The present invention relates to the field of food preparation, and in particular, relates to materials and constructs that may be used to prepare foods in a microwave oven.
Microwave ovens commonly are used to cook food in a rapid and effective manner. To optimize the cooking performance of microwave ovens, various food packaging arrangements have been developed to block, enhance, direct, and otherwise affect microwave interaction with food.
If browning or crisping of the exterior of the food item is desired, the food item is placed in a container that includes a susceptor. The susceptor typically includes a microwave energy interactive material, such as a metal, that absorbs, reflects, and transmits microwave energy in varying proportions. The surface to be browned is placed proximate the susceptor. The susceptor absorbs the microwave energy, and transmits heat to the food item to promote surface browning and crisping. Further, some of the microwave energy is transmitted to the inside of the food item.
Numerous susceptor configurations, shapes, and sizes are known in the art. Depending on the susceptor arrangement, the time of exposure to microwave energy, the desired degree of browning and crisping, and other factors, the susceptor may be in intimate or proximate contact with the food item. Thus, a material or package including a susceptor may be used to cook a food item, and to brown or crisp the surface of the food item in a way similar to conventional frying, baking, or grilling.
One particular food packaging arrangement that may employ susceptors involves closed cells formed between layers of packaging material. Upon exposure to microwave energy, the cells expand to form inflated cells that insulate the food item in the package from the microwave environment. One example of a microwave packaging material that provides inflatable cells is described in co-pending published PCT Application No. PCT/US03/03779 titled “Insulating Microwave Interactive Packaging”, which is hereby incorporated by reference herein in its entirety.
Despite these advances, numerous challenges in microwave cooking remain. For example, removal of large objects from a microwave oven, if not properly supported, can be difficult. If a flat tray supporting a pizza is grasped along only one side and lifted from the oven, the tray might bend and cause the pizza to slide off the tray. Additionally, many packages are fixed in shape and do not provide sufficient intimate or proximate contact with the food item to brown or crisp the surface of the food item. Some packages provide partitions to increase contact with the food item but, in many cases, the shape and size of the partitions are adapted to a standard or nominal food item size that does not accommodate any variation in the size of the food item. For example, if the cross sectional size of a portion of French fries varies, only a portion of the fries will contact the microwave interactive components of the package. Thus, there remains a need for improved microwave energy interactive packages.
The present invention generally relates to materials and packages, and methods of making such materials and packages, for use with microwaveable food items. In various aspects, an insulating material is used. In one aspect, the present invention involves a microwave sheet with a self-sealing feature to provide a partially sealed food wrap after the sheet is exposed to microwave energy. In another aspect, the present invention involves a microwave sheet or package employing variably sized and variably expansive cells for use in shipping, microwave cooking, and other uses. In another aspect, the present invention is directed to a microwave tray with side walls that form upon exposure to microwave energy. The present invention also relates to an insulating microwave material or other microwave packaging material with an oxygen barrier. Further, the present invention relates to insulating microwave material or other microwave packaging material formed at least in part with a thermo-mechanical device. The present invention also includes a method of wrapping a food item in an insulating microwave material and, optionally, a protective overwrap. Finally, the present invention includes a package with a lid that can be tucked under the package during microwave cooking to provide additional insulation and heating.
The present invention relates generally to various aspects of materials and packages for microwave cooking of food items, and methods of making such materials and packages. Although several different inventions, aspects, implementations, and embodiments of the various inventions are provided, numerous interrelationships between, combinations thereof, and modifications of the various inventions, aspects, implementations, and embodiments of the inventions are contemplated hereby.
According to various aspects of the present invention, an insulating material is used to form numerous constructs for microwave cooking and packaging of foods. As used herein, an “insulating microwave material” refers to any arrangement of layers, such as polyester layers, susceptor or “microwave interactive” layers, polymer layers, paper layers, continuous and discontinuous adhesive layers, and patterned adhesive layers, that provides an insulating effect. The sheet or package may include one or more susceptors, one or more expandable insulating cells, or a combination of susceptors and expandable insulating cells. Examples of materials that may be suitable, alone or in combination, include, but are not limited to, are QwikWave® Susceptor, QwikWave® Focus, Micro-Rite®, MicroFlex® Q, and QuiltWave™ susceptor, each of which is commercially available from Graphic Packaging International, Inc.
