Incumbents in the Transition Towards the Bioeconomy: The Role of Dynamic Capabilities and Innovation Strategies
Abstract
:1. Introduction
2. Setting the Theoretical Framework
2.1. The Multi-Level Perspective: A Snapshot of Incumbents in Transition
2.2. Dynamic Capabilities for Sustainability
2.3. MLP–DCs Analytical Framework
3. The Norwegian Meat-Processing Sector and the Case Study
4. Data and Methods
5. Exploring the Case through the Lenses of the MLP–DCs Analytical Framework
5.1. Unpacking the MLP Levels
5.1.1. The Socio-Technical Landscape
5.1.2. The Socio-Technical Regime
5.1.3. The Technological Niche
5.2. Untangling the Incumbent’s Dynamic Capabilities Creation Processes
5.2.1. Sensing Process—The Capability of Learning
5.2.2. Seizing Process—The Capability of Financing
5.2.3. Reconfiguring Process—The Capability of Organizational Restructuring
5.3. Discussion
5.3.1. Incumbent’s Innovation Strategies and Dynamic Capabilities
5.3.2. Leveraging Competitive Advantage
6. Conclusions
Funding
Acknowledgments
Conflicts of Interest
Appendix A
Date | Organization | Position | Duration | Type of Interview | |
---|---|---|---|---|---|
1 | 12.02.2016 | Incumbent | Business Development Manager | 153 min | Personal interview |
2 | 20.04.2016 | Rendering industry | Product and Sales Manager | 84 min | Phone interview |
3 | 20.04.2016 | Incumbent | Purchasing Manager | 92 min | Personal interview |
4 | 13.05.2016 | Incumbent | Business Development Manager | 57 min | Personal interview |
5 | 11.07.2016 | Research institute | Researcher | 85 min | Personal interview |
6 | 16.06.2017 | Incumbent | Business Development Manager | 112 min | Personal interview |
7 | 15.03.2018 | Industry Confederation | Managing Director | 45 min | Personal interview |
8 | 28.06.2018 | Incumbent | Process and Analysis Manager | 67 min | Personal interview |
9 | 18.12.2018 | Incumbent | Process and Analysis Manager | 66 min | Personal interview |
10 | 09.05.2019 | Incumbent | Business Development Manager | 50 min | Personal interview |
11 | 09.05.2019 | Incumbent | R&D senior scientist | 50 min | Personal interview |
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---|---|---|---|---|---|---|
A | 2012–2015 | By-products derived from animal and marine industries | Low value products markets | Increase the knowledge base on enzymatic hydrolysis of animal and marine by-products | Developing rapid screening techniques for process monitoring of industrial enzymatic protein hydrolysis | New markets for utilization of animal and marine hydrolysates |
B | 2012–2018 | Norwegian biomass derived from different industrial streams | NA | Establishing a national “enzyme development pipeline” | Developing competitive enzyme technologies able to utilize a wide range of Norwegian biomass | NA |
C | 2013–2017 | Low value side-streams of Norwegian food industry | NA | Producing films based on products like polysaccharides (starch) from potato, gelatin, and protein from mammals and fish as well as chicken feathers | Developing biodegradable mulch films for weed control in row-crop production | Environmentally friendly substitute for herbicides, as well as for petroleum-based polymer mulch films |
D | 2013–2017 | Chicken by-products (e.g., chicken bone cake) | NA | Addressing the potential obesity-reducing effects of bioactive compounds from meat on chicken bones and wings | Enzymatic breakdown of proteins Producing liquid or dried peptide hydrolysate with high quality and high value applications | Pet-feed markets Functional proteins/peptides for human products |
E | 2014–2017 | Eggshell | NA | Converting eggshell membrane into raw material for biomedical applications | Biomedical process technology | Biomedical applications (e.g., new skin regeneration, wound healing) |
F | 2015–2019 | By-products of food processing industry | NA | Developing new concepts and methods for flexible and sustainable food processing in Norway, capable of coping with the small volumes and high biological variation of existing raw materials | iProcess innovations e.g., 3D CAD anatomical models based on X-ray CT imaging and image processing; visual guidance of robot for adaptive processing, dedicated multifunctional and dexterous grippers challenging processing operation | NA |
G | 2015–2023 | By-products, residues not suitable for direct human consumption | NA | Developing sustainable feed ingredients from natural bioresources unsuited for direct human consumption | Innovative feed processing technology, conversion of national bioresources into feed for farm animals and fish | Novel feed ingredients |
H | 2016–2019 | Plus products | NA | A new slaughter and cutting concept—improvement with the proposed processing method, based on pre-cutting of pig with warm cutting, form outside and in, and part-atomization | NA | |
I | 2017–2019 | 12,000 tons of residues (plus products) from mechanical deboning of chicken | Cheap feed ingredients | Converting low-value plus products into high-value ingredients and foods for higher-paying markets | Enzymatic protein hydrolysis (EPH) | Sport/fitness market, and the elderly market |
J | 2017–2020 | Poultry (chicken carcasses before and after mechanical de-boning) and dairy processing by-products | NA | Screening protein hydrolysate from poultry and dairy processing by-products for potential antidiabetic peptides | Antidiabetic peptides in protein hydrolysates | Medical applications |
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Strøm-Andersen, N. Incumbents in the Transition Towards the Bioeconomy: The Role of Dynamic Capabilities and Innovation Strategies. Sustainability 2019, 11, 5044. https://doi.org/10.3390/su11185044
Strøm-Andersen N. Incumbents in the Transition Towards the Bioeconomy: The Role of Dynamic Capabilities and Innovation Strategies. Sustainability. 2019; 11(18):5044. https://doi.org/10.3390/su11185044
Chicago/Turabian StyleStrøm-Andersen, Nhat. 2019. "Incumbents in the Transition Towards the Bioeconomy: The Role of Dynamic Capabilities and Innovation Strategies" Sustainability 11, no. 18: 5044. https://doi.org/10.3390/su11185044
APA StyleStrøm-Andersen, N. (2019). Incumbents in the Transition Towards the Bioeconomy: The Role of Dynamic Capabilities and Innovation Strategies. Sustainability, 11(18), 5044. https://doi.org/10.3390/su11185044