Environmental Policy and Competitiveness in a Globalizing World: Challenges for Low-Income Countries in the UNECE Region

A major policy goal of low-income countries is to promote the creation of competitive economic capacities in order to achieve sustained growth and raise the material well being of the population. Economic growth is, however, associated with increasing environmental pressures, and the question is to what extent the costs of more stringent environmental policies will affect the competitiveness of domestic firms. This paper examines the empirical evidence on the impact of environmental protection costs on international trade and FDI location decisions and explores the opportunities that the process of technological upgrading, which is a major driving force of economic development, provides for reducing environmental pressures. Also considered are the policies and supportive institutional arrangements that can help to effectively integrate environmental protection into national economic development strategies and thereby promote sustainable production and consumption patterns.Environmental policy, competitiveness, Eastern Europe, transition economies

Environmental Policy and International Competitiveness in a Globalizing World: Challenges for Low-Income Countries in the UNECE Region.

This paper addresses a set of conflicting national objectives, that between economic competitiveness and environmental quality. In lower-income economies, the perceived benefits of improved environmental quality may be valued less than in richer economies while the perceived opportunity costs of abatement or compliance may be valued higher especially when they impact employment levels or result in lower wages and profits. There is also the fear that more stringent standards might negatively impact foreign investment as multinationals seek out locations where operating costs are low. As such, these countries are therefore quite concerned about mandating environmental regulations that could impose significant costs on their enterprises and thereby reduce their global competitiveness. In addition there is a free rider problem regarding transboundary pollution as a country can benefit from the higher environmental standards negotiated amongst its neighbours while avoiding all the costs by deciding not to participate themselves. This paper examines environmental policy in the former transition economies. In these countries environmental institutions, especially the government ministries, are weak, regulations are often inadequate, and enforcement efforts need to be improved. At the same time these economies attach a high priority to increasing living standards and view that this can only be achieved by increasing their global competitiveness in a number of non-traditional industries. Nevertheless it is argued that high environmental standards are only a minor factor in determining cost competitiveness for most industries and locational decisions for multinationals. Even to the degree that they might be a competitive disadvantage in the short-run, they can actually turn out to be an advantage in the longer-term as they promote technological upgrading, the efficient use of resources, and can reduce adjustment costs involved with future trade policy initiatives or integration into production-sharing networks. In addition there are other benefits external to the firm including improved public health, increased tourism and additional recreational resources. Furthermore, the costs of undoing degradation, which will be desired at some future date as national incomes rise, can be avoided altogether. Thus in essence, when these dynamic factors are combined with the social benefits, the real costs of setting high environmental standards are much less than what their current costs might suggest.competitiveness, Europe, transition economies, environmental policy, climate change, sustainable development

Understanding the Long-Term Growth Performance of the East European and CIS Economies

The paper analyses the determinants of long-term economic performance of east European and CIS economies in two periods: 1960-1989 (the era of central planning) and 1990-2005 (the transition to the market economy system). Throughout the 1960s and 1970s economic growth in eastern Europe progressively weakened and during the 1980s most of these economies plunged into a prolonged stagnation or recession, which contributed to the collapse of communism and central planning. The transition from plan to market began with the transformational recession, which persisted until the mid-1990s in eastern Europe, but was longer and deeper in the CIS. Since then, the east European and CIS economies have embarked on a path of strong economic growth. The recovery has been accompanied by a surge in fixed investment, often complemented by large inflows of FDI. Despite robust output growth, however, there has not been - at least so far - a noteworthy recovery in employment. The main feature of the recent strong economic growth in the region has been a remarkable upturn in both labour productivity and total factor productivity. The considerable gains in productive efficiency and rapid technological change were triggered by wide-ranging market reforms and the modernization of the capital stock. Gains in aggregate output per person employed have outpaced by a large margin increases in real GDP per capita. In terms of average productivity and real per capita income levels relative to those of the more developed, industrialized countries, the east European and CIS economies still face a long catching up process.economic growth, East Europe, CIS, transition economies