An exemplary insulating material 10 is depicted in
Referring to
Optionally, an additional substrate layer 24 may be adhered by an adhesive 29 or otherwise to the first plastic film 16 opposite the microwave interactive material 14, as depicted in
The second symmetrical layer arrangement, beginning at the bottom of the drawings, also comprises a PET film layer 50, a metal layer 52, an adhesive layer 54, and a paper or paperboard layer 56. If desired, the two symmetrical arrangements may be formed by folding one layer arrangement onto itself. The layers of the second symmetrical layer arrangement are bonded together in a similar manner as the layers of the first symmetrical arrangement. A patterned adhesive layer 58 is provided between the two paper layers 48 and 56, and defines a pattern of closed cells 60 configured to expand when exposed to microwave energy. In one aspect, an insulating material 10 having two metal layers 44 and 52 according to the present invention generates more heat and greater cell loft.
Referring to
Use of any of the exemplary insulating materials to package and/or cook a food item provides several benefits before, during, and after heating in a microwave oven. First, the water vapor and air contained in the closed cells provides insulation between the food item and the interior surfaces of the microwave oven. The base of a microwave oven, for example, the glass tray found in most microwave ovens, acts as a large heat sink, absorbing much of the heat generated by the susceptor film or within the food item itself. The vapor pockets in the pillows formed by the present invention maybe used to insulate the food item and susceptor film from the microwave oven surfaces and the vented air in the microwave oven cavity, thereby increasing the amount of heat that stays within or is transferred to the food item.
Second, the formation of the pillows allows the material to conform more closely to the surface of the food item, placing the susceptor film in greater proximity to the food item. This enhances the ability of the susceptor film to brown and crisp the surface of the food item by conduction heating, in addition to some convection heating, of the food item.
Further, the insulating materials contemplated hereby may be desirable as a packaging material because it adds little bulk to the finished package, yet is transformed into a bulk insulating material without any consumer preparation before cooking.
I. Self-Sealing Microwave Sheet
According to one aspect of the present invention, a sheet of microwave packaging material is provided with an “activatable adhesive”. As used herein, the phrase “activatable adhesive” refers to any bonding agent or adhesive that bonds to itself or a material when exposed to microwave energy or heat. The food item is wrapped in the sheet and heated in a microwave oven, where it self-seals during microwave heating to encompass all or a portion of the food item.
The type of activatable adhesive, the amount applied to the microwave sheet, and the coverage and positioning thereon may vary for a given application. Thus, the present invention contemplates numerous arrangements and configurations of the activatable adhesive on the microwave sheet as needed or desired. Where a stronger bond is desired, a particular adhesive may be selected and positioned accordingly. For a weaker bond, another particular adhesive may be selected and positioned accordingly. One example of an activatable adhesive that may be suitable for use with the present invention is amorphous polyethylene terephthalate (“APET”). For example, an APET layer may be co-extruded with a clear polyethylene terephthalate (“PET”). In one variation, the sheet or material includes a layer of DuPont Mylar™ 850 PET with a heat-sealable APET layer. However, other activatable adhesives are contemplated by the present invention.
In one aspect, the activatable adhesive is not tacky or sticky before exposure to microwave energy or heat, making the sheet easier to handle. Alternatively, the adhesive may be somewhat tacky or sticky so that the user substantially can wrap the food item prior to exposure to microwave energy. Depending on the activatable adhesive employed and/or the amount of heat generated during cooking, some implementations of the invention may employ a susceptor layer under or adjacent the activatable adhesive to concentrate more heat in the area of the activatable adhesive and optimize bonding conditions.
In one aspect, a sheet or package arrangement with an activatable adhesive may include an insulating microwave material. For example, according to one aspect of the present invention, the self-sealing package includes an insulating material having expandable closed cells. Upon exposure to microwave energy, the cells expand to form inflated cells. While not wishing to be bound by theory, it is believed that the inflated cells enhance the cooking efficiency of a microwave oven by reducing heat loss to the environment surrounding the package. For example, a microwave package, tray, or the like with insulating cells arranged between the food item and the glass tray in most microwave ovens is believed to reduce heat transfer between the food and the tray, allowing the food to heat more efficiently. Additionally, after cooking, a package with inflated cells may be comfortable to the touch, thereby allowing a user to comfortably grasp the package and remove it from the microwave oven. Optionally, the sheet is provided with a susceptor material. In one aspect, the susceptor material is positioned so that when the cells expand, the susceptor is are pressed against the food item in the package to enhance the heating, browning, and/or crisping thereof.
