Biodegradation, Pollutants and Bioremediation Principles
eBook - ePub

Biodegradation, Pollutants and Bioremediation Principles

  1. 352 pages
  2. English
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eBook - ePub

Biodegradation, Pollutants and Bioremediation Principles

About this book

This book presents a broad compendium of biodegradation research and discussions on the most up-to-date bioremediation strategies. The most relevant microbiological, biochemical and genetic concepts are presented alongside the fundamentals of bioremediation. The topics include: a wide variety of contaminant impacts evaluation, key methodologies required to measure biodegradation and propose new bioremediation protocols, as well as the handling of microbial communities related to such processes. The selected collaborating authors are renowned for their microbiology expertise and will provide an in-depth reference for students and specialists. The contents provide a valuable source of information for researchers, professionals, and policy makers alike.

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Yes, you can access Biodegradation, Pollutants and Bioremediation Principles by Ederio Dino Bidoia, Renato Nallin Montagnolli, Ederio Dino Bidoia,Renato Nallin Montagnolli in PDF and/or ePUB format, as well as other popular books in Biological Sciences & Biology. We have over one million books available in our catalogue for you to explore.

Information

Publisher
CRC Press
Year
2021
eBook ISBN
9781000264555
Topic
Biological Sciences
Subtopic
Biology
Index
Biological Sciences

1
Alkylphenols and Alkylphenol Ethoxylates Their Impact on Living Organisms, Biodegradation, and Environmental Pollution

Tomasz Grześkowiak,1 Andrzej Szymański,1 Agnieszka Zgoła-Grześkoviak,1,* Beata Czarczyńska-Goślińska2 and Robert Frankowskil1
Alkylphenols (APs) and short-chain alkylphenol ethoxylates (APEs) containing 1, 2, and 3 ethoxylene units per molecule are known for their endocrine disrupting properties. However, despite bans and restrictions introduced by different countries (the European Union, Canada), APs and their ethoxylates are still widely used on a global scale. In the present chapter, the influence of these compounds on living organisms is presented, and different factors affecting endocrine disrupting properties are discussed, such as length and branching of the alkyl chain, as well as oxidization of both ethoxylene and alkyl chains of APEs molecules. Biodegradation of APs and APEs in both aerobic and anaerobic conditions is also presented, and studies on their bacterial and fungal degradation are discussed. Experiments on removal of these contaminants are described and their environmental fate is shown. Contamination of the environment is discussed separately for water and sediments.

Introduction

Alkylphenols (APs) and short-chain alkylphenol ethoxylates (APEs) containing 1, 2, and 3 ethoxylene units per molecule are known for their toxic and endocrine disrupting properties. However, despite bans and restrictions introduced by different countries (including the European Union, Canada, and the USA), APs and their ethoxylates are still widely used on a global scale because of their ease of production, low cost, and numerous applications.
In the present chapter, the influence of these compounds on living organisms is presented, including their toxic properties towards different organisms and disruption of the endocrine system, resulting in numerous harmful effects, such as lowered reproductive performance, or even cancer. Different factors affecting endocrine disrupting properties are discussed, including length of both ethoxy and alkyl chains, branching of the alkyl chain, and its substitution position in the aromatic ring. Biodegradation of APs and APEs in both aerobic and anaerobic conditions is also presented, and studies on their bacterial and fungal degradation are discussed. Experiments on removal of these contaminants are described and their environmental fate is shown. Contamination of the environment is discussed separately for water and sediments.
_____________
1 Poznan University of Technology, Institute of Chemistry and Technical Electrochemistry, Berdychowo 4, 60-965 Poznan, Poland.
2 Poznan University of Medical Sciences, Department of Pharmaceutical Technology, Grunwaldzka 6, 60-780 Poznan, Poland.
Emails: [email protected]; [email protected]; [email protected]; [email protected]
* Corresponding author: [email protected]

Production and usage of alkylphenols and their ethoxylates

Alkylphenols, mainly nonylphenol (NP) and octylphenol (OP), are widely manufactured chemicals, which are produced during alkylation of phenol with nonene (obtained from trimerization of propene) or octene (obtained from dimerization of butene) in the presence of a catalyst. APs can be transformed to alkylphenol ethoxlyates, which are commonly used surfactants (Reed 1978, Groshart et al. 2001). NP is used mostly for production of nonylphenol ethoxylates (NPEs), and in plastic industry (e.g., for production of resins and tri(4-nonylphenyl) phosphite)—a heat stabilizer), and also in the production of oximes (used for manufacturing metals) (Groshart et al. 2001, SUBSPORT 2013). On the other hand, OP is rarely used in the synthesis of octylphenol ethoxylates (OPEs), and it is estimated that 98% of OP is used in the production of phenolic resins (OSPAR 2006). NPEs are used in many applications, including industrial cleaning, textile and leather processing, paper production, metal processing, extraction of crude petroleum and natural gas, paints and lacquer manufacturing, as well as pest control products (Groshart et al. 2001, SUB SPORT 2013). OPEs are mainly used in emulsion polymerization, but also in the production of octylphenol ether sulphates, textile and leather processing, pesticide formulations, and paints (OSPAR 2006). As a result of their widespread usage and problematic biodegradation, APs and APEs are directed to the environment, and are ubiquitous in both surface waters and sediments (Fig. 1.1).
fig1_1_C.webp
Figure 1.1. Usage and fate of alkylphenol and alkylphenol ethoxylates.
Global production of APEs at the edge of the new millennium was estimated at half a million tons, and it still rises, mainly due to their increased production in Brazil, China, India, and Russia (Renner 1997, Bergé et al. 2012), because usage of NP and NPEs in Europe and North America is a subject of very restrictive law regulations (Directive 2003, Canadian Act 2001, US EPA 2005). These regulations were introduced after a number of studies showed incomplete biodegradation of APEs (Giger et al. 1984, Ahel and Giger 1985, Potter et al. 1999), endocrine disrupting properties of their biodegradation products (including short-chain APEs, as well as APs) (Jobling and Sumpter 1993, White et al. 1994, Soto et al. 1995), and high accumulation of short-chain NPEs and NP in the environment (Ding and Tzing 1998, Shang et al. 1999), while OPEs and OP were present at lower concentrations (Snyder et al. 1999, Loyo-Rosales et al. 2003) due to much lower usage of OPE surfactants (Groshart et al. 2001, OSPAR 2006).

