Patent Description:
This application claims priority from US provisional application <CIT> and US provisional application <CIT>.

Coldseal is a water-based cohesive coating used to seal a variety of paper and film packaging materials. Coldseal is a self-seal adhesive only requiring pressure to seal. As the name implies, coldseal does not require heat. Coldseal cohesives are primarily used to seal heat-sensitive items like chocolate bars. The cohesive is typically applied wet to the substrate by a revolving gravure cylinder and immediately dried in an extended oven before it is reeled up at the end of the press.

Coldseal cohesive compositions known in the art typically comprise many non-biodegradable components, such as acrylic, styrene acrylics, and vinyl acetate emulsions. Thus, there is a need for new coldseal cohesive compositions that comprise low amounts of, or are free of, non-biodegradable and non-compostable components. The coldseal cohesive composition for use in the invention can thus be used in biodegradable packaging applications to afford products that undergo biodegradation and can be composted. New coldseal cohesive compositions must also satisfy the requirements for use, including suitably adhering to substrates and having suitable cohesive forces, in order to effectively seal packaging with the required sealing strength. <CIT> relates to the sealing of oriented isotactic polypropylene films. <CIT> relates to the sealing of foamed plastic sheet materials.

The inventors have discovered a water-based coldseal cohesive composition that comprises low amounts of, or is free of, non-biodegradable and non-compostable components. The water-based coldseal cohesive compositions for use in the invention have suitable properties for effective use in sealing packaging. The inventors have thus found a way to replace the non-biodegradable and non-compostable components that are present in the coldseal compositions of the art, in a way that does not compromise performance.

In particular, the present invention provides a structure comprising a water-based coldseal cohesive composition on a substrate, wherein the water-based coldseal cohesive composition comprises between <NUM> and 90wt% natural rubber latex, between <NUM> and 30wt% of a biodegradable resinous material, wherein the wt% refers to the solids content of the biodegradable resinous material. The biodegradable resinous material is a protein selected from the group consisting of casein, albumin, whey protein, soy protein, soy protein isolate, and combinations thereof. When the biodegradable resinous material is albumin, it is present in a solids content of at least 4wt% relative to the total weight of the water-based coldseal cohesive composition. The composition further comprises between <NUM> and 90wt% water. The substrate is selected from the group consisting of cellulose, polybutylene adipate terephthalate, polylactic acid, and combinations thereof. The coldseal cohesive composition is applied directly to the substrate. The composition comprises less than 10wt% of non-compostable material, wherein the non-compostable material is selected from the group consisting of acrylics, styrene acrylics, shellac-modified polystyrene, ethylene vinyl acetate, styrene butadiene, vinyl acetate, including emulsions thereof, and combinations thereof.

The invention further provides a packaged item comprising the structure of the invention. In addition, the invention provides a method of making the structure of the invention. Finally, the invention provides for the use of the coldseal compositions for use in the invention for sealing packaging.

Cohesive compositions are compositions that are capable of bonding to themselves, which can be used to join substrates together, such as packaging components. Cohesive compositions can be applied to the substrates of packaging components, which can be brought together and compressed in order to seal them together. Cohesive compositions bond to themselves, with the cohesive forces resisting separation. Cohesive compositions also act as adhesives and adhere to substrates, with the adhesive forces between the cohesive composition and the substrate also resisting separation.

Coldseal cohesives/adhesives are water-based natural rubber latexes primarily used to seal heat-sensitive items, such as chocolate bars. Coldseal is a self-seal adhesive that only requires pressure in order to seal (i.e., it does not require heat).

Unless otherwise stated, all ranges include the respective end points. For example, a range of between <NUM> and <NUM>, includes the end points <NUM> and <NUM>. However, where an end point is defined as being "more than" one value and/or up to "less than" another value, the range does not include the respective end points.

Unless otherwise stated, wt% (w/w) refers to the mass of the component in question in relation to all components present in the composition, including any solvents present. Unless otherwise specified, method steps are intended to be performed in the order in which they are recited.

In the context of the present application, compostability refers to the ability of some materials to disintegrate within a specified timeframe under controlled conditions (see, ASTM D6400-<NUM>, point <NUM>, ASTM D6868-<NUM>, point <NUM>, and EN13432). Biodegradability refers to the conversion of organic carbon present in a sample into carbon dioxide under controlled conditions (see ASTM D6400-<NUM>, point <NUM>, ASTM D6868-<NUM>, point <NUM>, and EN13432). Where the compostability or biodegradability are defined in terms of a percentage, it is the percentage of the original material that is lost (either through sieving or as carbon dioxide) following the tests outlined in one of the above-mentioned standards. The percentage may not necessarily be compliant with the limit recited in the relevant test.

