,000 Selenium7 <3* Sodium alginate47 50,000 Sodium alkylbenzenesulphonate** 5000 Sodium bisulphite** 500 Sodium chromate7* 300* Sodium cyclamate’7 10,000 Sodium 2,2-dichloropropionate1 300 Sodium dioctyl sulphosuecinate71 5000 Sodium hexametaphosphate** 5000 Sodium lauryl glycerylsulphonate7* 5000 Compound No-effect level (ppm) Sodium lauryl sulphate71 10.000 Sodium lauryl Irioxyethylene sulphonate7* 5000 Sodium monofluoracetate7 <5* Sodium nitrate7* 10,000 Sodium 0-sulphopropionamide* 10,000 Sodium tripoiyphosphatc** 5000 Sorbic acid1* 50,000 Sorbitan monopalmitate (Span 40)“ 50,000 Sorbitan monostearate (Span 60)“ 50,000 Sorbitan tristearate (Span 65)** 50,000 Sulphenone (p-chlorophenyl phenyl sulphone)* 100* Tall oil rosin, pale** 2000 Tartar emetic (Potassium antimonyl tartrate)* <50O) Tartaric acid74 12,000 Tartrazine7* 10,000 50* Terpene polychlorinates (Strobane)4 Tetradifon* 300* Thiodipropionic acid*1 30,000 Thiourea7* 500* Thiram* 200* Toxaphene7 25* 2,4,5-Trichlorophenoxyethyl sulphate, sodium salt1 200 Tri(polynonylphenyl) phosphite (Polygard)77 3300 -Tylosin7* 10,000 Vinyl chloride-vinylacetate copolymer7* 120,000 Vinyl idene chloride-vinyl chloride copolymer1 50,000 Wood rosin, dark" 500 Wood rosin, fully hydrogenated" 500 Wood rosin, hydrocarbon insoluble residue** 500 Wood rosin, pale** 2000 Wood rosin, partially hydrogenated44 2000 Yellow AB“ 500 Yellow OB** 500 Zineb* 500* Ziram* 250* REFERENCES 1. Weil, C. S. A McCollister, D. D. (1963). Relationship between short- and long-term feeding studies in designing an effective toxicity test. J, agric. Fd Chem. 11,486. 2. Davis, K. J. A Fitzhugh, O. G. (1962). Tumorigenic potential of aldrin and dieldrin for mice. Toxic, appl. Pharmac. 4, 187. 3. Hercules Incorporated (Unpublished data), 4. Lehman, A. J. (1965). Summaries of Pesticide Toxicity, The Association of Food and Drug Officials of the United States. Kansas. 5. Hazleton, L, W„ Paynter, O. E. A Weir, R. J. (1964). Safety evaluation studies on 2,5dichloro-3-aminobenzoic acid (Amiben). Toxic, appl. Pharmac. 6, 349. 6. Sherman, H. A Stula, E. F. (1965). Toxicity studies on ammonium sulfamate. Toxic, appl. Pharmac. 7, 497. 7. Lehman, A. J. (1952). In Chemicals lit Foods: A Report to the Association of Food and Drug Officials on Current Developments, Part II. Pesticides. Vol. XVI, No. 2. p. 47. The x- . • ■ X ASI-PR 0000456 306 J. P. FRAWLEY Association of Food and Drug Officials of the United States, 8, Prier, R. F,, Nees, P. O. & Derse, P. H. (1963). The toxicity of an organic arsenical, 3-nitro-4hydroxyphenylarsonic acid. II. Chronic Toxicity. Toxic, appl. Pharmac. 5, 526. 9. Fitzhugh, O. G. A Nelson, A. A. (1946). Subacute and chronic toxicities of ascorby! palmitates. Proc. Soc. exp. Biot. Med. 61, 195. 10. Joint FAO/WHO Expert Committee on Food Additives—Sixth Report (1962). Evaluation of the Toxicity of a Number of Antimicrobials and Antioxidants. Tech. Rep. Ser. Wld Hlih Org. 228. 11. Oser, B. L., Oser, Mona & Morgareidge, K. (1965). Studies of the safety of azodicarbonamide as a flour-maturing agent. Toxic appl. Pharmac. 7, 445. 12. Deichmann, W. B,, CIcmmcr, J. J., Rakoczy, R. A Bianchine, J. (1955). Toxicity of ditertiarybutylmethylphenol. A.M.A. Archs hid. Hlth 11,93. 13. Joint FAO/WHO Expert Committee on Food Additives—Ninth Report (1966). Specifica­ tions for the Identity and Purity of Food Additives and their Toxicological Evaluation: Some Antimicrobials, Antioxidants, Emulsi­ fiers, Stabilizers, Flour-Treatment Agents, Acids and Bases. Tech. Rep. Ser. Wld Hlth Org. 339. 