Water availability is crucial for the sustainability of life, and removal of effluents from water is equally significant. Water demand has increased as a consequence of industrialization due to its use in manufacturing processes. High production yields generate vast volumes of industrial effluents. For the long-term health of the ecosystem and industry, cost-effective and robust strategies for managing these effluents are crucial. Several remediation methods have been proposed to eliminate hazards and enable the recovery and reuse of wastewater pollutants.¹ The growth of communities worldwide has exposed our ecosystem to a large number of toxic effluents from multiple sources, while human activities and associated challenges are accelerating rapidly.^2,3 As a biologically driven process, bioremediation offers an outstanding tool to address the effects of effluents and eliminate environmental contamination by harmful substances (Figure 1).⁴

Wastewater treatment has become a reliable process for addressing water scarcity and protecting the environment from the toxic impacts of polluted water.⁵ Many regions now enforce strict regulations requiring effluent treatment prior to discharge into water bodies. Conventional physical and chemical processes (e.g., precipitation and adsorption) are effective but costly, require careful conditioning, and depend on complex infrastructure. Consequently, there is a pressing need to adopt green and innovative technologies—particularly microbial wastewater treatment methods—as sustainable alternatives to conventional approaches.⁶ Microbial treatment of wastewater using bacteria, microalgae, and fungi has recently attracted significant scientific attention. Nutrients such as nitrogen, carbon, and phosphorus—present in municipal effluents—support the growth of these organisms.⁷ Phytoremediation is often used to polish treated effluent; however, high nutrient levels can produce plant toxicity. To enhance plant growth under municipal wastewater irrigation, Sarawaneeyaruk et al.⁸ isolated plant growth-promoting bacteria (Bacillus spp.) from wastewater. Such eco-friendly technologies are sustainable and help maintain balance between human use and the environment. One promising strategy is the application of nanotechnology to remove harmful substances from contaminated water. This emerging field augments existing methods for heavy metal removal (Figure 2).⁹

Numerous organic pollutants are detected in water bodies, including herbicides, pesticides and haloalkanes.¹⁰ Toxic metals from acid mine drainage and inorganic pollutants such as sediments from stormwater runoff are examples of industrial waste. Various household effluents enter water sources. Herbicides used in gardens can also enter aquatic systems.¹¹ Cleaning products, soaps, and personal care items contain numerous contaminants that can pollute water systems making them unsuitable for use.¹² Chemicals, particularly acidic compounds from paper and steel manufacturing plants, are released into freshwater bodies.¹³ Freshwater systems receive over 70% of industrial discharges, including many toxic compounds.⁹ Primary agricultural discharges include fertilizers, pesticides, and other agrochemicals. Fertilizer production increases annually to enhance yield, resulting in high waste generation. Irrigation contributes significantly to surface water contamination in China and to nitrogen contamination of groundwater in the United States.¹⁰ Toxic compounds can accumulate in humans and ultimately reach dangerous thresholds, disrupting the food chain. Another significant source of water contamination is runoff (Table 1).

Sewage wastewater containing toxic metals has been released into the environment on a large scale in recent decades.¹⁴ Hazardous pollutants such as zinc (Zn), copper (Cu), sulfur (S), cadmium (Cd), chromium (Cr), nickel (Ni), and lead (Pb) are present in drinking water. The carcinogenic properties of these metals pose major health concerns as they bioaccumulate in humans via the food chain.¹⁵ Consequently, treatment of heavy metals in polluted wastewater is essential. Rapid urban sprawl and industrial expansion have led to the discharge of large volumes of wastewater, which is often reused for agricultural irrigation. This practice provides cost-effective water resources, particularly for resource-limited farmers, but it alters water quality and poses ecological risks.¹⁶ Water contamination is increasing daily due to population growth and industrial activities, exacerbating sanitation challenges and increasing health risks in both developing and developed regions. Consequently, water demand is projected to rise significantly, while available water bodies diminish due to depletion of nonrenewable sources, pollution, and climate change. This leads to longer droughts, increased evaporation, reduced precipitation, and altered hydrological cycles.^17,18

Biological methods employ microorganisms or biological processes to degrade pollutants in wastewater. As a green technology tool, microbes are essential to wastewater treatment and environmental protection. Various microbial groups—including bacteria, fungi, yeast, and microalgae—are utilized in biological treatments. Compared to physical and chemical methods, biological treatments are more cost-effective. Table 2¹⁹ summarizes the most commonly employed biological wastewater treatment techniques.

The remediation of industrial textile wastewater (ITW) has been approached through diverse biological, physicochemical, and hybrid techniques. Recent advances focus on microbial bioremediation, enzymatic degradation, and nanotechnology-assisted systems. This section synthesizes the methodologies commonly reported in the literature, highlighting their mechanisms, operational parameters, and comparative efficiencies.

Bacteria and other microorganisms are highly adapted for biological processes, easy to cultivate, and proliferate more quickly than other microbes, making them promising for removing organic contaminants. Numerous investigations have examined the ability of microorganisms to decolorize azo dyes in anaerobic environments. However, due to the action of redox mediators, the azoreductase enzyme cleaves azo bonds.²⁰ Conversely, several bacterial species degrade wastewater contaminants under aerobic conditions.²¹ The use of microbial consortia rather than pure cultures offers several advantages. Different strains can target various dye components, and metabolic byproducts from one strain’s activity may serve as substrates for others.²²

The primary goal of research on treating ITW using bacterial cultures is the decolorization of wastewater contaminants. One study examined how aerobic, thermophilic bacteria remove organics from wool effluent.²³

Fungi can eliminate dyes through two processes: biodegradation and biosorption.²⁴ Various ligninolytic fungi produce high levels of oxidative, extracellular enzymes—such as laccase, manganese peroxidase, and lignin peroxidase—that facilitate the solubilization of recalcitrant substrates (Figure 3).²⁵

Removal of color is the main focus of most studies on fungal remediation of ITW. Effectiveness varies widely depending on enzyme specificity and fungal morphology, making immobilization of fungal biomass advantageous.²⁶

Two applications for microalgae in ITW treatment are “low-cost wastewater treatment” and “bioenergy feedstock supply”.²⁷ Dye and nutrient removal can be achieved via bioadsorption and bioconversion using live or dead biomass.²⁸ Microalgae can grow mixotrophically, consuming organic compounds in addition to photosynthesis. The first paper on microalgal treatment of ITW was published in 2010.