Polymeric carbohydrates are carbohydrates that comprise at least <NUM> monosaccharide units in a chain.

Converters are companies that specialize in modifying or combining raw materials such as polyesters, adhesives, silicone, adhesive tapes, foams, plastics, felts, rubbers, liners and metals, as well as other materials, to create new products.

Directive (EU) <NUM>/<NUM> is the last amendment of Directive <NUM>/<NUM>/EC and contains updated measures designed to prevent the production of packaging waste, and promote the reuse, recycling and other forms of recovering of packaging waste, instead of its final disposal, thus contributing to the transition towards a circular economy.

Converters have expressed interest in a biodegradable or compostable coldseal adhesive. However, none are currently available on the market. Aside from the need for coldseal cohesives on heat-sensitive packaging items, converters in Europe would avoid taxation in <NUM> by using a coldseal cohesive listed under European Waste "Directive (EU) <NUM>/<NUM> Article <NUM>(<NUM>)". The present application describes development of biodegradable and/or compostable coldseal cohesives with performance that is at least as good as currently available non-biodegradable and/or non-compostable products, when used on biodegradable and/or compostable substrates. Compostable packaging comprising the coldseal adhesive of the invention can be composted in a way that does not hinder composting activity.

The development approach comprises combining natural rubber latex (NRL) with other suitable biodegradable and/or compostable raw materials, for example proteins (e.g. casein, albumin, soy protein and soy protein isolate); and polymeric carbohydrates (e.g. starch, dextrin).

The coldseal cohesive composition for use in the invention comprises an NRL. The NRL for use in the invention maybe be water-based. Hevea brasiliensis is the major source of NRL but natural rubber is synthesized in over <NUM> plant species and, for example, NRL produced by guayule (Parthenium argentatum Gray) or the Russian dandelion (Taraxacum koksaghyz), could be used within the scope of this invention.

It has surprisingly been found that biodegradable and/or compostable materials can be used to replace the non-biodegradable materials typically incorporated into coldseal compositions of the art, to provide compositions that have cohesive, adhesive, and blocking properties that are at least comparative with compositions of the art.

The biodegradable resinous material for use in the compositions for use in the invention is in the form of a resin (i.e., it is resinous). The biodegradable resinous material for use in the invention is a protein selected from the group consisting of casein, albumin, whey protein, soy protein, soy protein isolate, and combinations thereof. The biodegradable resinous material for use in the invention is preferably casein and/or albumin.

Other biodegradable resinous materials include polymeric carbohydrates such as starch, dextrin, cellulose, cyclodextrins, pectin, chitin, chitosan, hyaluronic acid, carrageenan gum, xanthan gum, and combinations therefore.

The biodegradable resinous material for use in the invention may be combination of two or more of the proteins discussed above.

The biodegradable resinous material preferably imparts adhesion and anti-blocking properties to the formulation, properties that are normally achieved in non-biodegradable or non-compostable coldseal cohesives by combining NRL with various acrylic, styrene acrylics, vinyl acetate, or similar non-biodegradable and/or non-compostable emulsions.

Packaging material is a finished product that can be considered compostable only if it's strictly compliant to certain criteria that ensures that the composting process will take place according to set rules and restrictions and in a controlled way, as opposed to a generic and uncontrolled biodegradation process. Specific regulations are in place in different regions. In general, the criteria are similar and stipulate that the compost produced is of good-quality and does not contain contaminants.

Packaging products include different constituents, which are classified as "components. " These include the substrate, inks, coldseals, adhesives and others. All components must comply with set rules. However, the complexity of these rules is a function of the components' maximum weight percentage in the packaging product. The substrate is normally the main component and the one that plays the most active part in the composting process. For this reason, compostable substrates are independently tested, not only for chemical composition and ecotoxicity, but also for biodegradation and disintegration, unlike components that don't exceed a certain weight percentage, as defined by the relevant standard.

According to the main international standards (i.e., ASTM <NUM>, ASTM D6868-<NUM>, EN13432), products applied at weight percentages higher than <NUM>% would be considered package "constituents. " They would have to pass not only eco-toxicity and chemical analysis tests, but also the same biodegradation and disintegration tests required for the main packaging component, which is the actively compostable substrate.

Compostability is commonly measured according to the following standards: European EN <NUM> (covering all packaging types), and the North American ASTM D6400-<NUM> and D6868-<NUM> standards (covering plastic and paper packaging products, respectively).

The European EN <NUM> Standard has been adopted by many national standard bodies in many European Union member states. Key tests and pass/fail criteria are:.