Turning to
To assist the bonding and the formation of the sleeve 124, the user may place the overlapping portions 120, 122 of the sheet 110 under the food item 118 in a manner illustrated in
The food item 118 wrapped in the sheet 110 then is placed in the microwave oven (not shown) and heated. During microwave heating, the microwave energy and/or the heat associated therewith activates the adhesive, thereby causing the overlapping edges of the sheet to adhere. In this manner, the sheet 110 generally forms a sleeve 124 with two open ends 130, 132 around the food item 118.
Additionally, exposure to microwave energy causes the cells 116 to expand, as shown in
Further, where a susceptor material is used, the susceptor material is brought substantially into intimate and/or proximate contact with the food item 118 to brown or crisp the surface 136 thereof. Prior to cooking, some of the sheet 110 may not be in intimate contact with an irregularly shaped food item 118 wrapped therein. As such, only some portions of the food item will be exposed to the susceptor material. The lofting or expansion of the cells 116 of the sheet 110 causes the susceptor layer to bulge against the food item, providing increased contact with the food item 118, and thus more efficient heating, browning, and/or crisping thereof.
The exemplary sheet 110 depicted in
While various examples of self-sealing microwave sheets are shown and described herein, it should be understood that other arrangements and configurations are contemplated by the present invention. Thus, a microwave sheet may have a food contacting surface, a non-food contacting surface, or both, that is partially, substantially, or entirely covered by an activatable adhesive, for example, APET. In one aspect, the activatable adhesive, for example, APET, may cover substantially the food-contacting surface of the microwave sheet. In this manner, the food item may be placed on the sheet and the sheet folded over the food item a variety of possible ways to form a sleeve, a pocket, or some other container.
II. Heating and Shipping Microwave Interactive Sheet Employing Variably Sized and Variably Expansive Cells
Many food items are irregular in shape and small in size, making them difficult to insert into individual microwave susceptor sleeves for heating, browning, and crisping. Thus, according to another aspect of the present invention, a packaging material and package formed therefrom provides improved contact between the material and multiple food items or a single food item having an irregular shape.
The material and package formed therefrom includes closed expandable cells that expand during exposure to microwave energy to conform to the shape and size of the food item. The cells may include one or more microwave interactive elements or susceptors. The cells expand upon exposure to microwave energy, thereby bringing the susceptor material into closer proximity to the surface of the food item. In one aspect, individual food items are wrapped or packaged in an insulating material, for example, a material having cells of varying sizes and configurations that may expand to differing degrees (termed herein “variably expanding cells” or “variable expanding cells”). The material may be any suitable expandable cell material as desired, and in some instances, may include any of the materials described herein, any of the materials described in PCT Application PCT/US03/03779, which is incorporated by reference herein, or any combination thereof. Optionally, the material may be used to form a package that provides support for and protection of fragile food items during shipping and handling prior to cooking.
The variably expanding cells and the non-uniform arrangements of the same provide several advantages over presently available microwave packaging materials. First, the cells provide insulation along the bottom and periphery of the food item, thereby preventing heat loss to the surrounding environment. Second, multiple cell arrangements may be used to form a sheet for use in a package, so that multiple food items can be cooked in the same package. Third, where a susceptor is included, the size, shape, and level of expansion may be customized to accommodate any food item, thereby providing increased proximity to the susceptor material and improved browning and crisping during microwave heating.
The size, shape, and configuration of the expanding cells may vary for a particular application. The cells may be arranged in any pattern, including rows, concentric circles, arrays of shapes or individual cells, or any other pattern as desired. Likewise, the difference in size between each of the expandable cells may vary for a particular application. In one aspect, one or more cells varies from about 5 to about 15% in expanded volume, as compared with the expanded volume of another cell. In another aspect, one or more cells varies from about 15 to about 25% in expanded volume when compared with the volume of another cell. In another aspect, one or more cells varies from about 25 to about 35%, from about 35 to about 45%, from about 45 to about 55%, from about 55 to about 65%, from about 65 to about 75%, from about 75 to about 85%, from about 85 to about 95%, from about 95 to about 105%, from about 105 to about 110%, from about 110 to about 115%, from about 115 to about 85%, from about 85 to about 100%, from about 100 to about 125%, from about 125 to about 150%, from about 150 to about 175%, from about 175 to about 200%, from about 200 to about 225%, from about 225 to about 250%, from about 250 to about 275%, from about 275 to about 300%, from about 300 to about 325%, from about 325 to about 350%, from about 350 to about 400%, from about 400 to about 450%, from about 450 to about 500%, from about 500 to about 600%, from about 600 to about 700%, from about 700 to about 800%, from about 800 to about 900%, from about 900 to about 1000%, or greater than 1000% in expanded volume, as compared with the expanded volume of another cell.
