Ritu Mahajan scite author profile

A Methodical Study to Unravel the Potential of using Polysaccharides based Organic Nanoparticles Versus Hybrid Nanoparticles for Pesticide Delivery

Mahajan¹,

Selim²,

Neethu³

et al. 2021

Preprint

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Conventional pesticide release pollutes the atmosphere and root healthiness threats. To daze its limitations, nanotechnology mediated pesticide delivery using various natural polymers have been actively investigated. However, the lack of information on what are the beneficial/non-beneficial aspects of using hybrid- and organic- nanoparticles (NP) and among the polysaccharides which are better suited concerning pesticide loading efficiency (PLE), entrapment efficiency (E.E), and sustained-pesticide-release (SPR) has prompted us to investigate this study. In this report, we systematically investigate a series of polysaccharides such as starch (S), cellulose (C), aminocellulose (AC) and sodium carboxymethylcellulose (NaCMC) coated on magnetite NP (MNP, Fe3O4) and complete organic nanocarrier systems (starch and cellulose) that have no MNP part were compared for the PLE and SPR efficiencies for chlorpyrifos (ChP) insecticide. Overall, all nanocarriers (NCs) have shown good to excellent PLE due to the smaller sized NP obtained through optimal conditions. However, among the hybrid polysaccharides studied, starch MNP (S-MNP) has shown a maximum PLE of 111 wt% in comparison with other polysaccharides (80 – 94 wt%) as well as with organic-NCs (81 – 87 wt%). The use of inorganic support does improve the PLE greatly for starch but not for cellulose derivatives. Similarly, the SPR results of S-NP showed remarkably better sustained-release-profile for ChP of 88 % in 14 days, whereas other unfunctionalized and functionalized celluloses exhibited poor release profiles of 60 – 20 % for the same period. These results indicate that the superior performance of starch might be due to the beta-1,4- & 1,6-linkages of sugar moieties leading to the branched polymers which bring more room for the pesticide to be entrapped and allow them to release in a sustainable manner. We believe that this study may help the researchers to choose the right system for designing and achieving enhanced pesticide efficiency.

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A Methodical Study to Unravel the Potential of using Polysaccharides based Organic Nanoparticles Versus Hybrid Nanoparticles for Pesticide Delivery

Mahajan¹,

Selim²,

Neethu³

et al. 2021

Preprint

0

View full text Add to dashboard Cite

Conventional pesticide release pollutes the atmosphere and root healthiness threats. To daze its limitations, nanotechnology mediated pesticide delivery using various natural polymers have been actively investigated. However, the lack of information on what are the beneficial/non-beneficial aspects of using hybrid- and organic- nanoparticles (NP) and among the polysaccharides which are better suited concerning pesticide loading efficiency (PLE), entrapment efficiency (E.E), and sustained-pesticide-release (SPR) has prompted us to investigate this study. In this report, we systematically investigate a series of polysaccharides such as starch (S), cellulose (C), aminocellulose (AC) and sodium carboxymethylcellulose (NaCMC) coated on magnetite NP (MNP, Fe3O4) and complete organic nanocarrier systems (starch and cellulose) that have no MNP part were compared for the PLE and SPR efficiencies for chlorpyrifos (ChP) insecticide. Overall, all nanocarriers (NCs) have shown good to excellent PLE due to the smaller sized NP obtained through optimal conditions. However, among the hybrid polysaccharides studied, starch MNP (S-MNP) has shown a maximum PLE of 111 wt% in comparison with other polysaccharides (80 – 94 wt%) as well as with organic-NCs (81 – 87 wt%). The use of inorganic support does improve the PLE greatly for starch but not for cellulose derivatives. Similarly, the SPR results of S-NP showed remarkably better sustained-release-profile for ChP of 88 % in 14 days, whereas other unfunctionalized and functionalized celluloses exhibited poor release profiles of 60 – 20 % for the same period. These results indicate that the superior performance of starch might be due to the beta-1,4- & 1,6-linkages of sugar moieties leading to the branched polymers which bring more room for the pesticide to be entrapped and allow them to release in a sustainable manner. We believe that this study may help the researchers to choose the right system for designing and achieving enhanced pesticide efficiency.

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Polysaccharide - Modified MMT/ Modified MMT/ Polysaccharide – MNP, Lignin - Modified MMT Nanocomposites Verses Polyethyleneimineimine- Modified MMT-: A Comparative Analysis of Sustained Pesticide Delivery

Mahajan¹

2021

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0

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Highlights: • At the nanoscale, the characteristics of a material can alter dramatically. With only a reduction in size and no change to the substance itself, materials can display new qualities. • Polysaccharide-Modified MMT/ Modified MMT/ Polysaccharide – MNP, Lignin-Modified MMT Nanocomposites vs. Polyethyleneimineimine-Modified MMT have been compared for a Sustained Pesticide Delivery in this manuscript. • We anticipate that this description will aid researchers in selecting the best technique for developing pesticides and improving pesticide delivery.

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Ritu Mahajan

A Methodical Study to Unravel the Potential of using Polysaccharides based Organic Nanoparticles Versus Hybrid Nanoparticles for Pesticide Delivery

A Methodical Study to Unravel the Potential of using Polysaccharides based Organic Nanoparticles Versus Hybrid Nanoparticles for Pesticide Delivery

Polysaccharide - Modified MMT/ Modified MMT/ Polysaccharide – MNP, Lignin - Modified MMT Nanocomposites Verses Polyethyleneimineimine- Modified MMT-: A Comparative Analysis of Sustained Pesticide Delivery

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