The North American ASTM D6400-<NUM>/D6868-<NUM> Standards is similar to the EN <NUM> Standard, but the NA ASTM D6400-<NUM>/D6868-<NUM> Standards are also aimed at supporting the evidence that "the entire product or package will completely break down and return to nature within a reasonably short period of time after customary disposal," which in this case is defined as <NUM> days for fragmentation of at least <NUM>% of the product and <NUM> days for complete mineralization in a properly managed composting facility.

The main difference between ASTM D6400-<NUM>/D6868-<NUM> and the EN13432 standard is that coatings / adhesives / coldseals and other components of the package with high application limits at a weight percentage between <NUM>% and <NUM>% require additional biodegradation tests in ASTM D6400-<NUM>/<NUM>, wherein each component is tested individually.

The water-based coldseal cohesive compositions for use in the invention disintegrate under the conditions outlined in ASTM D6400-<NUM>, ASTM D6868-<NUM>, or EN13432 (see point <NUM>) such that no more than <NUM>% of its dry weight remains after sieving on a <NUM> sieve (i.e., the composition is compostable to ≥<NUM>%). The water-based coldseal cohesive compositions for use inthe invention preferably disintegrate under the conditions outlined in ASTM D6400-<NUM>, ASTM D6868-<NUM> (see point <NUM>), or EN13432, such that no more than <NUM>% of its dry weight remains after sieving on a <NUM> sieve (i.e., the composition is compostable to ≥<NUM>%), such as more preferably no more than <NUM>% of its dry weight remains after sieving on a <NUM> sieve (i.e., the composition is compostable to ≥<NUM>%). In other words, the water-based coldseal cohesive compositions for use inthe invention pass the test conditions outlined in either ASTM D6400-<NUM> (point <NUM>), ASTM D6868-<NUM> (point <NUM>), EN13432. The water-based coldseal cohesive compositions for use inthe invention preferably pass the test conditions outlined in both ASTM D6400-<NUM> (point <NUM>) and ASTM D6868-<NUM>.

The water-based coldseal cohesive compositions for use in the invention may also biodegrade under the conditions outlined in either of ASTM D6400-<NUM>, ASTM D6868-<NUM> (see point <NUM>), or EN13432, such that at least <NUM>% of the organic carbon present is converted to carbon dioxide (i.e. the composition is biodegradable to at least <NUM>%). The water-based coldseal cohesive compositions for use inthe invention preferably biodegrade under the conditions outlined in either of ASTM D6400-<NUM>, ASTM D6868-<NUM>, or EN13432 (see point <NUM>) such that at least <NUM>% of the organic carbon present is converted to carbon dioxide (i.e. the composition is biodegradable to at least <NUM>%), such as more preferably at least <NUM>% of the organic carbon present is converted to carbon dioxide (i.e. the composition is biodegradable to at least <NUM>%). The water-based coldseal cohesive compositions for use inthe invention may biodegrade under the conditions outlined in EN13432 and comply with this standard.

The water-based coldseal cohesive compositions for use inthe invention may comply with at least one of ASTM D6400-<NUM>, ASTM D6868-<NUM>, and/or EN13432. The water-based coldseal cohesive compositions for use inthe invention preferably comply with at least EN13432. The water-based coldseal cohesive compositions for use inthe invention may comply with all of ASTM D6400-<NUM>, ASTM D6868-<NUM>, and EN13432.

The coldseal cohesive compositions for use inthe invention may further comprise one or more additives. The additives may be selected from the group consisting of anti-foaming agents, biocide agents, and combinations thereof.

As discussed, the biodegradable resinous materials are preferably solutions or dispersions of the biodegradable resinous materials in a solvent. The solvent is preferably water. The coldseal cohesive compositions for use inthe invention preferably comprise between <NUM> and <NUM> wt% of a solution or dispersion of the one or more biodegradable resinous materials, such as between <NUM> and 60wt%, and more preferably between <NUM> and 50wt%, such between <NUM> and <NUM> wt% of a solution or dispersion of the one of more biodegradable resinous materials.

The biodegradable resinous solvents and dispersions preferably have a solids content of between <NUM> and <NUM> wt%, more preferably of between <NUM> and <NUM> wt%, and even more preferably of between <NUM> and <NUM> wt%, such as between <NUM> and <NUM> wt%. Accordingly, the coldseal cohesive compositions for use in the invention comprises between <NUM> and <NUM> wt% of biodegradable resinous solids (e.g. casein and albumin), such as between <NUM> and <NUM> wt%, and more preferably between <NUM> and 15wt%, such as between <NUM> and <NUM> wt%, and even more preferably between <NUM> and <NUM> wt% of biodegradable resinous solids (e.g. casein and albumin).

