Journal of Ecology and Toxicology
Open Access

Bioremediation; Bio resources; Green waste; Heavy metals; PGPR; Complexation; Chelation

Introduction

In recent years, the detrimental effects of pollution on our environment have become increasingly evident. As a result, there is a growing need for sustainable and efficient methods of bioremediation to mitigate the impact of pollutants. Green waste, comprising organic materials such as leaves, branches, and grass clippings, offers a promising solution for environmental cleanup. When combined with plant growth promoting rhizobacteria, a group of beneficial soil microorganisms, their synergy enhances the bioremediation potential significantly [1]. This article delves into the incredible capabilities of this powerful duo and explores how their combination can revolutionize bioremediation efforts. Use of peel leftovers from a variety of fruits, vegetables, and plants adsorption is an environmentally friendly, versatile, simple, and economical method due to having the benefits, such as their wide availability, straight forward treatments, biodegradable capacity, and variety of sources, waste management, and high efficacy in the removal of pollutants, such as heavy metals [2].

Green waste: nature's restorative resource

Green waste is an abundant and renewable resource that arises from various activities like landscaping, gardening, and agricultural practices [3]. Traditionally, green waste has been considered a burden and discarded in landfills, contributing to greenhouse gas emissions and leachate formation. However, recent research has shed light on its immense potential in bioremediation. Green waste contains organic matter, essential nutrients, and a diverse range of microorganisms, all of which play crucial roles in the remediation of polluted environments. The organic matter acts as a carbon source, providing energy for microbial degradation of pollutants. Additionally, the microorganisms present in green waste produce enzymes that break down complex pollutants into simpler, less harmful compounds. This natural process, known as microbial degradation, can effectively remove contaminants from soil, water, and air [4].

Plant growth promoting rhizobacteria: nature's allies

Plant growth promoting rhizobacteria are a group of beneficial bacteria that colonize the root systems of plants. They form a symbiotic relationship with the plant, providing numerous benefits, including enhanced nutrient uptake, disease resistance, and stress tolerance. Moreover, certain strains of PGPR possess remarkable abilities to degrade pollutants and promote bioremediation PGPR interact with plants through various mechanisms, such as the production of phytohormones, siderophores, and enzymes [5]. These compounds stimulate plant growth and development while also facilitating the breakdown and detoxification of pollutants. PGPR can degrade a wide range of contaminants, including hydrocarbons, heavy metals, pesticides, and organic pollutants. Furthermore, they enhance the plant's natural defense mechanisms, enabling it to withstand toxic environments and support the overall bioremediation process [6].

Enhanced synergy: green waste

The combination of green waste and PGPR creates a synergistic effect that amplifies their individual bioremediation capabilities. When green waste is incorporated into polluted soil or water, it provides a nutrient-rich environment that supports the growth and activity of PGPR [7]. The bacteria, in turn, enhance the decomposition of organic matter, accelerating the biodegradation of contaminants.

Additionally, PGPR secrete specific enzymes that break down complex pollutants more efficiently, further facilitating the detoxification process [8]. Furthermore, the presence of green waste promotes the establishment and colonization of PGPR in the rhizosphere, the zone of soil surrounding plant roots [9]. The root exudates released by plants act as a food source for the bacteria, fostering their growth and multiplication. As the PGPR population increases, the bioremediation efficiency also escalates, leading to a faster and more comprehensive cleanup of polluted environments [10].

Conclusion

The combined use of green waste and plant growth promoting rhizobacteria holds immense promise for bioremediation efforts. Their enhanced synergy offers an environmentally friendly, cost-effective, and sustainable approach to restore contaminated ecosystems. By harnessing the power of nature's allies, we can turn waste into a valuable resource and combat pollution effectively. Hence, the farmers are forced to apply harmful inputs to their crop fields which in turn leave the unavoidable toxic pollutants into the ecosystem. In fact, the reclamation of the degraded soil is an expensive way and needs multifactorial actions from various aspects. These pollutants are threat to Mother Nature and all living organisms. Therefore, elimination of these pollutants must be achieved unconditionally; bioremediation is an efficient way to fulfill the termination process. Bioremediation is a process where the harmful materials are stamped out from the ecosystem; it can be acquired efficiently by the usage of plant growth promoting rhizobacteria and green wastes like orange peels, pineapple peels and citrus peels. In this article it is well defined and explained about the process, methods, applications and detrimental effects of these aspects. The PGPR micro biome can be a sustainable approach to banish the toxic pollutants, support plant growth in stressful conditions and soil reclamation.

References

1. Suresh L, Martinez Calixto LE, Radfar L (2006) Successful treatment of mucous membrane pemphigoid with tacrolimus Special care in dentistry : official publication of the American Association of Hospital Dentists, the Academy of Dentistry for the Handicapped, and the American Society for Geriatric Dentistry. 26:66-70.

Indexed at, Google Scholar, Crossref

2. (2001) World Medical Association Declaration of Helsinki. Ethical principles for medical research involving human subjects Bulletin of the World Health Organization. 79:373-4.

Indexed at, Google Scholar, Crossref

3. (2014) The International Criteria for Behçet's Disease (ICBD): a collaborative study of 27 countries on the sensitivity and specificity of the new criteria. Journal of the European Academy of Dermatology and Venereology. JEADV 28:338-47.

Indexed at, Google Scholar, Crossref

4. Haefeli M, Elfering A (2006) Pain assessment. European spine journal : official publication of the European Spine Society, the European Spinal Deformity Society, and the European Section of the Cervical Spine Research Society. 15:S17-24.

Indexed at, Google Scholar, Crossref

5. Tappuni AR, Kovacevic T, Shirlaw PJ, Challacombe SJ (2013) Clinical assessment of disease severity in recurrent aphthous stomatitis. J Oral Pathol Med 42:635-41.

Indexed at, Google Scholar, Crossref

6. Bhakta BB, Brennan P, James TE, Chamberlain MA, Noble BA et al. (1999) Behçet's disease: evaluation of a new instrument to measure clinical activity. Rheumatology 38:728-33.

Indexed at, Google Scholar, Crossref

7. Kiyani A, Sohail K, Saeed MHB (2019) Efficacy of 0.1% tacrolimus in long-term management of erosive lichen planus. J Dermatolog Treat 1-16.

Indexed at, Google Scholar, Crossref

8. Chainani-Wu N, Silverman S, Reingold A, Bostrom A, Lozada-Nur F et al. (2008) Validation of instruments to measure the symptoms and signs of oral lichen planus. Oral surgery, oral medicine, oral pathology, oral radiology, and endodontics.105:51-8.

Indexed at, Google Scholar, Crossref

9. Hatemi G, Melikoglu M, Tunc R, Korkmaz C, Turgut Ozturk B et al. (2015) Apremilast for Behçet's syndrome--a phase 2, placebo-controlled study. N Engl J Med 372:1510-8.

Indexed at, Google Scholar, Crossref

10. Tawfeek H, Abdellatif DAAH, Abd Elaleem Elnashar J, Abdelaleem Y, Fathalla D (2020) Transfersomal gel nanocarriers for enhancement the permeation of lornoxicam. J drug deliv sci technol 56.

Indexed at, Google Scholar, Crossref