14. Lehman, A. J. (1955). Insect Repellents. Vol. 19. p. 87, The Association of Food and Drug Officials of the United States. 15. Scala, R, A. A Paynler, O. E. (1964). Safety evaluation studies on 1,3-butylene glycol. Toxic, appl. Pharmac. 6, 358 16. Oser, B. L. A Oser, Mona (1962). l-(p-terb Butylphcnoxy)isopropyi 2-chloroethlyl sulfite (Aramite). II. Carcinogenicity. Toxic, appl. Pharmac. 4, 70. 17. Oser, B. L., Oser, Mona & Spencer, H. C. (1963). Safety evaluation studies of calcium EDTA. Toxic, appl. Pharmac. 5,142, 18. Oser, B. L., Morgareidge, K., Weinberg, M. S. A Oser, Mona (1966). Carcinogenicity study of carbarsone. Toxic, appl. Pharmac. 9, 528. 19. Shelanski, H. A. A Clark, A. M, (1948). Physiological action of sodium carboxymethylcellulose on laboratory animals and humans. Fd Res. 13, 29. 20. Bagdon, R. E., Zbinden, G. A Studer, A. (1960). Chronic toxicity studies of ^-carotene. Toxic, appl. Pharmac. 2, 225. 21. Lehman, A. J., Fitzhugh, O. G., Nelson, A. A. A Woodward, G. (1951). The pharmacological evaluation of antioxidants. Adv. Fd Res. 3,197. 22. Delahunt, C. S„ P’an, S. Y., Dardin, V. J. A Schneider, J. A. (I960). Prolonged administra­ tion studies with chlorpropamide. Toxic, appl. Pharmac. 2, 195. 23. Dessau, F. I. A Sullivan, W. J. (1961). A twoyear study of the toxicity of chlortetracyclino hydrochloride in rats. Toxic, appl. Pharmac. 3, 654. 24. Dacre, J. C. (1965). Chronic toxicity and carcinogenicity studies on Citruj Red No. 2. Proc. Univ, Otago med. Sch. 43, 31. 25. Hansen, W. H., Davis, K. J. A Fitzhugh, O. G. (1965). Chronic toxicity of cubi. Toxic, appl. Pharmac. 7, 535. 26. Industrial Bio-Test Laboratories (Unpublished data). 27. Davis, K. J. A Fitzhugh, O. G. (1962). Pathologic changes noted in rats fed D A C Red No. 9 for two years. Toxic, appl. Pharmac, 4, 200. 28. Davis, K. J. A Fitzhugh, O. G. (1963). Pathologic changes noted in rats fed D A C Red No. 10 [monosodium salt of 2-(2-hydroxyl-naphthylazo)-l-naphthalenesulfonic acid] for two years. Toxic, appl. Pharmac. 5, 728. 29. American Cyanamid Company (Unpublished data). 30. Hodge, H, C., Maynard, E. A,, Downs, W- L., Salerno, Lillian A Packer, J. T. (1962), Chronic oral toxicity studies of di-n-hexyl azelate in rats and dogs. Toxic, appl. Pharmac. 4, 247. 31. Smyth, H, F., Jr., Carpenter, C. P. A Weil, C. S. (1966). Toxicologic studies on 3,5dimethyltetrahydro-1,3,5, 2 f/-thiadiazine-2thione, a soil fungicide and slimicide. Toxic, appl. Pharmac. 9, 521. 32. Kerr, K. B,, Abrahamson, P. R, A Ipson, J. R, (1965). Evaluation of the safety of 3,5-dinitrobenzamide. Toxic, appl. Pharmac. 7, 488. 33. Ambrose, A. M., Booth, A. N., DeEds, F. A Cob, A. J., Jr. (1960). A toxicological study of biphenyl, a citrus fungistat, Fd Res, 25, 328. 34. Paynter, O. E. A Weir, R. J., Jr. (1960). Chronic toxicity of Santomerse No. 3 from olefin (dodecyl benzene sodium sulfonate). Toxic, appl. Pharmac. 2, 641, 35. Levinskas, G. J., Vidone, Lena B., O’Grady, J. J. A Shaffer, C. B. (1961). Acute and chronic toxicity of dodine (n-dodecylguanidine acetate). -- -Toxic, appl. Pharmac. 3, 127. 36. Larson, P. $., Finnegan, J. K., Haag, H. B., Smith, R. B., Jr., A Hennigar, G. R, (1960). Chronic toxicity studies on two epoxidized soybean oils in the rat and dog. Toxic, appl. Pharmac. 2, 649. 37. Fitzhugh, O. G., Nelson, A. A. A Frawley, J. P. (1951). A comparison of the chronic toxicities of synthetic sweetening agents. J. Am. pharm. Ass. Scl Ed. 40, 583. 