When the biodegradable resinous material is albumin, the coldseal cohesive compositions for use in the invention comprise at least 4wt% albumin solids relative to the total weight of the water-based coldseal cohesive composition. The coldseal cohesive compositions for use in the invention may comprise between <NUM> and 15wt% albumin solids, and preferably between <NUM> and 10wt%, and even more preferably between <NUM> and <NUM> wt% albumin solids.

The coldseal cohesive compositions for use in the invention comprises between <NUM> and <NUM> wt% of NRL, such as between <NUM> and 80wt%, and more preferably between <NUM> and 70wt%. The NRLs for use in the invention comprise natural rubber and water.

The NRL for use in the invention preferably has a solids content between <NUM> and 90wt%, such as more preferably between <NUM> and <NUM> wt%, and most preferably between <NUM> and <NUM> wt%, such as around <NUM> wt%. Accordingly, the coldseal cohesive compositions for use in the invention preferably comprise between <NUM> and <NUM> wt% of natural rubber solids, such as between <NUM> and <NUM> wt%, more preferably between <NUM> and <NUM> wt% of natural rubber solids, and even more preferably between <NUM> wt% and <NUM> wt% of natural rubber solids, such as between 25wt% and 36wt% of natural rubber solids.

When the biodegradable resinous material comprises albumin, it is preferred that the coldseal cohesive composition comprises between <NUM> and <NUM> wt% natural rubber solids, more preferably between <NUM> and <NUM> wt% of natural rubber solids, and even more preferably between <NUM> wt% and <NUM> wt% of natural rubber solids.

The coldseal cohesive composition for use in the invention comprises less than 10wt%, and preferably less than <NUM> wt%, of non-compostable materials. The coldseal cohesive composition for use in the invention may be free of non-compostable materials.

The coldseal cohesive composition for use in the invention preferably comprises less than 50wt% of non-compostable materials, relative to the total solids content, such as less than 40wt%, more preferably less than 30wt%, such as less than <NUM> wt%, less than 10wt%, and even more preferably less than <NUM> wt% of non-compostable materials relative to the total solids content.

The coldseal cohesive composition for use in the invention preferably comprises less than 70wt% of non-biodegradable materials, such as less than 60wt%, and more preferably less than 50wt% of non- biodegradable materials.

Non-biodegradable or non-compostable materials are materials that are non-compliant with the following standards: EN <NUM> (covering all packaging types), ASTM D6400-<NUM> and D6868-<NUM> (covering plastic and paper packaging products, respectively). In particular, non-compostable materials fail at least one of the relevant tests outlined in ASTM D6400-<NUM> (point <NUM>), ASTM D6868-<NUM> (point <NUM>) or EN13432. Non-biodegradable materials fail at least one of the relevant tests outlined in ASTM D6400-<NUM> (point <NUM>), ASTM D6868-<NUM> (point <NUM>) or EN13432. Examples of non-biodegradable and/or non-compostable materials include acrylics, styrene acrylics, shellac-modified polystyrene, ethylene vinyl acetate, styrene butadiene, vinyl acetate, and emulsions of any of the aforementioned.

The coldseal cohesive composition for use in the invention preferably comprises natural rubber solids and biodegradable resinous material solids in a ratio of between <NUM>:<NUM> to <NUM>:<NUM>, such as between <NUM>:<NUM> and <NUM>:<NUM>. The coldseal cohesive composition for use in the invention more preferably comprises natural rubber solids and biodegradable resinous material solids in a ratio of between <NUM>:<NUM> to <NUM>:<NUM>, such as between <NUM>:<NUM> and <NUM>:<NUM>.

The coldseal cohesive composition for use in the invention even more preferably comprises natural rubber solids and biodegradable resinous material solids in a ratio of between <NUM>:<NUM> to <NUM>:<NUM>.

The coldseal cohesive compositions for use in the invention comprise water in an amount between <NUM> and <NUM> wt%, such as between <NUM> and <NUM> wt%, more preferably between <NUM> and <NUM> wt%, and even more preferably the coldseal cohesive compositions for use in the invention comprise water in an amount between <NUM> and <NUM> wt%.

The coldseal cohesive composition for use in the invention preferably has a solids content between <NUM> and 60wt%, such as between <NUM> and <NUM> wt%, or more preferably between <NUM> and 48wt%.

The coldseal cohesive composition for use in the invention may comprise one or more additives in an amount up to <NUM> wt%, such as up to <NUM> wt%, preferably up to 5wt%, more preferably up to <NUM> wt%, and even more preferably up to <NUM> wt% of one or more additives.