In another aspect, one or more cells varies from about 5 to about 15% in unexpanded surface area, as compared with the unexpanded surface area of another cell. In another aspect, one or more cells varies from about 15 to about 25% in unexpanded surface area when compared with the unexpanded surface area of another cell. In another aspect, one or more cells varies from about 25 to about 35%, from about 35 to about 45%, from about 45 to about 55%, from about 55 to about 65%, from about 65 to about 75%, from about 75 to about 85%, from about 85 to about 95%, from about 95 to about 105%, from about 105 to about 110%, from about 110 to about 115%, from about 115 to about 85%, from about 85 to about 100%, from about 100 to about 125%, from about 125 to about 150%, from about 150 to about 175%, from about 175 to about 200%, from about 200 to about 225%, from about 225 to about 250%, from about 250 to about 275%, from about 275 to about 300%, from about 300 to about 325%, from about 325 to about 350%, from about 350 to about 400%, from about 400 to about 450%, from about 450 to about 500%, from about 500 to about 600%, from about 600 to about 700%, from about 700 to about 800%, from about 800 to about 900%, from about 900 to about 1000%, or greater than 1000% in unexpanded surface area, as compared with the unexpanded surface area of another cell.
In yet another aspect, cells may be provided around the periphery of the food item so that during microwave heating, the cells expand along the periphery of the food item and brown the sides of the food item. In another aspect, cells are provided beneath the food product and around it. The cells positioned under the food item may expand to one height, and the cells adjacent the perimeter of the food item may expand to a second height that is greater or less than the first height. In still another aspect, the cells may be arranged to form one or more cavities that can contain the individual food items. In this and other aspects, the susceptor material selectively is brought into proximate or intimate contact with the surface of the food item during expansion of the cells, thereby providing the desired degree of browning and crisping.
Additional examples are provided in
Turning to
Each of the four arrangements 214 of cells 212 of
If desired, a package employing the sheet 200 with variable cells 212 includes a paperboard or other type cover 228. The cover 228 may or may not include a microwave interactive material, such as a susceptor or antenna. Further, vertical dividers (not shown) may be provided to maintain appropriate alignment of the food items with the cell arrangements.
In this and other aspects, the sheet may include microwave active elements or susceptors. The susceptors may be flat, continuous, or patterned, and/or deployed in combination with shielding or pseudo-shielding elements, such as thicker aluminum patches. Additionally, individual cells may be provided with patterned microwave interactive functionality or susceptors, which can aid further in providing custom heating, browning, and crisping of the food item. Likewise, the area between the cell arrangements may include one or more of any of such elements as needed or desired for proper heat distribution.
As shown in
Various package arrangements with variably-sized or variably-expandable cell sheets are contemplated by the present invention. In one aspect, an expandable cell sheet is disposed on the bottom and top panels of a folding carton. In another aspect, an expandable cell sheet is adhered to a pouch or sleeve. Further, a sheet with variable cells may be provided with an activatable adhesive as described herein.
According to another aspect of the present invention, a sheet or package with variable cell arrangements may be used to pack and transport food items. Some food items are quite fragile, especially in the frozen state, and can be damaged by the normal stresses of distribution, shipping, and handling. It is known to provide thermoformed plastic trays with formed compartments to more securely hold the product. These trays are not typically capable, however, of providing susceptor functionality for microwave browning and crisping. Thus, according to this aspect, the sheet or package is exposed to microwave energy to expand the cells and hold the food items in place during shipping. The sheet or package may be exposed with or without the food item or items therein, for a period of from 1 to about 15 seconds, for example, 2 to 10 seconds. In doing so, the cells expand and provide support and protection for the food item or items contained therein.
