Flavor Encapsulation - ACS Publications - American Chemical Society

Chapter 1

Flavor Encapsulation An

Overview

Ronald J . Versic

Downloaded by UNIV LAVAL on July 5, 2014 | http://pubs.acs.org Publication Date: May 31, 1988 | doi: 10.1021/bk-1988-0370.ch001

Ronald T. Dodge Company, 55 Westpark Road, Dayton, OH

45459

The encapsulation of foods, flavors, fragrances and the like has been attempted and commercialized by many different methods. A comprehensive overview is given of these many methods. The overview describes each method in terms of the basic chemical and/or physical principles involved. The basic literature references, particularly fundamental or basic patents, are included. Each method was generally developed to solve a particular problem encountered by a product development or formulation chemist. The relationships among problems, capabilities, and encapsulation methods are shown. The overview concludes with a list of reasons for encapsulation, such as prevention of oxidation, conversion of liquids to solids and detackification. The use of microcapsules i n food i s generally that of an additive. By regulatory d e f i n i t i o n , a food additive i s any substance which becomes added to food either intentionally or unintentionally other than food i t s e l f . This includes both compounds added d i r e c t l y and those that are added i n d i r e c t l y such as migrating from packaging materials. We w i l l l i m i t our discussion here to d i r e c t , intentional additives. This means, for example, that the Vitamin C i n orange j u i c e i s not an additive but the Vitamin C added to orange juice i s . There are several hundred types of microcapsules being used as a food additive i n the U.S. today. Most of these are used i n the development and production of a r t i f i c a l flavors or natural flavors and spices. Microcapsules as food additives may be added to enhance or a l t e r appearance. Food i s not only consumed for i t s calories or nutrients. I t i s also part of our c u l t u r a l experience and i t must be appealing i n a l l of i t s aspects. I t i s not j u s t a b i o l o g i c a l necessity, i t s consumption i s a s o c i a l a c t i v i t y , an asthetic experience and an expression of c u l t u r a l and personal experiences. This means that food must not only taste good but i t also must have the right color, texture and aroma.

0097-6156/88/037Q-0001$06.00/0 ° 1988 American Chemical Society

In Flavor Encapsulation; Risch, S., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 1988.


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The use of microcapsules can improve or enhance n u t r i t i o n . The processing required to produce many of the food products used today and the long shelf needed to provide a variety of foods available far from the place where they were grown often results in the loss of n u t r i t i o n a l value. The products are often restored to their natural n u t r i t i o n a l values through the addition of vitamins, minerals and i n some cases, proteins. Microcapsules can be used as preservatives. Most food preservation o r i g i n a l l y was accomplished by curing, smoking or p i c k l i n g which were primarily e f f e c t i v e i n changing the moisture content or water a c t i v i t y i n foods. Then came canning, pasteurization, freezing and chemical preservatives. Microcapsules can also enhance the convenience of food products. Changing l i f e s t y l e s and the limited time available for food preparation require an increasing variety of high quality, nutritious and convenient food products today. Microencapsulation Terminology Microcapsules represent an extra degree of freedom i n the formulation or development of these food products. Many of the reasons or causes for the use of microcapsules are covered i n a previous symposium (1) and a continued updated review on this subject (2). The use of microcapsules i s one means of achieving controlled release of the core or inner material. The term controlled release actually covers a wide range of technologies and microencapsulation i s one way of achieving controlled release. In fact, microencapsulation i s the dominant means for achieving controlled release both i n product volume and d o l l a r value. One p a r t i c u l a r example of controlled release i s sustained release. In this form the desired material i s continuously released over a period of time at a constant rate. Two timely publications (3)(4) cover the general area of controlled release, which can also include the controlled release of a g r i c u l t u r a l materials and b i o l o g i c a l materials, f a r example, pheromones. In using the term microencapsulation in this a r t i c l e , the author intends to refer to capsules i n the size range of 1 micron to 1000 microns. Capsules below 1 micron i n size are frequently referred to as nanocapsules and they are made by one or more very specialized methods (5). The term capsule refers to macro objects in the order of 1 millimeter or larger. This term of capsule i s frequently used i n the delivery of pharmaceuticals. The simplest way of looking at a microcapsule i s that of imagining a hen's egg reduced i n size. The s h e l l has a number of names depending on the industry and company with which one works. This s h e l l can be referred to as a membrane, a wall, a covering or a coating. The internal core material also goes by a number of terms such as payload, core, encapsulant, f i l l , active ingredient, internal phase, IP or internal ingredient. For the purposes of the a r t i c l e here we w i l l refer to the terms wall and core. Often i n the making of microcapsules by a chemical process known as coacervation, there i s the additional use of the terms external phase or continuous phase.



1.

