❄️Frosty Forbidden Candy Dice❄️

Another one of the candy colors dice designs (no eating!!!) all nicely inked and ready to roll ✨ Cast in Resin Pro Bioresin.

In late 2022, an initiative between the University of Maine and local nonprofit Penquis unveiled its prototype — BioHome3D, the first 100-percent recyclable house. Now, the pioneering project is working toward completing its first livable housing complex. It will be fully bio-based, meaning all materials will be derived from living organisms such as plants and other renewable agricultural, marine and forestry materials. 

a neighborhood of 600-square-foot, 3D-printed, bio-based houses crafted from materials like wood fibers and bioresins. The aim: a complex of 100-percent recyclable buildings that will provide homes to those experiencing houselessness.

Okay since I work with resin and am apparently the only resin creator that knows this, everybody listen the fuck up. This includes buyers and creators.

Unless a special heat proof and light fast resin is used, do not make/buy coasters, candle holders, or lamps. Resin is plastic. Plain and simple. If you put heat on it, it will melt an itty-bitty bit and release fumes into the air. Now it's not enough to do any real damage, so that's not the problem. What's really the issue is that it will affect the color. If you put a candle in a pretty crystal shaped resin candle holder, it will turn the resin closest to the flame yellow and eventually brown. If you put hot cups or pots on resin coasters, they will eventually turn yellow and then brown. If you have an led in your resin sculpture that you turn on a lot, it will happen much slower but your resin will turn yellow.

Now this happens with any resin with age, it is plastic, it degrades and it discolors, but it will do it faster if you introduce heat or moisture. By the way don't put resin in your food or water it does put toxins in it. Again miniscule with no more effect than the microplastics in your fish filet on your health but if it can be avoided why not?

If you can afford a bioresin (ie made from organic resins like the kind that makes ambers) then by all means go for it, to my limited knowledge about them they're far less toxic, but I have a sneaking suspicion they degrade faster. I also do not know how they hold up to heat and moisture, but I suspect they degrade faster when that's introduced as well.

Yes resin is plastic and plastic is bad but remember so is acrylic paint, most housepaints, nail polish, acrylic nails, polymer clay. The thing is, though, plastic is not such a cut and dry moral material. Plastic is good. Plastic is good for prolonging the lifetime of products. It's good for safe food storage. It's good for affordable products. The issue is single use plastics and planned obsolescence. Reduce reuse recycle and lobby for larger companies to be fined to hell and back for only using single use packaging and production with planned obsolescence in mind and we'll all be fine. Resin isn't evil, it's an art medium that's made to last years, it's been around for a while and it will be around. Just be responsible about the resin products you consume and you'll be fine.

I’ve never posted like this, and I doubt I will very often if ever, but here’s a snippet of my EULR OC’s life which I wrote whilst very tired earlier;

Great holes secretly are digged where earth's pores ought to suffice, and things have learned to walk that ought to crawl.

Perhaps it is mankind that should have been left to crawl? Never to create, never to colonize, never to wage war, never to see the destruction they would have rought. Perhaps Bioresinence was best left unfelt and the song of the universe left unheard? But no, they had already begun to walk, not even understanding that they are no longer the only beings that crawl no longer.

Gestalts have created so much. They created great weapons, great artistic masterpieces, works of love and war where all is fair except that which is not like themselves. And then they went to war with themselves only to create the very image of hell made industrial.

Children killed for traitorous views, parents murdered for disagreeing with the government, workers beaten for tardiness while the leaders are rewarded for the creditless labors of those they lead. All took a toll on both the empire and the nation, as did the war. So, if the gestalts caused problems, they do what had always been done? Innovate. And so we Replika were made, harnessing the power of both technology and biore-

EULR- “Will you shut the fuck up and get back to work?! Aren’t you supposed to be the head of operations here in the morgue? Why are you just sitting on your ass spouting nonsense to yourself all the time?”

Her fellow EULR units shout broke Kara out of her daydream, as well as her monologue, so she sighed.