38. Borzelleca, J. F., Larson, P. S„ Hennigar, G. R., Jr., Huif, E. G., Crawford, E. M. A Smith, R. B., Jr. (1964). Studies on the chronic oral toxicity of monomeric ethyl acrylate and methyl methacrylate. Toxic, appl. Pharmac. 6,29. 39. Trcon, J. F„ Dutra, F. R. A Cleveland, F. P. (1953). Toxicity of 2-ethylhexyl diphenyl phosphate. A.M^A. Archs hid. Hyg. 8, 170. ■J i ASI“PR 0000457 FOOD-PACKAGING CONTROL 307 55. MacDonald, W. E., Deichmann, W. B., 40. Hansen, W. H., Long, Eleanor L., Davis, K. J., Nelson, A. A. & Fitzhugh, O, G. (1966). Radomski, J. L. St Austin, B. S. (1962). The chronic toxicity of octadecylamine in the rat— Chronic toxicity of three food colourings: a supplemental report. Toxic, appl. Pharmac. Guinea Green B, Light Green SF Yellowish 4, 610. and Fast Green FCF in rats, dogs and mice. FJ Cosmet. Toxicol. 4, 389. 56. Larson, P. S., Borzelleca, J. F., Bowman, E. R., 41. Hansen, W, H., Fitzhugh, O. G., Nelson, Crawford, E. M., Smith, R. B., Jr., St Hennigar A. A. & Davis, K. J. (1966). Chronic toxicity .. __ G. R. (1963). Toxicologic studies on a prepara­ of two food colours, Brilliant Blue FCF and tion of p-tertiary octylphenoxy-polyethoxy lndigotine. Toxic, appl. Pharmac. 8, 29. ethanols (Triton X-405}^Toxic. appl, Pharmac, 5,782. 42. Hine, C. H., Anderson, H. H., Moon, H. D., Dunlap, M, K. & Morse, M. S. (1953). 57. Oser, B. L., Oser, Mona & Carson, S. (1965). Comparative toxicity of synthetic and natural Toxicologic studies of petrolatum in mice and glycerin, AM.A. Archs ind. Hyg. 7, 282. rats. Toxic, appl. Pharmac. 7, 382. 43. Ames, S. R., O’Grady, M. P., Embree, N. D. 58. Shubik, P., Saffiotti, U., Lijinsky, W., Pietro, St Harris, P. L, (1951). Molecularly distilled G., Rappaport, H., Toth, B., Raha, C. R., Tomatis, £.., Feldman, R, St Ramahi, H. monoglycerides, III. Nutritional studies on monoglycerides derived from cottonseed oil. (1962). Studies on the toxicity of petroleum J. Am. Oil Cliem. Soc. 28, 31. waxes. Toxic, appl. Pharmac. (Supp.) 4, 49. 44. Johnson, V., Carlson, A. J., Kleitman, N. & 59. Woodard, G., Post, K. F., Cockrell, K. O. St Bergstrom, P. (1938). Action of gum guaiacum Cronin, M.T. I. (1965). Phenacetin: Long-term upon the animal organism. Fd Res. 3, 555. studies in rats and dogs. Toxic, appl, Pharmac. 45. Frawley, J. P. (1965). Investigations estab­ 7, 503. lishing the safety of rosin products for food, 60. Hodge, H. C., Maynard, E., Blanchet, H. J., food packaging applications. Nav. Stores Rev. Jr., Spencer, H. C. & Rowe, V. K. (1952). Ter. Chem. 74 (12), 4. Toxicological studies of ortho-phenylphenol 46. Paynter, O. E., Hazleton, L. W. & Garlock, in (Dowicide I). J. Pharmac. exp. Ther. 104, E. A. (1966). Toxicologic evaluation of the 202. n-heptyl ester of p-hydroxybenzoic acid. Toxic, 61. Levinskas, G. J., Ribelin, W. E. &. Shaffer, appl. Pharmac. 8, 350. C. B. (1966). Acute and chronic toxicity of 47. Smyth, H. F., Jr., Carpenter, C. P. St Weil, pimaricin. Toxic, appl. Pharmac. 8, 97. C. S. (1947). Chronic toxicity of hydroxyethyl 62. McCollister, D. D., Hake, C. L., Sadek, S. E. cellulose for rats. J. Am. pharm. Ass. 36, 335. St Rowe, V, K. (1965). Toxicologic investiga­ 48. Larson, P. S., Crawford, E. M., Smith, R. B,, tions of polyacrylamides. Toxic, appl. Pharmac. Jr., Hennigar, G. R., Haag, H. B. & Finnegan, 7, 639. J. K. (1960). Chronic toxicologic studies on 63. Joint FAO/WHO Expert Committee on Food isopropyl