Environmental remediation – Page 2

Current status and future prospects of microalgae-based degradation of spent lubricant oil hydrocarbon towards environmental sustainability: a mini review and bibliometric analysis

mycolabadmin

Spent oil waste from cars and industries is a major environmental problem that traditional cleanup methods struggle to handle. This review shows that microalgae, tiny organisms that are already used for various purposes, can effectively break down the harmful chemicals in used oil. A bibliometric analysis reveals that scientists worldwide, especially in China, are increasingly researching this promising green solution to clean up oil pollution in soil and water.

The Strategies Microalgae Adopt to Counteract the Toxic Effect of Heavy Metals

mycolabadmin

Microalgae can help clean water polluted with toxic heavy metals like cadmium and chromium while also producing useful biomass. The review explains how microalgae absorb and trap heavy metals, and describes ways to make them more effective, including adding certain chemicals, selecting resilient strains, and using genetic modification. Combining heavy metal removal with biomass production could make the process cost-effective for real-world applications.

Biotransformation of the Fluoroquinolone Antibiotic, Levofloxacin, by the Free and Immobilized Secretome of Coriolopsis gallica

mycolabadmin

Researchers discovered that a type of fungus called Coriolopsis gallica can break down the antibiotic levofloxacin, which persists in the environment and contributes to antibiotic resistance. They tested both free enzymes from the fungus and enzymes trapped in alginate beads to see which worked better. The study found that free enzymes degraded more of the antibiotic when a chemical helper molecule called HBT was added, while immobilized enzymes were more stable and could be reused multiple times.

Biodegradation of synthetic organic pollutants: principles, progress, problems, and perspectives

mycolabadmin

This comprehensive review explains how bacteria naturally break down synthetic pollutants in our environment through various mechanisms. Scientists use advanced tools like gene sequencing and computer analysis to identify which bacteria degrade specific pollutants, how quickly they work, and what intermediate products form. Understanding these bacterial degradation pathways helps us develop better strategies to clean up contaminated water and soil in an environmentally friendly way.

Bioremediation Potential of Indigenous Bacterial Isolates for Treating Petroleum Hydrocarbons-Induced Environmental Pollution

mycolabadmin

Scientists isolated three types of bacteria from soil near auto repair shops that can break down petroleum oil pollutants. When tested in the laboratory, these bacteria degraded between 55-83% of petroleum hydrocarbons over 12 days by converting them into simpler compounds. These findings suggest these naturally occurring bacteria could offer an affordable and environmentally-friendly way to clean up oil-contaminated soil without the harmful side effects of chemical cleanup methods.

Electroactive Bacteria in Natural Ecosystems and Their Applications in Microbial Fuel Cells for Bioremediation: A Review

mycolabadmin

Electroactive bacteria are special microorganisms found in soil, water, and sediment that can generate electrical current. Scientists are harnessing these bacteria in microbial fuel cells to simultaneously clean contaminated water and produce electricity. These systems can remove pollution including heavy metals and antibiotics while generating renewable energy, offering a green solution for environmental cleanup and power generation.

Genomic analysis of Acinetobacter baumannii DUEMBL6 reveals diesel bioremediation potential and biosafety concerns

mycolabadmin

Researchers isolated bacteria from diesel-contaminated soils in Bangladesh that can break down diesel fuel efficiently. The best strain, Acinetobacter baumannii DUEMBL6, degraded about 41% of diesel in laboratory tests through multiple enzymatic pathways. However, this bacteria also carries genes for antibiotic resistance and virulence factors, making it both a promising environmental solution and a potential health risk that requires careful monitoring before field application.

Actinorhizal plants and Frankiaceae: The overlooked future of phytoremediation

mycolabadmin

Actinorhizal plants are special trees and shrubs that team up with beneficial bacteria called Frankiaceae to clean up polluted and degraded soils. This natural partnership helps these plants survive harsh conditions like salty or heavy metal-contaminated soil while also cleaning up the environment. The bacteria help the plants by providing essential nitrogen and improving their ability to tolerate pollution, making them an inexpensive and sustainable solution for restoring degraded farmland.

Exploring the Potential and Evaluating Hydrocarbon Degradation by Novel Antarctic Dietzia and Pusillimonas Isolates From a Pristine Environment

mycolabadmin

Scientists discovered two types of bacteria living in an Antarctic pond that can break down crude oil and petroleum contamination. These bacteria can survive in very cold conditions and harsh environments. Testing showed they could degrade about 79% of crude oil in laboratory conditions and improved cleanup processes in contaminated soil samples. This research suggests these Antarctic bacteria could be useful tools for cleaning up oil-polluted sites, especially in cold regions of the world.

Nanostructured Aerogels for Water Decontamination: Advances, Challenges, and Future Perspectives

mycolabadmin

Aerogels are ultra-light, ultra-porous materials made mostly of air that can effectively remove toxic pollutants from contaminated water. These materials can absorb heavy metals, oil spills, dyes, and pesticides from water, offering a promising solution to global water contamination problems. Scientists are developing new types of aerogels using sustainable methods to make them more practical and affordable for large-scale water treatment applications in communities worldwide.

Research Keyword: Environmental remediation