Impact of alkylphenols and their ethoxylates on living organisms

The toxicity of alkylphenols and their ethoxylates was already extensively studied in the 90s. Numerous results were collected for fish, crustaceans, and other organisms. Available data shows that for 4-nonylphenol, lethal concentration killing 50% of tested subjects (LC50) falls between 100 and 1000 ug/L (Fig. 1.2) (Servos 1999, Canadian Water Act 2002), and similar data was also gathered for 4-octylphenol (Brook et al. 2005). Alkylphenol ethoxylates were also found to be toxic (Servos 1999), but their toxicity considerably depends on the number of ethoxy groups in the molecule (Canadian Water Act 2002, Whitehouse 2002). Thus, the Canadian Environmental Quality Guideline on nonylphenol and its ethoxylates gives toxic equivalency factors (’1EFs) for alkylphenols and their ethoxylates. For both NP and OP TEF = 1, for their ethoxylates with 1 to 8 ethoxy groups TEF = 0.5, for ethoxylates with 9 or more ethoxy groups TEF = 0.05, and for short-chained carboxylated ethoxylates TEF is also equal to 0.05 (Canadian Water Act 2002). Moreover, it was also found that toxicity of NPEs for different species (fish, invertebrates, algae) decreases exponentially with increasing ethoxy chain length (Whitehouse 2002). Therefore, the LC50 values of APEs often fall to the mg/L level (Warhurst 1995, Servos 1999).
Apart from their toxic properties, alkylphenols and their short-chain ethoxylates also belong to xenobiotics, which may be harmful to the development and reproduction of humans, wildlife, and aquatic organisms (Darbre 2015). These compounds have the ability to disrupt the functioning of the endocrine systems of humans and wildlife (Warhurst 1995). The first evidence of estrogenic potential of alkylphenols was reported by Dodds and Lawson in 1938 (Dodds and Lawson 1938). Later, these observations were confirmed in the research of Mueller and Kim (Mueller and Kim 1978), who proved the ability of various alkylphenols to displace the prebound estradiol from the estrogen receptor of uterine cytosols, and also to prevent estradiol from binding to the receptor. Moreover, the toxicity increased with the length of the hydrophobic chain For hydrophilic 4-ethoxyphenol or 4-(a-OH-isopentyl)phenol, no activity of inhibiting estradiol binding to the receptor was found (Mueller and Kim 1978).
fig1_2_B.webp
Figure...

Table of contents

  1. Cover
  2. Title Page
  3. Copyright Page
  4. Preface
  5. Table of Contents
  6. 1. Alkylphenols and Alkylphenol Ethoxylates — Their Impact on Living Organisms, Biodegradation, and Environmental Pollution
  7. 2. Selective-enrichment as a Tool to Obtain Microbial Degrading Consortia for the Remediation of Pesticide Residues
  8. 3. Using Molecular Methods to Identify and Monitor Xenobiotic-Degrading Genes for Bioremediation
  9. 4. Bioprospecting Contaminated Soil for Degradation of the Drimaren X-BN Azo Dye
  10. 5. Saccharomyces cerevisiae—A Platform for Delivery of Drugs and Food Ingredients Encapsulation and Analysis
  11. 6. Biotransformation of Toxic Thiosulfate into Merchandisable Elemental Sulfur by Indigenous SOB Consortium
  12. 7. Removal of Oil Spills in Temperate and Cold Climates of Russia Experience in the Creation and Use of Biopreparations Based on Effective Microbial Consortia
  13. 8. Microbial Biosurfactants Remediation of Contaminated Soils
  14. 9. Dual Benefits of Microalgae in Bioremediation Pollutant Removal and Biomass Valorization, a Review
  15. 10. Bioremediation and Biodegradation of Crude Oil Polluted Soil
  16. 11. Microbial Recycling of ‘Sustainable’ Bioplastics A Rational Approach?
  17. 12. Hydrogels and Nanocomposite Hydrogels for Removal of Dyes and Heavy Metal Ions from Wastewaters
  18. 13. Review on Period of Biodegradability for Natural Fibers Embedded Polylactic Acid Biocomposites
  19. 14. New Approaches on Phytoremediation of Soil Cultivated with Sugarcane with Herbicide Residues and Fertigation
  20. 15. Bioactivity and Degradability Study of the Bone Scaffold Developed from Labeo Rohita Fish Scale Derived Hydroxyapatite
  21. 16. Physiological and Metabolic Aspects of Pesticides Bioremediation by Microorganisms
  22. 17. Whole Effluent Toxicity Assessment of Sewage Water
  23. 18. Whole Effluent Toxicity Test for Ambient Water Monitoring
  24. Index