Seaweed-based Packaging Solutions

Introduction The use of single-use packaging materials has increased dramatically in recent decades in parallel with increasing trends in convenience and fast-food. Most of these packaging materials are made of non-biodegradable, petroleum-based polymers that have degradative impacts on the environment and contribute to the global plastic pollution crisis. Finding alternative packaging materials is an important step towards building a bio-based circular economy. Sustainable land-based macroalgae cultivation can provide a solution, as it eliminates land-use pressure on coastal areas, doesn’t interfere with recreational activities or agriculture, reduces seasonal limitations, allows for complete control over product quality, and ensures consistent quality and traceability. Here, we present the success story of land-based macroalgae production for sustainable packaging solutions in the food industry via the Mak-Pak and Mak-Pak Scale-Up projects. Materials and Methods An initial screening of local macroalgae species was conducted based on detailed knowledge of growth rates, seasonality, geographic range, edibility, iodine content, biochemical properties, bioactivity, robustness and ease of cultivation. Different combinations of selected macroalgae were tested to develop a biodegradable, edible packaging prototype that was rated by consumer tests. In a follow-up project, we are focusing on eliminating the biggest bottleneck: scaling-up biomass production. We have partnered with a local, innovative farmer to sustainably scale-up and optimize biomass production for our sustainable, biodegradable macroalgae-based packaging material for the food industry. Results Several species of suitable macroalgae were selected based on the screening protocol and a method for using different combinations of selected species is described in a patent application for the packaging prototype. The packaging prototype was positively reviewed in consumer tests, where the consumers were pleasantly surprised by the neutral taste and smell. We could also show that certain components of the macroalgae that are important for packaging functionality (e.g. antioxidant activity) could be optimized during land-based production in artificial seawater. Currently we are in the early stages of scaling-up production and selecting strains to optimize growth rates and robustness, where we can complete the life cycle of one selected species from single cells to mature gametophytes within 6 weeks. With controlled induction of reproduction, we can continually provide material for transplantation to large-scale systems. Discussion The Mak-Pak and Mak-Pak Scale-Up projects have been featured in numerous news articles, exhibitions, and podcasts throughout Germany, Europe and even New Zealand. Our experience has shown that there is a lot of public interest in macroalgae-based packaging solutions. Consumers have become aware of the plastic pollution crisis and are open to alternatives to plastic packaging. Consequently, we have recently seen rapid changes in packaging trends in the cosmetic and food industries. Here we show that it is possible to produce a biodegradable, edible packaging from macroalgae biomass for the food-industry. Not only is this a success story for sustainable aquaculture, but also for macroalgae cultivation in general. This project has increased public awareness of macroalgae and contributed to a dialogue about the diversity of products and services that macroalgae can provide as we strive towards a sustainable, circular economy. However, optimization of the raw material production as well as the packaging itself is still underway. Furthermore, limitations in the food-industry require that our raw material meets high quality standards. In other industries where the quality of the raw material is not a limiting factor, there is enormous potential for macroalgae-based packaging solutions

Nachhaltigen Verpackungslösung aus Makroalgen für den Lebensmittel-Handel

Haben Sie schon einmal darüber nachgedacht, dass Meeresalgen eine Lösung für die weltweite Plastikverschmutzungskrise bieten könnten? Die Verwendung von Einweg-Verpackungsmaterialien hat in den letzten Jahrzehnten parallel zu den zunehmenden Trends in Sachen Convenience und Fast-Food dramatisch zugenommen. Die meisten dieser Verpackungsmaterialien bestehen aus biologisch nicht abbaubaren, erdölbasierten Polymeren, die sich negativ auf die Umwelt auswirken und zur globalen Plastikverschmutzungskrise beitragen. Die Plastikverschmutzung in den Ozeanen zerstört die Ökosysteme und bedroht in der Folge unsere eigene Gesundheit, die Lebensmittelsicherheit und den Küstentourismus. Die Suche nach alternativen Verpackungsmaterialien ist ein wichtiger Schritt zum Aufbau einer biobasierten Kreislaufwirtschaft und zum Erreichen unserer Nachhaltigkeitsziele. Unsere Ozeane könnten eine Lösung in Form von Makroalgen bieten. Das Mak-Pak Scale-Up Projekt konzentriert sich auf die Skalierung und Optimierung der Produktion von Meeresalgen, um nachhaltiges, biologisch abbaubares und/oder essbares Verpackungsmaterial auf Makroalgenbasis für die Fast-Food-Industrie zu schaffen, das potenziell Einweg-Plastikverpackungen ersetzen könnte. Dieser Vortrag stellt das Mak-Pak Scale-Up Projekt vor, einschließlich des Hintergrunds, der wichtigsten Errungenschaften, der aktuellen Aktivitäten und der Zukunftspläne im Rahmen der UN-Nachhaltigkeitsziele und der Kreislaufwirtschaft

Correction to: Cluster identification, selection, and description in Cluster randomized crossover trials: the PREP-IT trials

An amendment to this paper has been published and can be accessed via the original article

