Phytoremediation – mycolab.ai

Soil polluted system shapes endophytic fungi communities associated with Arundo donax: a field experiment

mycolabadmin

Mining activities pollute soils with heavy metals and red mud waste, damaging ecosystems and making plant growth difficult. This study examined fungi living inside the roots of Arundo donax, a hardy plant that survives in polluted soils, grown in three soil types: clean, heavy metal-contaminated, and red mud-contaminated. The researchers found that fungal communities changed based on the type of pollution, with a fungus called Pleosporales sp. thriving in red mud and showing promise for helping clean up contaminated soils. This research suggests that understanding these beneficial fungi could improve strategies for using plants to remediate polluted environments.

The Effect of Plant Growth Promoting Rhizobacteria Bacillus thuringiensis LKT25 on Cadmium Accumulation and Physiological Responses in Solanum nigrum L

mycolabadmin

Scientists discovered a beneficial bacterium called Bacillus thuringiensis LKT25 that helps black nightshade plants absorb cadmium from contaminated soil more effectively. When this bacterium is applied to the plant roots, it boosts plant growth and activates the plant’s natural defense systems against heavy metal toxicity. In tests with moderately contaminated soil, the bacterial treatment improved cadmium removal by nearly 50%, making it a promising solution for cleaning up polluted agricultural lands.

Phytoremediation Potential of Heavy Metals Using Biochar and Accumulator Plants: A Sustainable Approach Towards Cleaner Environments

mycolabadmin

Researchers tested whether mixing coconut fiber biochar with contaminated mine soil could help plants called Sanvitalia procumbens clean up heavy metal pollution. The plants absorbed less toxic metals when grown in the biochar-amended soil, grew bigger, stayed healthier with more green coloring, and experienced less genetic damage. Using this natural byproduct from coconut processing as a soil amendment proved to be an effective and sustainable way to reduce heavy metal contamination risks to the environment and food chain.

Modern-Day Green Strategies for the Removal of Chromium from Wastewater

mycolabadmin

Chromium from industries like leather tanning and metal plating contaminates water and soil, causing serious health problems including cancer and organ damage. Scientists have developed eco-friendly methods using bacteria, fungi, plants, and agricultural waste to remove chromium from polluted water at low cost. These biological treatment methods are more sustainable and affordable than traditional chemical approaches, offering a promising solution for cleaning up contaminated environments.

Role of Azolla in sustainable agriculture and climate resilience: a comprehensive review

mycolabadmin

Azolla is a fast-growing water fern that can help farms become more sustainable by naturally fertilizing soil with nitrogen, reducing the need for chemical fertilizers. It also helps control weeds, conserve water, and provides nutritious feed for livestock and fish. Beyond agriculture, Azolla can help reduce greenhouse gas emissions and clean polluted water, making it valuable for both farming and environmental protection.

Phyto- and Microbial-Based Remediation of Rare-Earth-Element-Polluted Soil

mycolabadmin

Rare-earth elements from mining and industry accumulate in soil, posing environmental and health risks. This review explores how plants and beneficial microorganisms can work together to clean up contaminated soil by absorbing or immobilizing these elements. The combined approach of using specific plant species alongside soil microorganisms is more effective than using either method alone, offering a natural and cost-effective solution for soil remediation.

Optimizing bioremediation techniques for soil decontamination in a linguistic intuitionistic fuzzy framework

mycolabadmin

This research develops mathematical tools to help experts choose the best method for cleaning contaminated soil using living organisms. The study presents new fuzzy logic operators that can handle both numerical and linguistic information, making decisions more understandable to humans. When applied to a contaminated industrial site, the method identified bioaugmentation (adding beneficial microorganisms) as the most effective cleanup approach among four options tested.

Enhanced Phytoextraction Technologies for the Sustainable Remediation of Cadmium-Contaminated Soil Based on Hyperaccumulators—A Review

mycolabadmin

Cadmium contamination of farmland is a serious global problem that threatens food safety and human health. This review explores how special plants called hyperaccumulators can extract cadmium from soil, and how scientists can boost their effectiveness through various methods like beneficial bacteria, improved farming techniques, and special chemicals. The research shows that combining multiple enhancement strategies works better than using any single approach, offering hope for cleaning up polluted agricultural lands sustainably.

A review on microbe–mineral transformations and their impact on plant growth

mycolabadmin

Soil microorganisms are crucial partners that help plants access nutrients locked in soil minerals. Bacteria and fungi produce special acids and molecules that dissolve minerals, making nutrients like phosphorus, iron, and zinc available for plant roots to absorb. This natural process reduces the need for chemical fertilizers and helps plants grow stronger while cleaning up contaminated soils.

Enhancing Environmental and Human Health Management Through the Integration of Advanced Revitalization Technologies Utilizing Artificial Intelligence

mycolabadmin

This paper describes how combining artificial intelligence with environmental monitoring can help us better understand how pollution harms our health. The authors propose a seven-step system that collects data on pollution levels in air, water, and soil alongside health information from communities. By using AI to analyze these massive datasets together, scientists and doctors can more quickly identify which pollutants are causing specific health problems and design better treatments for affected people and environments.

Research Keyword: Phytoremediation