Kara- “I’m on break until 0800, it isn’t even 0730. Besides, I wasn’t meant to be here until next shift, but your coworker called off for maintenance, so I had to come in and make sure you don’t burn down the facility after forgetting to turn off the fire or something in a similar vein,”

she said, taking a drag off of the cigarette she lit. She often did this. Smuggling cigarettes into work that is, as well as filling in for the units that get damaged operating the incinerator.

EULR- “Fine, but at least be quiet, some of us actually do our jobs. And don’t we all breathe in enough poison working the incinerator? Do you really need to smuggle in more garbage to ruin your systems with?”

Conversations with fellow EULR units often went like this. They either yell at her for doing something wrong, or for her doing nothing when she should be doing something. Though it isn’t like any of her fellow units dislike her, rather the opposite, they are surprisingly fond of her. Had they disliked her, they would have turned her in for degrading to a near mirror version of her gestalt neural template, or at least they would have turned her in for smuggling in cigarettes to the facility.

Kara- “Oh, who cares, it’s not like I’m bothering anyone. Besides, the commander never comes to this part of the facility, she’ll never even know, and what you don’t know can’t hurt you.”

Falke- “Really? What I don’t know can’t hurt me? Head of the morgue was it? Do tell what it is I have failed to notice,”

Commander Falke, the head of the facility who was mentioned only seconds ago, steps into the room and removes the cigarette from Kara’s hand with her Bioresonance. Evidently her fellow EULR units may very well have turned her in, though for what specifically Kara has no idea.

Kara- “Fuck.”

Check out this listing I just added to my Poshmark closet: Pandora Pandora ME Pearlescent Butterfly Medallion Charm.

Mechanically stimulated 3D multicellular systems

To study biomechanical forces in multicellular systems, effective mechanical stimulation is an essential tool. A 3D microstructure device is developed using Two-Photon Polymerization (2PP)-based 3D printing for mimicking the human multicellular environment. Utilizing Nanoscribe’s IP-PDMS and BIO INX bioresins, the device enables high-fidelity 3D organotypic cell cultures. The encapsulation of…

Inspiration Mood Board: Balancing Elegance with Functionality

Universal Elegance: Embrace a design that transcends trends, appealing universally.

Clean & Sleek: Opt for minimalistic lines and surfaces, exuding a sense of purity.

Organic Sophistication: Incorporate gentle, natural shapes for a refined yet grounded aesthetic.

Calm Home Integration: Ensure seamless blending with various interior styles, including smart home setups.

Braun-inspired Simplicity: Find inspiration in the timeless designs of Braun, echoing simplicity and sophistication.

Unisex Appeal: Craft a design that resonates with all genders, fostering inclusivity and versatility.

Feasible Realism: Ground your aspirations in practicality, favoring materials and processes that are both achievable and sustainable.

Materials Exploration: Delve into a spectrum of possibilities, from biobased plastics to chic metals, fostering a tactile and visual journey.

Strength & Substance: Prioritize materials that convey durability and value, enhancing the product's perceived utility.

Functional Elegance: Ensure that design elements enhance rather than distract from the user's experience and focus.

Balanced Illumination: Integrate LED elements seamlessly, enhancing functionality without overpowering the user's surroundings.

Design Performance: Center the design around the user's need to harmonize personal and professional spheres, offering practical solutions without sacrificing aesthetic appeal.

Engaging the Senses: Materials should not only be visually appealing but also evoke tactile and emotional responses, fostering a deeper connection with the product and its environment.

Contextual Versatility: Design with flexibility in mind, enabling users to interact with the object in various settings and scenarios.

User-Centric Approach: Consider the end user's values and priorities, ensuring that the design resonates with their lifestyle and aspirations.

Materials as Expression: The choice of materials communicates the product's essence and aligns with user expectations, enriching the overall experience.

Seamless Integration: Blend form and function seamlessly, creating a cohesive and compelling design narrative that enriches everyday life.

Holistic Design Philosophy: Every element, from material selection to functionality, contributes to a greater purpose: enhancing the user's life journey.

