Investing in Biopolymers

Investing in Biopolymers

Last month Eastman Chemical Company (EMN:  NYSE) announced an expansion of its urethane extrusion line at one of its specialty chemical plants. This one located near Martinsville, Virginia makes paint protection films and window films.  Urethane is perfect to protect surfaces in a home or business.  It is not brittle like plastic, but has excellent tolerance for grease and oils.  When exposed to the elements it does not rot or degrade over time like rubber.

Shareholders likely cheered the development in Virginia for potential addition to market share.  Eastman grabbed $9.6 billion in sales from the specialty chemicals market in 2017, earning $1.4 billion in net income or $9.47 in earnings per share. Anyone who has waded through even just a few of posts here, knows I hold a special interest in companies that generate cash.  In 2017, Eastman turned a whopping 17.3% of sales into operating cash flow.  With so much cash sloshing around Eastman is able to offer a tasty dividend of $2.24 per share, which at the current price provides a yield of 2.1%.

As appealing as EMN shares might seem, Eastman’s urethane and most of its other products are made from fossil fuels.  Environmentally conscientious investors may balk at dividends tainted by a supply chain that contributes to climate change. Plastics that come out the other end of that chain offer durability but are not readily biodegradable because of resistance to microbial action.  They simply keep accumulating in the environment.

Discerning investors need not be frustrated in finding redeeming investments in specialty chemicals.  There are biodegradable polymers made from both petroleum and renewable resources such as corn starch, cassava roots or sugarcane. Polylactides or PLAs are one an example. The most common way to make product PLAs is ring-opening polymerization of lactide with a metal catalyst in a solution. Polylactides materials can be extruded with a three-dimensional printer or an injection molding machine.  Consumers will be most familiar with PLAs as food containers, but the material is so versatile it can also be used for everything from upholstery to medical implants.

Tea bags made from polyacitate By Elke Wetzig (elya) [GFDL or CC BY-SA 3.0], from Wikimedia Commons
PRODUCERS OF POLYLACTIDE (PLA)
Trade Name Company Country Symbol
NatureWorks Cargill Dow USA Private
Galacid Galactic Belgium Private
Lacea Mitsui Chemicals Japan 4182:  Tokyo
Lacty Shimadzu Japan 7701:  Tokyo
Heplon Golden Technologies USA Private
CPLA DIC Global Japan 4631: Tokyo
Eco plastic Toyota Corporation Japan TM:  NYSE
Treofan Treofan Holdings GmbH Netherlands Private
PDLA Corbion NV (formerly Purac) Netherlands Private
Ecoloju Mitsubishi Plastics, Inc. Japan 8058:  Tokyo
Biomer Biomer Germany Private

Nature has its own ring-opening polymerization process that result in polymers.  It is a part of the regular growth cycle of living organisms.  Starch and cellulose are the two most common biopolymers from nature’s ‘specialty chemical factory,’ but lipids are another resource.  From a commercial standpoint, wheat gluten is a popular resource because it is available in high quantity at low cost.  Most importantly gluten is fully biodegradable and the products that are produced are non-toxic.

Chitin is the second most abundant natural biopolymer.  It is found in the shells of crabs, shrimp, crawfish and insects.  With a rigid and compact crystalline structure, it is insoluble in water and alkaline media.  Unfortunately, chitin and its derivative chitosan are limited because of insolubility in most solvents.  Nonetheless, it has found utility in cosmetics and in wound treatment.

The word in biopolymers is starch.  It is a low-cost polyssacharide and available with abundance at low cost.  Starch is mainly extracted from potatoes, corn, wheat and rice.  It is interesting that there are few if any U.S. companies developing ‘starch polyesters.’  Perhaps this is because the chemical industry really began formation in the U.S., providing the seeds to an entrenched supply chain that does change speed or direction quickly.  Among the European competitors there is considerable scrambling for position in the starch polymer market.  Italy-based Novamont was in a legal dust up with Britain’s Biotec a few years back, but the two finally agreed to put their patent infringement accusations aside.

COMMERCIAL ‘STARCH’ POLYESTERS
Trade Name Company Country Symbol
Mater-Bi, Biocol Novamont, S.p.A. Italy Private
Solanyl Rodenburg Biopolymers, B.V. Netherlands Private
Ecofram National Starch (Akzo Nobel) Netherlands AKZA:  AMS
Vegeplast Vegemat France Private
Biolice Limagrain France Public, Non-quoted
Biotech Biotech, s.r.o. Germany Private
Bioplast Biotec England Private
Plantic Plantic Technologies Ltd. Australia Private

Investors with an interest in getting involved with biopolymers, the vehicle will need to be at the private level.  Only Akzo Nobel has a trading stock that can be purchased through the Amsterdam Exchange.  It seems more likely than not that the biochemical companies will capture market share as the world turns to sustainable materials.  The next step in the somewhat fragmented starch group will likely be a wave of mergers or acquisitions.  The result could be deeper product lines and scale in production that provide the foundation for public trading company stock.

Debra Fiakas is the Managing Director of Crystal Equity Research, an alternative research resource on small capitalization companies in selected industries.

Neither the author of the Small Cap Strategist web log, Crystal Equity Research nor its affiliates have a beneficial interest in the companies mentioned herein.

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