VERSIC

Flavor Encapsulation: An Overview

Microcapsule Design The architecture of microcapsules i s generally divided into several a r b i t r a r y and overlapping c l a s s i f i c a t i o n s . One such design i s known as matrix encapsulation. In this design the matrix p a r t i c l e resembles that of a peanut c l u s t e r . The core material i s buried to varying depths inside of the wall material. The most common or well known type of microcapsule i s that of a spherical or reservior design. I t i s this design that most approaches a hen's egg. I t i s also possible to design other microcapsules that have multiple cores where the multiple cores may actually be an agglomerate of several d i f f e r e n t types of microcapsules. If the cere material i s an irregular material, such as occurs with a ground p a r t i c l e , then the wall w i l l somewhat follow the contour of the irregular p a r t i c l e and one achieves an irregular microcapsule. The l a s t well known design for a microcapsule i s that of a multiple wall. In this case the multiple walls are placed around a core to achieve multiple purposes related to the manufacture of the capsules, their subsequent storage and controlled release. In a discussion of microencapsulation technology, p a r t i c u l a r l y when one i s talking quantities and cost, i t i s necessary to understand that encapsulation i s a volume process, independent of the density or value of the core material. Thus microencapsulators frequently state that i t i s j u s t as expensive on a volume basis to encapsulate diamond as graphite. Likewise, on a volume basis i t i s just as expensive to encapsulate p a r a f f i n wax as tungsten metal. When experimenting with or acquiring microcapsules, i t should be emphasized that i t i s necessary to use common terminology because preference to discuss microcapsules i n terms of the core material, p a r t i c u l a r l y when one i s discussing the cost of production. One should also keep i n view that the t o t a l process of microencapsulation actually covers three separate processes on a time scale. The f i r s t process consists of forming a wall around the core material. The second process involves keeping the core inside the wall material so that i t does not release. Also, the wall material must prevent the entrance of undesirable materials that may harm the core. And f i n a l l y , i t i s necessary to get the core material .out beginning at the right time and at the r i g h t rate. There i s a good reference material covering the current work i n the area of microencapsulation (6) and a review article that i s continually updated (7). Microcapsule Uses The uses of microcapsules since the i n i t i a l coacervation work i n the 1940's are many and varied. A good early review of these uses that also includes pharmaceuticals and a g r i c u l t u r a l materials i s contained i n reference (8). The uses of microcapsules that are of interest here include the following: 1. Reduce the r e a c t i v i t y of the core with regard to the outside environment, for example oxygen and water; 2. Decrease the evaporation or transfer rate of the core material to the outside environment;


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Promote the ease of handling of the core material; a. Prevent lumping; b. Position the core material more uniformily through a mix by giving i t a size and outside surface l i k e the remainder of the materials i n the mix; c. Convert a l i q u i d to a s o l i d form; and, d. Promote the easy mixing of the core material. Control the release of the core material so as to achieve the proper delay u n t i l the right stimulus; Taste mask the core; and, Dilute the core material when i t i s only used i n very small amounts; but, achieve uniform dispersion i n the host material.

Release Mechanisms A variety of release mechanisms have been proposed for microcapsules; but i n fact, the number that have actually been achieved and are of interest here are rather limited. These are as follows: 1. A compressive force i n terms of a 2 point or a 12 point force breaks open the capsule by mechanical means; 2. The capsule i s broken open i n a shear mode such as that i n a Waring blender or a Z-blade type mixer; 3. The wall i s dissolved away from around the core such as when a l i q u i d flavoring o i l i s used i n a dry powdered beverage mix; 4. The wall melts away from the core releasing the core i n an environment such as that occuring during baking; and, 5. The core diffuses through the wall at a slow rate due to the influence of an exterior f l u i d such as water or by an elevated temperature. Release Rates The release rates that are achievable from a single microcapsule are generally "0" order, 1/2 order or 1st order. "0" order occurs when the core i s a pure material and releases through the wall of a reservoir microcapsule as a pure material. Half order release generally occurs with matrix p a r t i c l e s . 1st order release occurs when the core material i s actually a solution. As the solute material releases from the capsule the concentration of solute material i n the solvent decreases and a 1st order release i s achieved. Please note that these types of release rates occur from a given single microcapsule. A mixture of microcapsules w i l l include a d i s t r i b u t i o n of capsules varying i n size and wall thickness. The e f f e c t , therefore, i s to produce a release rate d i f f e r e n t from "0", "1/2" or "1" because of the ensemble of microcapsules. I t i s therefore very desirable to c a r e f u l l y examine on an experimental basis the release rate from an ensemble of microcapsules and to recognize that the deviation from theory i s due to the d i s t r i b u t i o n i n size and wall thickness. Microcapsule Formation The general technology for forming microcapsules i s divided into two c l a s s i f i c a t i o n s known as physical methods and chemical



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Flavor Encapsulation: An Overview