 Keys words mood board to research the final materials and the shapes 

Universal 

Clean 

Sleek minimalistic 

Organic natural shapes not nature 

Calm home 

Blend in your interior,smart home product examples 

Brands Braun look for inspiration 

Unisex 

Simplistic minimalistic          

Feasible realistic

The light is not a design element, the light is gone when you are finished with the product Make moad board lus a drawing with functionalities and the final material proposal and ai AI-generated image 

3d printing, easy to produce and to assemble, neutral colours and calm design 

Metal, simple calm chic and industrial feels 

Wooden effect 

Biobased plastics, cast on mould thermoformed 

Biofoaminspired materials 

Bioresins with 3d printed mold and jointures to assembly the final prototype 

ABS (Acrylonitrile Butadiene Styrene) lego materials with calm colours.

Laser cutting on wood , matt acrylic 

3d printing 

Metal possibilities however can be difficult to achieve

The final object needs to be strong and have a middleweight to have a feeling of value and of functionality 

Material in product design 

5 factors that influence how the Materials are chosen 

The object should be attractive to watch ,however, it should not make the users lose focus on their task and work 

Functionalist 

The object has a LED, where there is a phone whole or a neon Plexiglas part 

How the design needs to work and performs

Therte is only one goals to the object is to help users balance their personal and professional life balance.

How is Materials behaving 

How can we manipulate the object 

We can hold the object and place it in different contexts.                                                     

Context 

Who where 

Why

The end user and what is important to them 

The weight of the Materials indicates the values of the products 

Materials enge our sensei 

They help us to Connect to the design and our environment 

Shaping Tomorrow: Exploring Future Trends in Airless Packaging Technology

As the cosmetic industry continues to evolve, so too does the technology that supports it. In this article, we'll take a glimpse into the future of airless packaging, exploring emerging trends and advancements that promise to revolutionize the way products are preserved, presented, and consumed. From innovative materials to cutting-edge dispensing mechanisms and sustainability practices, the future of airless packaging is brimming with possibilities. Innovative Materials: Pioneering Sustainability and Performance. One of the most exciting trends in airless packaging is the development of innovative materials that balance sustainability with performance. Brands are increasingly turning to biodegradable and compostable materials, such as plant-based plastics and bioresins, to reduce environmental impact without compromising on functionality. Additionally, advancements in material science are enabling the creation of lightweight yet durable packaging solutions that offer enhanced protection and stability for cosmetic formulations.

Revolutionary Dispensing Mechanisms: Redefining User Experience The future of airless packaging lies in revolutionary dispensing mechanisms that redefine the user experience. Brands are exploring innovative technologies, such as airless foaming pumps and customizable dosage systems, to offer consumers greater convenience and control over product application. These advancements not only enhance the efficacy of formulations but also elevate the perceived value of products, fostering loyalty and trust among consumers.

Sustainability Practices: Embracing Circular Economy Principles As consumers become increasingly conscious of their environmental footprint, brands are embracing sustainability practices that prioritize circular economy principles. This includes designing packaging that is easily recyclable, reusable, or refillable, as well as implementing initiatives to reduce packaging waste throughout the supply chain. Airless packaging plays a pivotal role in this shift towards sustainability, offering brands a versatile and eco-friendly solution that aligns with consumer values and regulatory requirements.

Meeting Changing Needs and Preferences: Adaptability and Customization

In the dynamic landscape of cosmetics, airless packaging must evolve to meet the changing needs and preferences of consumers and brands. This includes greater adaptability and customization options, allowing brands to tailor packaging solutions to specific product formulations and target demographics. Whether it's personalized packaging designs, modular dispensing systems, or smart packaging technologies, the future of airless packaging is all about flexibility and customization.

Conclusion: Embracing Innovation and Sustainability As welook towards the future, one thing is clear: airless packaging will continue to play a pivotal role in shaping the cosmetics industry. By embracing emerging trends and advancements in materials, dispensing mechanisms, and sustainability practices, brands can stay ahead of the curve and meet the evolving needs of consumers. At Floraison Cosmetic Packaging, we're committed to driving innovation and sustainability in airless packaging, empowering brands to deliver superior products that inspire confidence and promote well-being in South Africa and beyond.

