This publication has been discontinued on July 19, 2011.
Abstract
Environmental Concerns and Soaring Oil Prices Create Renewed Interest in
Bioplastics
While, in the past, plastics from alternate sources were significantly more
expensive as well as less efficient than those derived using petroleum
technology, higher oil prices have rendered these alternatives cheaper in
comparison. Moreover, mounting environmental concerns and legislative
incentives, particularly in the European Union (EU), are stimulating keen
interest in the adoption of biodegradable plastics. This is in turn spurring
research to improve bioplastic technology, and developments in plant breeding
and processing are expected to further narrow the cost differential between
bioplastics and synthetic ones.
This Frost & Sullivan research service provides a technical insight into
emerging technologies and trends in bioplastics. It covers more than 80 trends
in the areas of bioplastics materials, technology, and applications, among
others. This research service also includes an 80 company, global bioplastics
manufacturers summary and a detailed source guide in plastics-related end-user
areas, which are further augmented by lists of key industry contacts.
World's First Polylactic Acid (PLA) BlowMolded Spring Water Bottles Usher in a
New Era in Consumer Packaging
With legislative and regulatory instruments driving the uptake of bioplastics,
there have been numerous innovations in the field of bioplastic technology
across the world. Highly touted and showcased at a White House conference on
cooperative conservation in June 2005, BIOTA brands of America Inc. (US)
demonstrated the life cycle advantages of the world's first spring water
bottles to be molded using PLA from NatureWorks LLC (US). This unique bottle
has been approved and certified as commercially compostable by the
Biodegradable Products Institute and testing demonstrated that BIOTA water
bottles are likely to completely degrade within 75 to 80 days in a commercial
composting situation.
Likewise, driven by European and Japanese recycling guidelines, Sanyo Mavic
Media Co Ltd. (Japan), a subsidiary of Sanyo Electric Co, Ltd, introduced the
world's first biodegradable compact disc based on PLA. "Developed jointly by
Mitsui Chemicals Inc. (Japan) and Sanyo Mavic Media, the new disks that are
marketed under the name MildDisc are virtually indistinguishable from
conventional ones made of polycarbonate, with no trade-off in sound or picture
quality," says Dr. Don Rosato, senior research analyst, of this research
service. "Other notable developments in this field include Novamont's
design-enhanced compostable corrugated packaging, John Deere's development of
soy bean-based polyurethane for agricultural equipment panels, and Inion's
novel bioplastic blends for orthopaedic medical implants, to name a few."
Bioplastic Advancements set to Expand Applications
Presently, bioplastics are mostly used in low-value disposables such as food
service items, bags, and packages. Although these are expected to continue to
be their main markets, evolutions in bioplastic performance and processability
are being targeted at more demanding end-uses. Key areas of development
include polymers produced in situ by bacteria, which are believed to
significantly improve biodegradability as well as barrier properties,
hydrolytic stability, sealability, printability, and compatibility with other
resins.
"While bioplastic technology is continuing to see tremendous progress, the new
generation of biopolymers do not offer much in the way of price relief as they
are more expensive by an average of 70-80 percent when compared to the
commodity resins, such as low-density polyethylene, which they replace," says
Dr. Rosato. "It is expected to be several years before advances in formulation
technology and market growth create economies that reduce bioplastics prices
to the level of packaging resins such as polyethylene terephthalate."