Roll-to-Roll pilot line for large-scale manufacturing of microfluidic devices

Roll-to-roll (R2R) technologies with roller-based nanoimprinting methods enable manufacturing of highly cost-effective and large-scale sheets of flexible polymer film with precise structures on a micro- and nanoscale 1. Areas that can benefit strongly from such large scale technologies are microfluidics, biosensors, and lab-on-chip products for point of care diagnostics, drug discovery and food control. Here, R2R fabrication could greatly reduce production costs and increase manufacturing capacity with respect to currently used products. A pilot line with this technology is investigated in the European Horizon 2020 project R2R Biofluidics and its capabilities are tested on two Demonstrators: - Demonstrator 1: In-vitro diagnostic chip with imprinted microfluidic channels based on optical chemiluminescence measurement by photodetectors. - Demonstrator 2: Neuronal cell culture plate with imprinted cavities and channels for controlled culturing and fluorescence imaging of neurons, for high throughput drug screening. Please click Additional Files below to see the full abstract

High-throughput roll-to-roll production of polymer biochips for multiplexed DNA detection in point-of-care diagnostics

Roll-to-roll UV nanoimprint lithography has superior advantages for high-throughput manufacturing of micro- or nano-structures on flexible polymer foils with various geometries and configurations. Our pilot line provides large-scale structure imprinting for cost-effective polymer biochips (4500 biochips/hour), enabling rapid and multiplexed detections. A complete high-volume process chain of the technology for producing structures like μ-sized, triangular optical out-couplers or capillary channels (width: from 1 μm to 2 mm, height: from 200 nm up to 100 μm) to obtain biochips (width: 25 mm, length: 75 mm, height: 100 μm to 1.5 mm) was described. The imprinting process was performed with custom-developed resins on polymer foils with resin thicknesses ranging between 125–190 μm. The produced chips were tested in a commercial point-of-care diagnostic system for multiplexed DNA analysis of methicillin resistant Staphylococcus aureus (e.g., mecA, mecC gene detections). Specific target DNA capturing was based on hybridisation between surface bound DNA probes and biotinylated targets from the sample. The immobilised biotinylated targets subsequently bind streptavidin–horseradish peroxidase conjugates, which in turn generate light upon incubation with a chemiluminescent substrate. To enhance the light out-coupling thus to improve the system performance, optical structures were integrated into the design. The limits-of-detection of mecA (25 bp) for chips with and without structures were calculated as 0.06 and 0.07 μM, respectively. Further, foil-based chips with fluidic channels were DNA functionalised in our roll-to-roll micro-array spotter following the imprinting. This straightforward approach of sequential imprinting and multiplexed DNA functionalisation on a single foil was also realised for the first time. The corresponding foil-based chips were able to detect mecA gene DNA sequences down to a 0.25 μM concentration.This research was supported by R2R BIOFLUIDICS project (http://www.r2r-biofluidics.eu/) under Horizon 2020 European Union (EU) Research and Innovation Programme with grant agreement no 646260. The research was also partially supported by NextGenMicrofluidics project (https:// www. nextgenmicrofluidics.eu/) under HORIZON2020 with grant agreement no 862092. The authors cordially thank Gerburg Schider & Gerhard Mohr, Markus Postl, Paul Patter and Alexander Wheeldon (JOANNEUM RESEARCH – Materials, Weiz, Austria) for revising the manuscript, preparing all the chip and R2R pilot line illustrations, taking the photographs and providing technical support, respectively. The authors are also grateful to Christian Wolf and Johannes Götz (JOANNEUM RESEARCH – Materials, Weiz, Austria) for their supports in the fluidic design and R2R UV-NIL structuring, respectively. We further kindly thank Alba Simon Munoz and Robert Fay (SCIENION AG, Berlin, Germany) for providing the illustration of the R2R micro-spotting line. PT specially thanks Ege Ozgun (NANOTAM, Bilkent University, Ankara, Turkey) for critically reading the manuscript

Overexpression of human BAG3P209L in mice causes restrictive cardiomyopathy

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