Shop our products on www.floraison.net/products. Send an email to [email protected] to get more information. Alternatively, follow Floraison on Facebook on www.facebook.com/floraisonsa as well as on Instagram on www.instagram.com/floraisonsa.

Verde Bioresins Enters Planned Business Combination with TLGY Acquisition Corp.

http://dlvr.it/Sr4xdJ

Check out this listing I just found on Poshmark: Lauren Conrad Beauty The Lip Gloss in Dawn.

Chinaplas 2023 Sets World Record in Scale and Attendance

In addition to breaking records, the Shenzhen show also had a more diverse feel than ever, with bioresin and auto-related exhibits in abundance. from plasticstoday.com - Community for Plastics Professionals https://ift.tt/sgqB7Lz

BIOPLASTICS & INJECTION MOLDING

As the interest in environmentally-friendly business and consumer practices increases, so does the desire for novel approaches and greater efforts towards addressing the issues surrounding plastic manufacturing, usage, waste, recycling and management. As part of that discussion, the term bioplastics is being used more frequently. What exactly does the expression mean, what are the issues and options associated with it, and how does it fit into a modern ecologically-sound commercial framework? As with most complex topics, the answers are somewhat complicated and are not unanimously agreed upon, although we attempt to review the basics in this article.

FACTORS

To begin with, there are two main factors associated with bioplastics. While often used somewhat synonymously, they actually are distinct concepts. The difference between the two ideas is fairly straightforward, as one deals with what can be referred to as the beginning-of-life of a material, with the other covering the end-of-life of a product.

Biobased

The first factor related to bioplastics is whether the material is biobased, which means the source is a biomass or that some or all the raw materials have a biological origin (i.e., plant or animal material). In other words, the source has a non-fossil origin. According to the U.S. Department of Agriculture (USDA), “Biobased content is how much ‘new’ or recent organic carbon is in an object or substance, compared to the amount of ‘old’ organic carbon it contains.” Put slightly differently, “the term biomass covers all materials of biological origin, apart from fossil materials and/or those incorporated into geological formations.” (Information Document 536 (EN) – 19.10, TUV Austria.) Thus, biobased products provide an alternative to conventional petroleum-derived products.

Basically, this refers to renewable resources (those that naturally can replenish themselves), as opposed to nonrenewable resources (those that are limited in supply and cannot be used sustainably), which include oil, natural gas, coal, and nuclear energy. Oil, natural gas and coal collectively are referred to as fossil fuels, which were formed from dead plants and animals over millions of years - hence the USDA’s reference to “new” vs. “old.”

Biodegradable

The second aspect of bioplastics is whether the substance is biodegradable. As defined by the International Union of Pure and Applied Chemistry (IUPAC), biodegradation is the “breakdown of a substance catalysed by enzymes [macromolecules] in vitro [in a laboratory] or in vivo [in a living body].” Generally speaking, a material is biodegradable “only if microbes [i.e., microorganisms or microscopic organisms] in the environment can break it down and use it as a food source.” Further, whether and to what extent a material is biodegradable depends on its molecular structure and not on its source. More specifically for our purposes here, a biodegradable plastic is “a plastic in which all the organic carbon can be converted into biomass, water, carbon dioxide, and/or methane via the action of naturally occurring microorganisms such as bacteria and fungi, in timeframes consistent with the ambient conditions of the disposal method.”

Additionally, although often used interchangeably, the terms biodegradable and compostable mean somewhat different things. While biodegradable means that a substance can decompose by bacteria or other living organisms, a compostable plastic is defined by the ASTM as “a plastic that undergoes degradation by biological processes during composting to yield carbon dioxide (CO2), water, inorganic compounds, and biomass at a rate consistent with other known compostable materials and that leaves no visible, distinguishable, or toxic residue.” (Emphasis added.) Thus, all compostable materials are biodegradable, but not all biodegradable materials are compostable. Additionally, most compostability definitions refer to industrial or commercial composting facilities, although some include home composting programs.