Table of Contents
- 1. Executive Summary
- 1. Overview
- 1. Overview
- 2. Global Technology Highlights (North America; Europe; Asia)
- 2. Scope and Methodology
- 1. Scope
- 2. Methodology
- 3. Bioplastics Webwatch Directory
- 2. Bioplastics Introduction (North America; Europe; Asia)
- 1. Biopolymers
- 1. Overview
- 2. Development of Bioplastics
- 2. Life Cycle
- 1. Life Cycle Analysis
- 2. Life Cycle Design
- 3. Legislation
- 1. European Union Packaging and Packaging Waste Directive
- 2. Amended German Packaging Ordinance Encourages Biopackaging
- 3. Japan's Container and Wrapping Recycling Law
- 4. Green Procurement Law
- 5. US Government Support
- 6. Nongovernmental Organizations
- 4. Degradability Certification
- 1. Introduction
- 2. Biodegradable Products Institute
- 3. DIN Certco
- 4. AVI Certest
- 5. GreenPla Designation in Japan
- 3. Bioplastics Technology and Applications Viewpoint (North America;
Europe; Asia)
- 1. Bioplastics Development Snapshot
- 1. Bioplastics Applications Continue Growth Trajectory
- 2. Bioplastics Materials Evolving
- 2. Compostable Packaging Applications
- 1. Dissolving Thermoformed Chocolate Tray
- 2. Wave by Mater-Bi
- 3. Corrosion Protecting Biodegradable Film
- 3. Compostable Food Service
- 1. Total Bioplastic Food Service Package
- 2. Biodegradable Cutlery for Defense Logistics
- 4. Textile-Based Bioproducts
- 1. A New Sustainable Bioplastic
- 2. Corn-Derived Sorona Textile
- 5. Consumer Products
- 1. Cornstarch-Based DVD
- 2. NEC's Biodegradable Computer Case
- 6. Automotive Applications
- 1. Bio-Based Materials in Vehicles - DamilerChrysler
- 2. Opel and CitroE Reinforced Flax Applications
- 7. Medical Applications
- 1. Introduction
- 2. PLA and PHB-Based Immunological Test Systems
- 3. Bioplastics for Medical Gloves
- 4. Bioplastics Materials Technology Adoption (North America; Europe; Asia)
- 1. Biodegradable and Non Petroleum-Based Polymers
- 1. Environmental Impact Reducing Plastics
- 2. Petroleum Dependence Reducing Plastics
- 2. Genetically Modified Biomolecules
- 1. Pathway Engineering of Microorganisms
- 2. Pathway Engineering Steps to Implementation
- 3. Polyhydroxy-Alkanoates (PHA)
- 1. Introduction
- 2. PHAs through Metabolic Pathways
- 3. PHAs through Nonfood Crops
- 4. Polylactides (PLAs)
- 1. Introduction
- 2. NatureWorks PLA
- 5. Starch-Derived Plastics
- 1. Introduction
- 2. Starch Foamed Bioplastic
- 3. Bioplastic Starch/Polymer Blends
- 6. Other Biobase-Derived Polymers
- 1. Sorona Polyester
- 2. Soyol; Bio-Based Polyurethane Component
- 7. Biopolymer Blends; Alloys; and Copolymers
- 1. PLA Eastar Bio Blends
- 2. PHB/PHBV Bioblends
- 8. Bio-Based Compounded and Filled Products
- 1. High Fiber Filled Compounds
- 2. Natural Fiber Reinforcements
- 3. Flame Resistant PLA Resin
- 9. Renewable Resource Stock Shapes
- 1. Polylactic Acid; New Generic Fiber
- 2. Bio-Based Soy Plastic Powder Coating
- 5. Bioplastics Technology and Market Assessment (North America; Europe;
Asia)
- 1. Bioplastics Strategy Introduction
- 1. Drivers for Bioplastics
- 2. Business Landscape for Bioplastics
- 3. Major Bioplastics Developers
- 2. Major Bioplastics Company Strategies
- 1. Metabolix's Microbial Biofactories
- 2. NatureWorks Targets PLA Applications
- 3. Bioplastics Fabricated Product Strategies
- 1. Biodegradable Orthopaedic Fixation Implants
- 2. Vertically Integrated Soyol Producer
- 3. High Growth Bio-Based Metal Protective Packaging
- 6. Plastics Company Sourceguide and Glossary
- 1. Plastics Company Sourceguide (North America; Europe; Asia)
- 1. Plastics Company Sourceguide (North America; Europe; Asia)
- 2. Bioplastics Glossary
- 7. Frost & Sullivan Science and Technology Awards
- 1. Technology Innovation Award
- 1. Award Description
- 2. Award Recipient
- 2. Technology Leadership Award
- 1. Award Description
- 2. Award Recipient
- 3. Excellence in Technology Award
- 1. Award Description
- 2. Award Recipient
- 8. Critical Reference Tables
- 1. Decision Support Database Tables
- 1. Car Production Worldwide (1999-2006)
- 2. Bus Production Worldwide (1999-2006)
- 3. Total Vehicle Production Worldwide (1996-2004)