The coldseal cohesive compositions for use in the invention may comprise between <NUM> and 15wt% of biodegradable resinous solids (e.g. casein and/or albumin), between <NUM> wt% and <NUM> wt% of natural rubber solids, between <NUM> and <NUM> wt% water, and optionally up to <NUM> wt% of one or more additives. The coldseal cohesive compositions for use in the invention may comprise between <NUM> and <NUM> wt% solids. The coldseal cohesive compositions for use in the invention may comprise less than <NUM> wt% of non-biodegradable and non-compostable materials.

The coldseal cohesive compositions for use in the invention preferably comprise between <NUM> and 15wt% of biodegradable resinous solids (e.g. casein and/or albumin), between <NUM> wt% and <NUM> wt% of natural rubber solids, between <NUM> and <NUM> wt% water, and optionally up to <NUM> wt% of one or more additives. The coldseal cohesive compositions for use in the invention preferably comprise between <NUM> and <NUM> wt% solids. The coldseal cohesive compositions for use in the invention preferably comprise less than <NUM> wt% of non-biodegradable and non-compostable materials.

The coldseal cohesive compositions for use in the invention more preferably comprise between <NUM> and 8wt% of biodegradable resinous solids (e.g. casein and/or albumin), between <NUM> wt% and <NUM> wt% of natural rubber solids, between <NUM> and <NUM> wt% water, and optionally up to <NUM> wt% of one or more additives. The coldseal cohesive compositions for use in the invention more preferably comprise between <NUM> and <NUM> wt% solids. The coldseal cohesive composition for use in the invention more preferably comprise less than <NUM> wt% of non-biodegradable and non-compostable materials.

The invention further provides a structure comprising the coldseal cohesive composition for use in the invention on a substrate. The structure maybe a printed structure further comprising an additional printed layer on the substrate. Moreover, the coldseal cohesive composition for use in the invention may be printed onto the substrate. The structure of the invention may be a printed packaging structure, for example, for a food item.

The structure of the invention may comprise the coldseal cohesive composition for use in the invention coated onto the substrate at a dry coat weight of between <NUM> and <NUM>/m<NUM>, such as between <NUM> and <NUM>/m<NUM>, more preferably between <NUM> and <NUM>/m<NUM>, and even more preferably between <NUM> and <NUM>/m<NUM>. The coldseal cohesive composition for use in the invention may represent greater than <NUM> wt% of the total mass of the structure.

The substrate may have a thickness of between <NUM> and <NUM>, such as between <NUM> and <NUM>, preferably between <NUM> and <NUM>, and more preferably between <NUM> and <NUM>, such as between <NUM> and <NUM>.

The substrate is a biodegradable substrate selected from cellulose, polybutylene adipate terephthalate, polylactic acid, including substrates derived from corn, sugar cane, or bamboo. Cellulose films may be derived from natural sources, including hemp, wood, and cotton.

The structure of the invention is compostable. For example, the structure of the invention disintegrates under the conditions outlined in ASTM D6400-<NUM>, point <NUM>, ASTM D6868-<NUM> point <NUM>, or EN13432, such that no more than <NUM>% of its dry weight remains after sieving on a <NUM> sieve (i.e., the structure is compostable to ≥<NUM>%). The structure of the invention preferably disintegrates under the conditions outlined in either of ASTM D6400-<NUM>, point <NUM>, ASTM D6868-<NUM>, point <NUM>, or EN13432, such that no more than <NUM>% of its dry weight remains after sieving on a <NUM> sieve (i.e., the structure is compostable to ≥<NUM>%), such as more preferably no more than <NUM>% of its dry weight remains after sieving on a <NUM> sieve (i.e., the structure is compostable to ≥<NUM>%). In other words, the structure of the invention passes the test conditions outlined in ASTM D6400-<NUM> (point <NUM>), ASTM D6868-<NUM> (point <NUM>), or EN13432. The structure of the invention preferably passes the test conditions outlined in both ASTM D6400-<NUM> (point <NUM>) and ASTM D6868-<NUM> (point <NUM>).

The structure of the invention may biodegrade under the conditions outlined in either of ASTM D6400-<NUM>, ASTM D6868-<NUM>, or EN13432 (see point <NUM>) such that at least <NUM>% of the organic carbon present in each individual component is converted to carbon dioxide (i.e. the printed substrate is biodegradable to at least <NUM>%). The structure of the invention preferably biodegrades under the conditions outlined in either of ASTM D6400-<NUM>. ASTM D6868-<NUM>, or EN13432 (see point <NUM>) such that at least <NUM>% of the organic carbon present is converted to carbon dioxide (i.e. the printed substrate is biodegradable to at least <NUM>%), such as more preferably at least <NUM>% of the organic carbon present is converted to carbon dioxide (i.e. the printed substrate is biodegradable to at least <NUM>%). The structure of the invention may biodegrade under the conditions outlined in EN13432 and complies with this standard.