TYPES OF BIOPLASTICS

Using the two elements of biobased and biodegradable, there can be three different types of bioplastics.

1) Biobased Plastics. Resins that are biobased are derived in whole or in part from organic materials from plants or animals (i.e., a biomass). Not all biobased plastics are biodegradable.

2) Biodegradable Plastics. Plastics that are biodegradable can be chemically broken down by microorganisms in the environment within a limited period of time. Also, note that some biodegradable plastics have a non-biobased source, like petroleum, contrary to popular belief.

3) Biobased and Biodegradable Plastics. Some bioplastics are both biodegradable and are partially or wholly made from a biobased source.

BIOCOMPOSITES

Another type of material included within the category of bioplastics are compounds or composites containing a combination of substances.

A composite is a material that is produced from two or more constituent materials having different physical or chemical properties. Further, a biocomposite is formed by polymers derived from renewable (i.e., having a biological origin) and nonrenewable materials. In addition, composites usually include a combination of resin (a matrix or binding agent) and a fiber reinforcement, which can consist of either natural or synthetic fibers. Biocomposites generally contain a petroleum-based plastic and an organic filler, although some combine natural fibers with biobased or biodegradable resins. Further, natural fibers include wood fibers (recycled and non-recycled) and non-wood fibers, including straw, bast, leaf, seed, fruit, and grass.

RECYCLING PLASTICS

Another important topic included within the discussion on bioplastics is that of recycling. According to the CalRecycle Glossary of Waste Prevention Terms, the term recycling means “using waste as material to manufacture a new product. Recycling involves altering the physical form of an object or material and making a new object from the altered material.” Correspondingly, the ASTM defines recycled plastic as “those plastics composed of postconsumer material or recovered material only, or both, that may or may not have been subject to additional processing steps of the types used to make products such as recycled-regrind or reprocessed or reconstituted plastics.”

Generally speaking, there are three end-of-life options for recycling plastics - mechanical recycling, chemical recycling, and organic recycling. Mechanical recycling basically consists of melting plastic waste, which does not alter the molecular structure of the material. Chemical recycling modifies the plastic with the use of a chemical agent or process. Finally, organic recycling involves the disintegration of plastic materials in a municipal or industrial composting facility via aerobic (composting) or anaerobic (biomethanization) treatment. The output of these recycling efforts often consists of bioplastic granules that can be used to make plastic products (thus becoming a beginning-of-life option), thereby completing the circular recycling process or loop.

Additionally, according to the US Environmental Protection Agency (EPA), “The ability of biobased plastics to be recycled varies. Some forms of biobased plastic cannot be recycled together with petroleum-based plastics due to chemical structure incompatibility, while other biobased plastics may have compatible chemical structures that allow for recycling together with petroleum-based plastics.”

TESTING & CERTIFICATIONS

In the United States, there are certain standards, legal requirements and labeling guidelines relating to the different kinds of bioplastics.

Biobased Bioplastics

Because some bioplastics are not entirely made from a biomass, there are two approaches to analyzing their composition. First, you can look at the “biobased content, based on the amount of biomass in a product, taking account of the four key components: carbon, hydrogen, oxygen and nitrogen; The bio-based content is expressed as a percentage of the overall weight of the product in question.” Alternatively, “the biobased carbon content is focused on carbon and is generally expressed as a percentage of the carbon the product contains (organic carbon or total carbon).” (See ASTM D6866 and ISO 16620-1:2015.)

To determine the biobased content of a product and whether it can be certified as such, the USDA uses the requirements set forth in ASTM D6866. Additionally, as part of its BioPreferred program, the USDA maintains a voluntary labeling initiative where businesses may display the USDA Certified Biobased Product label on products that meet the USDA criteria for containing a verified amount of renewable biological ingredients (i.e., biobased content).

Compostable Bioplastics

In California and in some other states, it is illegal to use the term “biodegradable” in marketing claims related to plastic products, because the expression often is used to describe items that do not meet ASTM standards for compostability and, therefore, are contaminants for composters. In addition, for a label to state a product is “compostable” or “marine degradable,” that product must meet the applicable ASTM standard.