Screening and processing techniques for macroalgae in food applications

The trend to consume “to-go”, “ready-to-eat” or “convenience” food has increased over the last years (Statista, 2016). As a consequence, the amount of single-used packaging materials has also increased. Most of these packaging materials are made of non-biodegradable, petroleum-based polymers that have degradative impacts on the environment. This aspect is in conflict with the consumer expectations to have healthy and environmental-friendly food products including the surrounding packaging. Therefore, new, innovative and sustainable packaging concepts need to be established. A way for achieving this ambitious goal could be biodegradable and/or edible packaging concepts made form macroalgae (seaweeds). Macroalgae provide a sustainable, inexpensive and renewable raw material for packaging concepts due to their naturally occurring quantities and characteristic polymers such as alginate or agar. Moreover, marine hydrocolloids are commonly used in the food industry as thickeners or gelling agents and are accepted by consumers. For the proof of concept to develop a macroalgal-based packaging, we conducted a screening of local sources of green, red and brown algae to select a portfolio of functional and environmental-friendly species. We take into account that the intact and sensible maritime ecosystem should still be protected. Key markers for the selection were the concentration of iodine (low), hydrocolloids (high) and possible toxins (low) as well as local availability. The biodegradable macroalgae packaging concept was studied by using different mechanical preparation techniques under various conditions (e.g. energy input, shear rate, temperature etc.). The applied technology as well as the type of macroalgae led to different material properties of the produced macroalgal-based packaging. In contrast with common studies, where edible films are created by extracted hydrocolloids, the aim of the novel production system is to use the macro-algae in an ecological and economic optimized manner. The project (“Mak-Pak”) is supported by funds of the Federal Ministry of Food and Agriculture (BMEL) based on a decision of the Parliament of the Federal Republic of Germany via the Federal Office for Agriculture and Food (BLE) under the innovation support program

Optimizing antioxidant activity in Agarophyton vermiculophyllum for functional packaging

The value of macroalgae in a healthy human diet is becoming increasingly recognized and supported throughout Europe. Macroalgae provide a rich source of vitamins, minerals, proteins, fatty acids, and antioxidants that also support the functionality of macroalgae in other industries, including cosmeceuticals, pharmaceuticals, and more recently, packaging. Sustainable aquaculture of macroalgae will be necessary to supply the increasing demand for macroalgae as a functional material, considering that natural harvests are limited and cannot keep up with demand. Different methods can be used to cultivate macroalgae, including flow-through systems or recirculating aquaculture systems (RAS) with natural or artificial seawater. The latter provides strict control over the growth conditions and water quality in order to provide a high quality and traceable product. Additionally, environmental conditions such as salinity, temperature, and light can be modified to optimize the concentration of functional ingredients in macroalgae. While most research efforts have focused on seasonal and geographic trends in concentrations of functional ingredients in wild macroalgae, there is less information available on optimizing these functional ingredients in aquaculture. Therefore, we performed controlled experiments to optimize the activity of antioxidants in Agarophyton vermiculophyllum (Ohmi) Gurgel, J.N.Norris et Fredericq comb. nov. (formerly Gracilaria vermiculophylla) grown in RAS with artificial seawater and commercial fertilizer. We show that the free radical scavenging activity could be increased by 13% via high salinity, and up to 34% by increasing the light intensity, but not daily light dose, for a period of 7 days. We also monitored growth rates and the maximum quantum yield of photosystem II (Fv/Fm) and show that the conditions for optimizing antioxidant activity are not optimal for growth or photosynthesis. We therefore suggest an optimization period of 4–7 days exposure to high light on a 6:18 hour light:dark cycle prior to harvesting in order to increase antioxidant activity

Sustainable packaging solutions from land-based seaweed cultivation

The use of single-use packaging materials has increased dramatically in recent decades in parallel with increasing trends in convenience and fast-food. Most of these packaging materials are made of non-biodegradable, petroleum-based polymers that have degradative impacts on the environment and contribute to the global plastic pollution crisis. Finding alternative packaging materials is an important step towards building a bio-based circular economy. Sustainable land-based macroalgae cultivation can provide a solution, as it eliminates land-use pressure on coastal areas, doesn’t interfere with recreational activities or agriculture, reduces seasonal limitations, allows for complete control over product quality, and ensures consistent quality and traceability. Here, we present the success story of land-based macroalgae production for sustainable packaging solutions in the food industry via the Mak-Pak and Mak-Pak Scale-Up project

Quality of Physical Activity Apps: Systematic Search in App Stores and Content Analysis

BackgroundPhysical inactivity is a major contributor to the development and persistence of chronic diseases. Mobile health apps that foster physical activity have the potential to assist in behavior change. However, the quality of the mobile health apps available in app stores is hard to assess for making informed decisions by end users and health care providers. ObjectiveThis study aimed at systematically reviewing and analyzing the content and quality of physical activity apps available in the 2 major app stores (Google Play and App Store) by using the German version of the Mobile App Rating Scale (MARS-G). Moreover, the privacy and security measures were assessed. MethodsA web crawler was used to systematically search for apps promoting physical activity in the Google Play store and App Store. Two independent raters used the MARS-G to assess app quality. Further, app characteristics, content and functions, and privacy and security measures were assessed. The correlation between user star ratings and MARS was calculated. Exploratory regression analysis was conducted to determine relevant predictors for the overall quality of physical activity apps. ResultsOf the 2231 identified apps, 312 met the inclusion criteria. The results indicated that the overall quality was moderate (mean 3.60 [SD 0.59], range 1-4.75). The scores of the subscales, that is, information (mean 3.24 [SD 0.56], range 1.17-4.4), engagement (mean 3.19 [SD 0.82], range 1.2-5), aesthetics (mean 3.65 [SD 0.79], range 1-5), and functionality (mean 4.35 [SD 0.58], range 1.88-5) were obtained. An efficacy study could not be identified for any of the included apps. The features of data security and privacy were mainly not applied. Average user ratings showed significant small correlations with the MARS ratings (r=0.22, 95% CI 0.08-0.35; P<.001). The amount of content and number of functions were predictive of the overall quality of these physical activity apps, whereas app store and price were not. ConclusionsApps for physical activity showed a broad range of quality ratings, with moderate overall quality ratings. Given the present privacy, security, and evidence concerns inherent to most rated apps, their medical use is questionable. There is a need for open-source databases of expert quality ratings to foster informed health care decisions by users and health care providers