While the invention uses the coldseal cohesive composition for use in the invention on compostable/biodegradable substrates, the coldseal cohesive composition for use in the invention can also be used on non-compostable and/or non-biodegradable substrates, including polyolefins such as polyethylene, polytetrafluoroethylene, polypropylene, and polymethylpentene, polyesters such as polyethylene terephthalate (PET) and polybutylene terephthalate (PBT), polycarbonates, polystyrene, nylon, polyurethanes, and acrylics.

The invention also provides a packaged item comprising the structure of the invention. The structure of the invention thus forming the packaging for the item. The item can be a food item, such as a heat-sensitive food item including chocolate. The item can be a non-food, heat-sensitive item, such as a pharmaceutical item.

The invention further provides a method of making the coldseal cohesive composition for use in the invention, comprising the steps of a) providing a natural rubber latex and a biodegradable resinous material; and b) mixing the natural rubber latex and the biodegradable resinous material in water to form the coldseal cohesive composition.

The invention also provides a method of making the structure or packaged item of the invention comprising the steps of a) providing the coldseal cohesive composition for use in the invention, and b) applying the coldseal cohesive composition to a substrate to make a coated substrate. The method may further comprise the steps of c) contacting the coated substrate with a second substrate, and d) applying pressure to the two substrates. The second substrate may also be coated with the coldseal cohesive composition for use in the invention. The step of applying the cohesive composition to a substrate may comprise printing the coldseal cohesive composition onto the substrate. Preferred methods include gravure and flexographic printing, with gravure most preferred.

The invention further provides the use of the coldseal cohesive composition for use in the invention for sealing packaging.

The invention is further described by the following non-limiting examples which further illustrate the invention, and are not intended, nor should they be interpreted to, limit the scope of the invention.

Viscosity: Tested using the DIN4 viscosity cup at <NUM>. Preferred viscosity is <NUM> - <NUM> with DIN4 at <NUM>.

T Peel Test: The composition for use in the invention are adjusted to print viscosity (<NUM>-<NUM> DIN4 @ <NUM>) with water and then printed onto ether a Natureflex™ NVS or Jindal OPPalyte™ MW247 substrate using a <NUM> red K-bar giving dry coat weights of <NUM> - <NUM>/m<NUM> depending on the solid contents. Print samples are cut into <NUM> strips and sealed with a pressure of <NUM> kPa (<NUM> psi) for <NUM> second using a RDM Pneumatic meshing twin crimp jaws sealing machine. Technical specification: Crimp jaws <NUM> pitch/<NUM> angle; area of jaws 150x25mm. The seals are then separated in a T-peel at room temperature (<NUM>-<NUM>) on a Lloyd Instruments LRX tensile tester at <NUM>/min; ensuring the "tail" is supported at an angle of <NUM>° to the vertical. Results are expressed in N/<NUM>. Target T-peel seal strength results: Preferably between <NUM> - <NUM> N/<NUM>, and more preferably between <NUM> - <NUM> N/<NUM>.

Adhesion Test: Approximately <NUM> of a <NUM> wide strip of Tesa <NUM> adhesive tape with a <NUM> pre-folded end is carefully applied with firm finger pressure to the coldseal surface, ensuring no air bubbles are trapped. The structure is then separated in a T-peel test at room temperature (<NUM>-<NUM>) on a Lloyd Instruments LRX tensile tester at <NUM>/min; ensuring the "tail" is supported at an angle of <NUM>° to the vertical. The tape (pre-folded end) being in the top jaw; film and coldseal in the bottom jaw. Results are expressed in N/<NUM>. Preferred adhesion result is ≥ <NUM> N/<NUM>.

Blocking test: The samples are placed in a Specac press with platens having a diameter of <NUM> under <NUM> tons of pressure for <NUM> hours at room temperature (<NUM>-<NUM>). <NUM> printed strips are cut from the samples and then separated in a T-peel test at room temperature (<NUM>-<NUM>) on a Lloyd Instruments LRX tensile tester at <NUM>/min; ensuring the "tail" is supported at an angle of <NUM>° to the vertical. Acceptable blocking is in the range of ≤ <NUM>. 5N/<NUM> with or without a compostable release lacquer applied on the opposite side to the coldseal.