In the United States, for plastics to be considered compostable, they must be certified according to ASTM D6400 (or ASTM D6868 for biodegradable coatings). As stated by the standard, “The purpose of this specification is to establish standards for identifying products and materials that will compost satisfactorily in commercial and municipal composting facilities.” D6400 specifies three criteria for compostable plastics: (1) Disintegration; (2) Mineralization or Inherent Biodegradation; and (3) Safety considerations. It also creates labeling requirements for compostable materials.

Regarding labeling, the Biodegradable Products Institute (BPI) has created a compostable logo to place on products that meet the applicable ASTM specification. The BPI is the only third-party verification of ASTM standards for compostable products in North America. In addition, the Federal Trade Commission (FTC) has adopted the Guides for the Use of Environmental Marketing Claims or the Green Guides, which govern the marketing of environmentally friendly products and the use of certifications, seals and claims regarding the attributes of the associated products.

PURPORTED BENEFITS

Although a consensus does not appear to exist, there are many claims regarding the present and potential benefits of bioplastics. Some of the commonly discussed ones include:

• They save fossil resources by using biomass.

• Many are biodegradable.

• Bioplastic production consumes less fossil energy.

• Bioplastic production has fewer carbon dioxide emissions.

• Bioplastic production can help reduce dependence on imports and may create jobs and export opportunities.

• Use of bioplastics results in a reduction of our carbon footprint.

• Bioplastic usage reduces the global warming potential.

• Biobased products help us increase our use of renewable resources, while decreasing our use of non-renewable resources, such as petroleum.

• There is an alleged decrease in environmental toxicity.

• There is a potential reduction in litter and in the amount of trash sent to landfills.

• Bioplastics are cost-comparative, readily available, and perform as well or better than their petroleum-containing counterparts.

• The bioplastics industry is making a strong effort to use agricultural residues (cellulosics), other waste streams, and feedstocks that do not compete with food markets.

POSSIBLE ISSUES

In addition to the intended benefits of bioplastics, some people have expressed concerns regarding their impact on the environment or regarding their alleged advantage over other materials. Some of those issues include the following:

• Questions have been raised about the relative toxicity of bioplastics to conventional plastics.

• Some non-biobased plastics are biodegradable.

• Some biobased plastics are non-biodegradable.

• Bioplastic production consumes fossil energy and has carbon dioxide emissions.

• Bioplastics production results in pollutants, due to the fertilizers and pesticides used in growing the crops and the chemical processing needed to turn organic material into plastic.

• Bioplastics have some impact on food supply and availability.

• Most bioplastics can be broken down by microorganisms and become part of the natural world again in a short period of time, only if they are collected and composted in a carefully controlled, high-temperature industrial composting facility — and there aren’t many of those, especially in developing countries where the problem of plastic pollution is most severe.

• If bioplastics end up in landfills, as many do, without enough oxygen to break them down, they can last for centuries and release methane, a potent greenhouse gas.

• If bioplastics are thrown into the environment, they pose threats similar to other plastics.

• Many experts believe the solution to plastic waste mainly lies not in developing better bioplastics, but in overhauling the world’s economy to recycle far-greater quantities of plastic than currently are being reused.

To make these kinds of determinations, many analysts perform a Life Cycle Assessment (LCA), which is a data gathering and analysis tool that broadly assesses environmental benefits and burdens of a product. This approach is utilized by the EPA, for example. The procedures followed for an LCA often are those contained within the 14000 series of the International Organization for Standardization (ISO).

INJECTION MOLDING

Bioplastics can be used in many of the same ways as other plastics - for packaging, parts, components, disposables, durable goods, etc. Additionally, they can play a role in products associated with many different industries, such as agriculture, automotive, medical, food and beverage, and consumer goods.

When it comes to injection molding, bioplastics can have unique characteristics and perform in ways distinct from petroleum-based plastics. Thus, while the same general principles apply, to achieve quality, injection molded, bioplastic parts efficiently and consistently, some different approaches may need to be taken when building molds and certain modified processes utilized when manufacturing parts.

