Please use this identifier to cite or link to this item:
http://repository.futminna.edu.ng:8080/jspui/handle/123456789/18079| Title: | Phycoremediation of crude oil-contaminated water: Current microbial remediation protocol and effect on the ecosystem |
| Authors: | Ezugwu, Basil Utazi Bala, Jeremiah David Abioye, Olabisi Peter Oyewole, Oluwafemi Adebayo Maude, Asmau Mohammed Adabara, Nasiru Usman Kuta, Faruk Adamu |
| Keywords: | Crude oil pollution Aquatic environments Remediation Microbial-based remediation Phycoremediation Crude oil pollution Aquatic environments Remediation Mmicrobial-based remediation Phycoremediation |
| Issue Date: | 2022 |
| Publisher: | Journal of Pure and Applied Sciences |
| Citation: | Ezugwu, B.U., Bala, J..D., Abioye, O.P., Oyewole, O.A., Maude, A.M., Adabara, N.U., Kuta, F.A. (2022). Phycoremediation of crude oil-contaminated water: Current microbial remediation protocol and effect on the ecosystem: A review. Journal of Pure and Applied Sciences, 22, 272-291. |
| Abstract: | Owing to the extensive use of petroleum hydrocarbons in the modern world, petrochemi cal derivatives have become one of the major environmental pollutants with ensuing envi ronmental devastation. Pollution of aquatic environments by hydrocarbon via numerous anthropogenic and natural sources has become even more worrisome. The detrimental effects of this pollution on the aquatic micro and macroorganisms, including fishes, birds, and mammals, have been thoroughly documented. The associated health impacts of crude oil pollution on humans and the environment have resulted in the current microbial reme diation protocol to alleviate the effect on the ecosystem. The physicochemical protocols of cleaning the aquatic environments of hydrocarbon pollutants have been found deficient because of the high cost and the need for high-tech equipment and expertise. The ability of diverse microorganisms to degrade hydrocarbon pollutants as sources of carbon has been well studied for over three decades. These studies have focused mostly on bacteria. The bacterial-based crude oil remediation protocol is an effective means of remediating crude oil-polluted environments. It is environmentally friendly and cost-effective. It is even more effective when in collaboration with different species of bacteria (consortium) or when in association with plants (rhizodegradation). However, bacterial-based metabolism of organic pollutants, like crude oil, comes with severe reduction in dissolved oxygen, giving rise to longer time for microbial adaptation to the pollutants and the actual degradation, thus raising questions on the application of bacterial-based remediation protocols. Studies on the hydrocarbon metabolism by algae are already available with some details on the oxygenic metabolic pathways. The present review, therefore, highlights the potentials/advantages of algae in crude oil remediation. In addition to algae’s direct involvement in the breakdown of hydrocarbon pollutants, it provides an enabling environment, like the copious supply of oxygen, for indigenous aerobic microbes equally involved in the remediation |
| Description: | The traditional physicochemical remediation proto cols are helpful as they provide a fast means of con fronting the crude oil pollution as soon as it occurs. However, these protocols have become obsolete because of the expensive nature and need for high tech equipment and expertise. Microbes, fungi, and bacteria have the spontaneous abilities to break down hydrocarbon pollutants and turn them into delicacies (microbial-based remediation protocol). This proto col has also shown to be ineffective especially when applied as sole remediation system of crude oil-con taminated aquatic environments, particularly against high concentrations of pollutants like massive marine oil spillage. The use of these agents in hydrocarbon degradation is environmentally friendly, cost-effec tive, and thorough. However, the time frame needed for microbial adaptation and colonization is usu ally a huge drawback. Algae use the greenhouse gas, CO2 , as they grow photosynthetically: a tool against global warming and climate change. Algae are able to grow very fast, doubling in large mass and colonizing the entire polluted sites within the shortest time. In the process, algae generate about half of the oxygen needed for the sustenance of planet Earth. Algae have the ability to proliferate in extremely salty habitats and also generate the essential oxygen needed for microbial hydrocarbon degradation in the said envi ronment. Obviously, the application of phycoremedia tion, therefore, becomes more advantageous not only because of the direct involvement in the hydrocarbon degradation but also for creating the enabling envi ronmental conditions needed for other members of the microbial community involved in the environmen tal remediation. |
| URI: | http://repository.futminna.edu.ng:8080/jspui/handle/123456789/18079 |
| Appears in Collections: | Microbiology |
Files in This Item:
| File | Description | Size | Format | |
|---|---|---|---|---|
| Phycoremediation of crude oil-contaminated water Current microbial.pdf | 1.23 MB | Adobe PDF | View/Open |
Items in DSpace are protected by copyright, with all rights reserved, unless otherwise indicated.