Air Entrainment Foam Test: Performed at room temperature (<NUM>-<NUM>). <NUM> of coldseal are placed in a <NUM> measuring cylinder with an internal diameter of <NUM>. Air bubbling is generated in the sample with an "aquarium pump" Interpet Aqua Air AP4 for <NUM> mins with the twin outlets combined to feed one porous stone (<NUM> diameter, <NUM> length) placed at the bottom of the cylinder, the increase in volume is then recorded.

Acceptable maximum increase <NUM>. The samples are then left to stand for <NUM> and the new volume is recorded to assess reduction in foaming.

Field disintegration test (Compostability) in an industrial compostable facility: The substate Natureflex™ NVS film was coated with RESR736 on one side at <NUM> dry/m<NUM> (<NUM>% coverage) and with the composition to be tested on the other side (<NUM> dry/m<NUM>; either <NUM>% coverage or <NUM>% coverage applied on the edges of the sheet of the substrate). Testing was then performed at the COMPOST MANUFACTURING ALLIANCE (CMA). Samples with <NUM>% coverage were kept as sheets while samples with <NUM>% coverage were cold-sealed as pouches with the inventive example <NUM> being the sealant and inside the pouches. The samples were tested according to ASTM D6400-<NUM>, point <NUM> and EN13432.

Examples were adjusted to print viscosity (<NUM>-<NUM> DIN4 @ <NUM>) with water and printed using a <NUM> red K-bar giving dry coat weights of <NUM> - <NUM>/m<NUM> depending on the solid contents of the examples.

Comparative Example <NUM> is ADHC009 (also known as Polarseal S8044 CS) and is used as a reference. S8044 is a commercial, non-compostable, high-performance, natural rubber latex based coldseal from SunChemical, and is designed to give high-ranking results on a wide range of OPP films. S8044 has a solid content of <NUM>% and a viscosity (DIN4 @ <NUM>) of <NUM>. S8044 comprises around 40wt% non-compostable material. S8044 was printed using an <NUM> Grey K-bar giving a dry coat weight of <NUM>/m<NUM>.

On treated MW247, Inventive Examples <NUM>-<NUM> all performed well, with seal strength being within the preferred range and similar to Comparative Example <NUM>. On untreated MW247, Inventive Examples <NUM>-<NUM> all performed well, with seal strength being within the preferred range. Good seal strengths were obtained on NVS compostable film for all three Inventive Examples (similar to Comparative Example <NUM>), with Inventive Example <NUM> being most preferred due to higher seal strengths and higher solid contents.

All three Inventive Examples exhibit good adhesion on both substrates (within the preferred range), similar to Comparative Example <NUM>.

Quite surprisingly, the inventive formulations release well from both sides of NVS compostable film without release lacquer with forces much lower than the acceptable limit of <NUM>. This means that the biodegradable or compostable coldseal could potentially be used in a laminate structure with NVS film reverse printed as the release film. This would be highly advantageous as the same coldseal could be used in monoweb and laminate applications.

Comparative Example <NUM> is normally used in combination with release lacquers and the high blocking values observed on both substrates were expected.

The inventive formulations did not produce the same acceptable blocking results on the MW247 standard film. Thus, if a user wanted to use the inventive biodegradable or compostable coldseal on a non-compostable OPP, the use of a release lacquer would likely be needed.

SunChemical patented compostable release lacquer RESR736 was applied at a dry coat weight of <NUM>/m<NUM> on the opposite side before applying the various coldseals. As expected, blocking is improved with the use of the compostable release lacquer RESR736 with samples showing virtually no blocking on both films. RESR736 is a solvent-based varnish based on a biodegradable compostable polyamide resin. The solids content of the varnish is <NUM>-<NUM>%.

All three inventive examples performed within the preferred volume increase limit of <NUM>. Lower foaming is a preferred property as foaming on press in the duct or when the coldseal is pumped or goes through recirculation systems can negatively affect runnability and quality of the print.

After <NUM> minute of rest without air bubbled through the samples, all samples saw a considerable decrease in volume of foam. This is an important factor since if the configuration of the press generates foam in the coldseal, it would be desirable for the foam to dissipate as quickly as possible to avoid the problems previously mentioned.

Field disintegration testing in an industrial compostable facility was performed according to the method described above using inventive example <NUM> as the composition to be tested. All samples meet ASTM D6400-<NUM> and EN13432 criteria for compostability with a recovery of less than <NUM>% within <NUM> days of active composting. In other words, all samples meet the criteria of point <NUM> of ASTMs D6400-<NUM> and D6868-<NUM>, as well as the compostability test of EN13432.

Examples <NUM> to <NUM> did not need viscosity adjustment with water and were printed using either a <NUM> or <NUM> K-bar giving dry coat weights of <NUM> - <NUM>/m<NUM> depending on the solid contents of the examples.