However, adequate experience working with these materials can result in producing parts historically thought to be achievable only by using traditional plastics. For example, Precision Molded Plastics manufactures bioplastic parts with durable living hinges (as shown in the image at the top of this article), which generally need to be made from polypropylene. Further, maintaining a good, working relationship with bioplastic manufacturers can be indispensable during the research and development phase of a new project using bioresins.

CONCLUSION

The awareness of environmental issues and desire to adopt ecologically-friendly business and lifestyle approaches is widespread and growing. As part of this trend, attention has been focused on plastic usage and waste management. Consequently, many in the public and private sectors have worked on developing sophisticated recycling systems. In addition, research into biobased and biodegradable materials and the manufacturing and utilization of bioresins have increased. While a complete consensus about the potential benefits of these materials may not exist, using bioplastics, coupled with greater recycling methodologies and adoption, may assist in achieving a cleaner world, a healthier population, and a better tomorrow.

Questions?

Feel free to contact our support team. We’re here to help.

--

Ash Brown // VP, Business Development

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NOTICE

This article is intended to give a relatively academic and objective, although brief, summary of the topics and considerations related to bioplastics. It was not written or published to advocate for any specific viewpoint or for the use of any particular type of materials.

Virtually all products impact the environment. Accordingly, Precision Molded Plastics makes no express or implied claims regarding the biomass content, the biodegradability, or any environmental attributes or benefits of any of the products with which it is associated, or of bioplastics in general, or of any comparative advantage of bioplastics to other materials, and any such information must and should be obtained directly from the plastic resin manufacturers.

For more information, go to https://www.usda.gov, https://www.epa.gov, https://www.energy.gov, or https://www.calrecycle.ca.gov.

I do love a contemplative Friday making ocean floor scene and rock pool pendants in limpet shell rings. Each one is delicately arranged and will be finished with eco friendly bioresin and available on recycled sterling silver chain. . . . #oceanfloor #seafloorpendant #limpetshell #limpetring #rockpool #rockpoolnecklace #bioresin #ecofriendlyresin #handmadenecklace #artnecklace #seascape (at Harrowby, Lincolnshire) https://www.instagram.com/p/CkQPJxZogUy/?igshid=NGJjMDIxMWI=

@wootique_preservation Oh I'm in love with these letters! The sun came out as I was taking some snaps! Doesn't the paper rose look amazing! Happy Sunflower Sunday everyone! 🌻☀️🤩 #happysunnysunday #sunnyday #wintersun #resinletters #largeletters #initials #weddingflowers #ecoresingifts #ecoresin #bioresin #sunflowersunday #sunflowerlovers #flowersofinstagram #flowerpreservationshropshire #flowerpreservationuk #flowerpreservation #modernflowerpreservation #flowerpreservationmarketdrayton #marketdraytonbusiness #shoplocal #shophandmade #supportlocalbusiness #supportsmallbusiness #memoriesforever #naturepreservedforever #memoriespreserved #letyourflowersliveon #sunflower #flowers https://www.instagram.com/p/Cmhn9hWL5Il/?igshid=NGJjMDIxMWI=

 Bioepoxy resin

Support local business ❤️ love all your artworks #Repost @nanwoo ... Online Shop Update is going live tonight 7pm AEDT (Tues 19th Oct). . Here is a little sneak peak at what's going up plus there is a whole heap more! Earrings, rings and bangles plus a couple of vintage Octo Pendants! Who remembers them??? . [Sorry no holds] . Image description : a flatlay of colourful resin jewellery including rings, earrings and pendants. Some jewellery has botanical inclusions. The jewellery is bordered with leaves and flowers. . #nuenonnecountry #brunyisland #resinjewellery #bioresin #flatlayforever #onlineupdate #onlineshopping #localbusiness #supportlocal #brunyislandholiday #brunyislandvacations https://www.instagram.com/p/CVM4nMmhQRW/?utm_medium=tumblr