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methods. The physical methods are generally divided into the following: 1. Spray coating. a. Pan coating. This i s a mature, well established technology i n t i a l l y patented by a pharmacist i n the 19th century by the name of Upjohn. I t generally requires large core p a r t i c l e s and produces the coated tablets that we are f a m i l i a r with; b. F l u i d bed coating. One version of this coating i s known as Wurster coating and was developed i n the 1950's and 60's (9). The Wurster coater r e l i e s upon a bottom positioned nozzle spraying the wall material up into a f l u i d i z e d bed of core p a r t i c l e s . Another version sprays the wall material down into the core p a r t i c l e s . 2. Annular j e t . This technology was developed by the Southwest Research I n s t i t u t e and has not been extensively used i n the food industry (10). I t r e l i e s upon two concentric j e t s . The inner j e t contains the l i q u i d core material. The outer j e t contains the l i q u i d wall material, generally molten, that s o l i d i f i e s upon e x i t i n g the j e t . This dual f l u i d stream breaks into droplets much as water does upon e x i t i n g a spray nozzle; 3. Spinning disk. A new method was developed by Professor Robert E. Sparks at Washington University i n St. Louis. This method r e l i e s upon a spinning disk and the simultaneous motion of core material and wall material e x i t i n g from that disk i n droplet form (11). The capsules and p a r t i c l e s of wall material are collected below the disk. The capsules are separated from the wall p a r t i c l e s (chaff) by a s i z i n g operation; 4. Spray cooling. I t i s a method of spray cooling a molten matrix material containing minute droplets of the core materials (12). This method i s well known because of i t s practice by the Sunkist Company; 5. Spray drying. I t i s a method to be discussed at length i n the following papers; and, 6. Spray c h i l l i n g . I t i s a process of spray c h i l l i n g the wall around an atomized core (13). The r e s u l t i n g capsules move countercurrent to a flow of tempered a i r and are collected i n a large container below the spray nozzle. I t i s practiced currently by the Durkee Company. The number of methods for chemical encapsulation i s a c t u a l l y far less. They are necessary because they are very e f f e c t i v e i n encapsulating l i q u i d s and small core s i z e s . In p a r t i c u l a r , i t i s possible to encapsulate flavors and fragrances down to 10 microns in size. Two methods are known as water-in-oil and oil-in-water. The oil-in-water process i s known as complex coacervation. This process r e l i e s , for example, upon a solution of g e l a t i n and the complex i t forms with a solution of gum arable. Complex coacervation w i l l be described i n a l a t e r paper by the author. The other method of encapsulating water soluble cores within an o i l medium i s generally not used i n the food industry.


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Conclusion In looking at the need f o r encapuslation i n a product i t should be emphasized that microcapsules are rarely sold and consumed by themselves. Microcapsules are generally additives to a larger system and must function within that system. Consequently there are a number of performance requirements placed on microcapsules when a limited number of encapsulating materials and methods exist. Consequently i t i s necessary to make a number of trade offs and compromises to incorporate microcapsules into a food product as an additive. In contrast to t h i s , though, there i s the continual development of new materials f o r encapsulation, p a r t i c l u a r l y i n the Wurster method. Fortunately a number of the patents have now expired and so i t i s possible f o r the encapsulator to use a number of methods without fear of patent infringement.

Literature Cited 1. Whitten, J . Α., Food Additives in the 1980's; New Demands, New Products, New Opportunities. Food Additives Symposium, American Chemical Society, April 1986. 2. Food; Encapsulation, 1972 - November 1986 PB87-850335/CAW, U. S. Dept. of Commerce, National Technical Information Service, Springfield, VA, 1987. 3. J . Controlled Release: Controlled Release Society, Elsevier: New York. 4. CA Selects, Controlled Release Technology, Chemical Abstracts Service, Columbus, OH. 5. Cook, E. J.; Lagace, A. P. U.S. Patent 4 533 254, 1985. 6. J . Microencapsulation: Taylor and Francis Inc.: Philadelphia. 7. Kirk-Othmer, Encyclopedia of Chemical Technology, John Wiley and Sons: New York, 1981; Vol. 15, p. 470-493. 8. Fanger, G. O. Chemtech," , 1974, 398-405. 9. Wurster, D. E. U.S. Patent 2 799 241, 1957; 3 089 834, 1963; 3 117 027, 1964; 3 196 927, 1965; 3 207 824, 1965; 3 241 520, 1966; 3 253 944, 1966. 10. Somerville, G. U.S. Patent 3 015 128, 1962; 3 310 612, 1967; 3 389 194, 1968. 11. Sparks, R. E. U.S. Patent 4 675 140, 1987. 12. Swisher, Η. E. U.S. Patent 3 041 180, 1962. 13. Johnson, L. Α.; Walters, L. A. U.S. Patent 3 976 794, 1976; Johnson, L. Α.; Beyn, E. J. U.S. Patent 3 949 094, 1976; Johnson, L. Α.; Beyn, E. J. U.S. Patent 3 949 096, 1976. RECEIVED

December 29, 1987


Flavor Encapsulation - ACS Publications - American Chemical Society

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