On both substrates, Inventive example <NUM> performed well, with seal strength being within the preferred range and similar to Comparative Example <NUM>. On the other hand, Inventive example <NUM> did not achieve the desired level of seal strength on both substrates while inventive example <NUM> did not achieve the desired level of bond strength on the NVS film (preferred film for coldseal applications) and narrowly gave an acceptable result on the NP film.

Results are expressed in N/<NUM>. Adhesion Result Preferred is ≥ <NUM> N/<NUM>. Tests carried out as previously described.

Inventive Example <NUM> exhibit good adhesion on both substrates (within the preferred range). Inventive Example <NUM> and <NUM> did not perform well on the NVS (preferred film for coldseal applications) but achieved good adhesion on the NP substrate.

Sun Chemical patented compostable release lacquer RESR736 was applied at a dry coat weight of <NUM>/m<NUM> on the opposite side before applying the Inventive Example <NUM>. Only Inventive example <NUM> was tested for blocking as it was the overall best performing system containing albumin. Tests carried out as previously described.

Quite surprisingly, the inventive formulation Example <NUM> release well from both sides of NVS and NP compostable film without release lacquer with forces lower than the acceptable limit of <NUM>. This means that the compostable coldseal could potentially be used in a laminate structure with NVS or NP films reverse printed as the release film. This would be highly advantageous as the same coldseal could be used in monoweb and laminate applications.

As expected, blocking is improved with the use of the compostable release lacquer RESR736 with samples showing virtually no blocking on both films.

CareTips 300D, produced by Lactips, is the first natural pellet made of <NUM>% biobased ingredients and is fully biodegradable. The pellets contain approximately <NUM>-<NUM>% water. The <NUM>% solids solution used in the inventive examples <NUM> and <NUM> was prepared by dissolving under moderate agitation at room temperature <NUM>% by weight of the pellets in water containing <NUM>% of Tego Foamex <NUM> defoamer and <NUM>% of Proxel BD <NUM> biocide.

Examples <NUM> and <NUM> were adjusted to print viscosity (<NUM>-<NUM> DIN4 @ <NUM>) with water and printed using a <NUM> red K-bar giving dry coat weights of <NUM> and <NUM>/m<NUM> depending on the solid contents of the examples.

Results are expressed in N/<NUM>. Target T-peel seal strength results: Preferably <NUM> - <NUM> N/<NUM>, more preferably <NUM> - <NUM> N/<NUM>. Tests Carried out as previously described. On both substrates, Inventive Example <NUM> and <NUM> performed well, with seal strengths being within the preferred range or slightly greater for example <NUM> on Natureflex NP which is a favourable outcome.

Results are expressed in N/<NUM>. Adhesion Result Preferred is ≥ <NUM> N/<NUM>. Tests carried out as previously described. Inventive Examples <NUM> and <NUM> exhibit good adhesion on both substrates (within the preferred range).

SunChemical patented compostable release lacquer RESR736 was applied at a dry coat weight of <NUM>/m<NUM> on the opposite side before applying the coldseals. With the use of the compostable release lacquer RESR736, examples <NUM> and <NUM> show virtually no blocking on both films.

Both Inventive Examples <NUM> and <NUM> performed within the preferred volume increase limit of <NUM>. Lower foaming is a preferred property as foaming on press in the duct or when the coldseal is pumped or goes through recirculation systems can negatively affect runnability and quality of the print.

Claim 1:
A structure comprising a water-based coldseal cohesive composition on a substrate; wherein the water-based coldseal cohesive composition comprises;
a) between <NUM> and 90wt% of natural rubber latex;
b) between <NUM> and 30wt% of a biodegradable resinous material, wherein the wt% refers to the solids content of the biodegradable resinous material; wherein the biodegradable resinous material is a protein selected from the group consisting of casein, albumin, whey protein, soy protein, soy protein isolate, and combinations thereof, and wherein when the biodegradable resinous material is albumin, it is present in a solids content of at least 4wt% relative to the total weight of the water-based coldseal cohesive composition; and
c) between <NUM> and 90wt% water;
wherein the substrate is selected from the group consisting of cellulose, polybutylene adipate terephthalate, polylactic acid, and combinations thereof;
wherein the coldseal cohesive composition is applied directly to the substrate; and
wherein the composition comprises less than 10wt% of non-compostable material, wherein the non-compostable material is selected from the group consisting of acrylics, styrene acrylics, shellac-modified polystyrene, ethylene vinyl acetate, styrene butadiene, vinyl acetate, including emulsions thereof, and combinations thereof.