Another exemplary package is provided in
If desired, the lid may be pulled back along perforations (not shown) located along or proximate edges 274a and 274b. The interior surface 276 of the lid 264 may include an insulating material 278, with or without a susceptor layer, such as those described herein. The insulating material 278 may include an oxygen barrier layer, variably sized and/or variably expanding cells, partially expanded cells, or numerous other features disclosed herein or contemplated hereby. To re-close the package 260 after being opened, the tab 266 may engage a corresponding slot 280 to secure the lid 264 in position. However, other means of securing the tab 266 are contemplated hereby.
If desired, additional insulating material 278 may be provided on one or more interior surfaces of the package, for example, on the bottom interior surface 288 to enhance heating, browning, and crisping of the food product, or to provide further insulation between the food item and the bottom of the tray and the floor of the microwave oven.
A package in accordance with this aspect of the present invention may be suitable for the packaging, transportation, and cooking of numerous types of food items. For example, the package may be used for irregularly shaped items, such as French fries, and may incorporate other features disclosed herein, such as variably expanding cells, such as those discussed above, and pre-expanded cells, such as those discussed below.
III. Insulating Material and Tray with Self-Forming Walls Formed Therewith
According to another aspect of the present invention, a microwave tray is provided. The tray is flat initially, but upon exposure to microwave energy, one or more flaps or edges of the tray fold upward to form flaps substantially perpendicular to the tray. The flaps serve to strengthen and support the tray. Moreover, if combined with microwave active elements, the flaps may improve browning and crisping of the sides of a food item in the tray.
To facilitate bending of the flaps 306a, 306b, 306c, and 306d, it is also possible to provide a score line 322, depression, or perforation at the desired fold line. The walls 324 substantially are transverse to the support 302, and serve to stiffen the tray 300 and minimize flexing thereof. Thus, upon removal of the tray 300 from the microwave oven, the food item is less likely to spill or fall from the tray 300.
As discussed above, to facilitate bending of the flaps 306a, 306b, 306c, and 306d, it is also possible to provide a score line 322, depression, or perforation at the desired fold line. The walls 324 substantially are transverse to the support 302, and serve to stiffen the tray 300 and minimize flexing thereof. Thus, upon removal of the tray 300 from the microwave oven, the food item is less likely to spill or fall from the tray 300.
IV. Insulating Microwave Material with Oxygen Barrier
According to another aspect of the present invention, a microwaveable material with an oxygen barrier and a package formed therefrom is provided. Such a material or package may lengthen the shelf life of a food item placed in the packaging. Moreover, the package may be used to contain and transport a food item. Numerous materials and packages having various layers and shapes are contemplated hereby.
Any suitable oxygen barrier material may be used in accordance with the present invention. Examples of materials that may be suitable include, but are not limited to, polyvinylidene chloride (PVdC), ethylene vinyl alcohol (EVOH), and DuPont DARTEK™ nylon 66 film may be applied in various manners including the various configurations discussed with regard to PVdC and EVOH. DuPont Dartek™ nylon 66 has a high melting point and good oxygen barrier properties.
The oxygen barrier material may be incorporated into any suitable insulating material including, but not limited to, those described herein. Typically, the insulating material has several layers. For example, the microwave insulating material may include an outer PET layer coated or otherwise provided with a metal layer (such as aluminum), and a paper or paperboard layer adhered to the PET layer, such that the metal layer is disposed between the PET layer and the paper layer. Typically, the food item is placed on the material adjacent the outer PET layer. The insulating material includes expandable cells defined by an arrangement or pattern of adhesive, such as in a grid pattern, between the paper layer and a second PET layer. As discussed in detail above, the cells expand upon exposure to microwave energy to provide an insulating feature and bring the susceptor in proximity to the food item.
The oxygen barrier material may be incorporated at any of numerous possible locations between layers of material.
An insulating microwave material with an oxygen barrier may be provided in a sealable package or construct. In such an exemplary construct, after the food item is inserted into the package, the package may be flushed with a gas or gas mixture, such as nitrogen and carbon dioxide, to displace the oxygen in the package, and sealed hermitically. The oxygen barrier helps to retard or eliminate the reentry of oxygen into the package. Such a package may help to reduce oxidation of and aerobic bacteria growth on a food item contained therein, and thus may reduce spoilage.
V. Formation of Insulating Microwave Structure using a Thermo-mechanical Device
Various aspects of the present invention disclosed herein or contemplated hereby involve use of an insulating material having expandable closed cells. According to another aspect of the present invention, the closed cells of the insulating material are formed by thermo-mechanically bonding one or more layers of the insulating material.
