Biologically engineered microbes for bioremediation of electronic waste: Wayposts, challenges and future directions

Han, Ping; Teo, Wei Zhe; Yew, Wen Shan

doi:10.1049/enb2.12020

Cited by 20 publications

(8 citation statements)

References 102 publications

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“…Pulp denisty or amount of e-waste is another significant aspect that impacts the bioleaching potential of microorganism. As the concentration of e-waste increases, the amalgam of hazradous metals, inorganic pollutants in e-waste bacome toxic to microorganism and ceases the growth of micoorganism during bioleaching process and therefore reduce the production of lixiviant and metals solubilization significantly (Han et al 2022; Mudali et al 2021). These observations are based on the effect of one parameter at a time.…”

Section: Resultsmentioning

confidence: 99%

“…In addition, Mintek, BacTech, N2S are some other firms that are commercializing the biohydrometallurgy technique for recycling e-waste at large-scale operations. (Han et al 2022).…”

Section: Resultsmentioning

confidence: 99%

“…The researchers have continuously been developing many methods to overwhelm the limitations and to manifest this technology for industrial scale applications. The effect of synergistic behaviour on bioleaching activity have also examined with different cynogenic and sulphur reducing bacterial strains (Han et al 2022;Shittu et al 2021). Pradhan and Kumar (2012) utilized mixed culture of Chromobacterium violacium and Pseudomonas fluo rescence to enhance the Cu recovery.…”

Section: Introductionmentioning

confidence: 99%

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Exploring bioleaching potential of indigenous Bacillus sporothermodurans ISO1 for metals recovery from PCBs through sequential leaching process

Thakur

Kumar

2023

Waste Manag Res

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The low efficiency and selectivity limitations of biohydrometallurgy technique compel the researchers to explore novel microbial strains acclimated to metal existence site with higher toxicity tolerance and bioleaching capability in order to improve the role of bioleaching process for e-waste management. The current study aimed to explore bioleaching potential of indigenous Bacillus sporothermodurans ISO1; isolated from metal habituated site. The statistical approach was utilized to optimize a variety of culture variables including temperature, pH, glycine concentration and pulp density that impact bio-cyanide production and leaching efficiency. The highest dissolution of Cu and Ag, 78% and 37% respectively, was obtained at 40 °C, pH 8, glycine concentration 5 g L−1, and pulp density 10 g L−1 through One Factor at a Time (OFAT), which was further increased up to 95% Cu and 44% Ag recovery through the interactive effect of key factors in the Response Surface Methodology (RSM) approach. Furthermore, Chemo-biohydrometallurgy approach was utilized to overwhelm the specificity limitation; as higher concentration of Cu in computer printed circuit boards (CPCBs) causes interference to recover other metals. The sequential leaching through ferric chloride (FeCl3), recovered Cu prior to bio-cyanidation by B. sporothermodurans ISO1 and resulted in the improved leaching of Ag (57%), Au (67%), Pt (60%), etc. The current work reports on B. sporothermodurans ISO1, a new Bacillus strain that exhibits highest toxicity tolerance (EC50 = 425 g L−1) than earlier reported stains and has higher leaching potential that can be implemented to large-scale biometallurgical process for e-waste treatment to achieve the agenda of sustainable development goal (SDG) under the strategies of urban mining.

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Section: Resultsmentioning

confidence: 99%

“…In addition, Mintek, BacTech, N2S are some other firms that are commercializing the biohydrometallurgy technique for recycling e-waste at large-scale operations. (Han et al 2022).…”

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Exploring bioleaching potential of indigenous Bacillus sporothermodurans ISO1 for metals recovery from PCBs through sequential leaching process

Thakur

Kumar

2023

Waste Manag Res

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“…Joint research projects, technology transfer agreements, and knowledge exchange programs enable Nigerian researchers to leverage external support and advance their capabilities in lipase research. Furthermore, partnerships with international organizations and funding agencies facilitate access to grants, scholarships, and fellowships, enhancing research opportunities and promoting scientific excellence in Nigeria (Ejairu, et al, 2024;Ashok, et al, 2024;Han, et al, 2022).…”

Section: Challenges and Opportunitiesmentioning

confidence: 99%

Thermophilic lipases in industrial applications: Stutzerimonas stutzeri as a Case Study in Nigeria and the US

Deborah Aanuoluwa Soyombo

2024

GSC Biol. Pharm. Sci.

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Thermophilic lipases derived from Stutzerimonas stutzeri have garnered significant attention in recent years due to their robustness and efficiency in various industrial applications. This review delves into the research, development, and application of these enzymes, with a comparative analysis between Nigeria and the United States. In both nations, researchers have explored the enzymatic properties of thermophilic lipases from Stutzerimonas stutzeri, aiming to optimize their performance for diverse industrial processes. The research encompasses studies on enzyme purification, characterization, and genetic engineering to enhance catalytic activity and stability under extreme conditions. Additionally, efforts have been directed towards understanding the enzyme's structure-function relationship to tailor it for specific applications. In Nigeria, the focus on thermophilic lipases from Stutzerimonas stutzeri has been primarily driven by the need for sustainable biotechnological solutions in various industries, including food, pharmaceuticals, and biofuel production. The enzymes' thermostability makes them particularly suitable for high-temperature processes prevalent in Nigeria's tropical climate, offering potential for cost-effective and eco-friendly alternatives to conventional chemical catalysts. In contrast, the United States has witnessed extensive research and development in thermophilic lipases for industrial applications, with a strong emphasis on biocatalysis in the pharmaceutical, detergent, and biofuel sectors. The advanced infrastructure and investment in biotechnology have facilitated the commercialization of Stutzerimonas stutzeri lipases, leading to their integration into various industrial processes to improve efficiency and sustainability. Despite the similarities in research objectives, disparities exist in the technological advancements and industrial utilization of thermophilic lipases from Stutzerimonas stutzeri between Nigeria and the US. While Nigeria faces challenges related to limited resources and infrastructure, the US benefits from well-established research institutions and industrial networks, enabling accelerated innovation and commercialization. Bridging these gaps through international collaborations and knowledge exchange could facilitate the widespread adoption of thermophilic lipases for sustainable industrial development globally.

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“…In Ref. [1], the authors wish to acknowledge the funder. Below is the acknowledgment statement: “This project is partially supported by the National Research Foundation, Singapore, under its Competitive Research Programme (Award # NRF‐CRP22‐2019‐0005)”. …”

mentioning

confidence: 99%

Corrigendum: Biologically engineered microbes for bioremediation of electronic waste: Wayposts, challenges and future directions

2022

Engineering Biology

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Biologically engineered microbes for bioremediation of electronic waste: Wayposts, challenges and future directions

Cited by 20 publications

References 102 publications

Exploring bioleaching potential of indigenous Bacillus sporothermodurans ISO1 for metals recovery from PCBs through sequential leaching process

Exploring bioleaching potential of indigenous Bacillus sporothermodurans ISO1 for metals recovery from PCBs through sequential leaching process

Thermophilic lipases in industrial applications: Stutzerimonas stutzeri as a Case Study in Nigeria and the US

Corrigendum: Biologically engineered microbes for bioremediation of electronic waste: Wayposts, challenges and future directions

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