The thermo-mechanical bonds may be formed using a thermo-mechanical device, an impulse sealer, ultrasonic bonding device, heat bar, or any similar device, or any combination thereof configured in the desired cell pattern. Typically, an impulse sealer includes a nichrome wire or bend that is pulsed electrically to form a seal. An ultrasonic bonding device uses high frequency vibration, typically in the ultrasonic region, to create a thermo-mechanical bond. In one aspect, the bonding device is pressed against or deployed adjacent to an arrangement of material layers to form a pattern of bonding between portions of the layers. The pattern of bonding defines a plurality of closed cells that expand when exposed to microwave energy, the heat generated thereby, and/or expansion of gases in the cells brought on by exposure to microwave energy.
In one aspect, a container is formed from various layers of base material 600, such as those shown in
In another aspect, a container is formed from a microwave insulating sheet having pre-formed expandable cells, such as those shown and described herein. The insulating material including the expandable cells is positioned between the upper punch 622 and lower cavity 624. The tool then is closed, thereby forming the insulating material into a container.
VI. Method of Packaging a Food Item
According to another aspect of the present invention, a method and process for wrapping a food item in a sleeve of insulating microwave material is provided. If desired, the wrapped food item further may be overwrapped with a printed film.
Turning to
Turning to
Referring now to
In an alternative configuration (not shown), the plate 728 may be substituted by a second heat seal tool. In such a configuration, the second heat seal tool may oppose the first heal tool of the heat seal and cut-off tool, so that upon actuation, the two heat seal tools work in concert to form a seal between the first and second webs of insulating materials. In one aspect, the face of the heat sealing tool may be shaped to receive the blade, thereby preventing direct contact with the second heat sealing tool. For example, the face of the second heat sealing tool may be curved, notched, slotted, or otherwise configured to receive the portion of the blade that extends beyond the interface between the first and second heat sealing tools. If desired, the blade may travel from the heat seal and cutoff tool housing during actuation.
Referring again to
From
VII. Package With Reconfigurable Insulating Lid
In accordance with yet another aspect of the present invention shown in
Prior to being opened (
As shown in
If desired, additional insulating material 830 may be provided on one or more interior surfaces of the package to provide further insulation between the food item and the bottom of the tray and the floor of the microwave oven. Spacers along the lid surface that provide additional separation between the lid and the bottom of the tray in the folded-under position also may be provided. Ventilation holes 824 also may be provided.
It will be readily understood by those persons skilled in the art that, in view of the above detailed description of the invention, the present invention is susceptible of broad utility and application. Many adaptations of the present invention other than those herein described, as well as many variations, modifications, and equivalent arrangements will be apparent from or reasonably suggested by the present invention and the above detailed description thereof, without departing from the substance or scope of the present invention.
While the present invention is described herein in detail in relation to specific aspects, it is to be understood that this detailed description is only illustrative and exemplary of the present invention and is made merely for purposes of providing a full and enabling disclosure of the present invention. The detailed description set forth herein is not intended nor is to be construed to limit the present invention or otherwise to exclude any such other embodiments, adaptations, variations, modifications, and equivalent arrangements of the present invention. Accordingly, all directional references (e.g., upper, lower, upward, downward, left, right, leftward, rightward, top, bottom, above, below, vertical, horizontal, clockwise, and counterclockwise) are only used for identification purposes to aid the reader's understanding of the present invention, and do not create limitations, particularly as to the position, orientation, or use of the invention. Joinder references (e.g., attached, coupled, connected, and the like) are to be construed broadly and may include intermediate members between a connection of elements and relative movement between elements. As such, such joinder references do not necessarily infer that two elements are directly connected and in fixed relation to each other. Accordingly, the present invention is limited solely by the claims appended hereto and the equivalents thereof.
This application is a divisional of co-pending U.S. application Ser. No. 11/054,633, filed Feb. 9, 2005, which claims the benefit of U.S. Provisional Application No. 60/543,364, filed Feb. 9, 2004, both of which are incorporated by reference herein in their entirety.
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Number | Date | Country | |
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20080047958 A1 | Feb 2008 | US |
Number | Date | Country | |
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60543364 | Feb 2004 | US |
Number | Date | Country | |
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Parent | 11054633 | Feb 2005 | US |
Child | 11906845 | US |