Effect of pro‐oxidants on biodegradation of polyethylene (LDPE) by indigenous fungal isolate, <i>Aspergillus oryzae</i>

Konduri, Mohan K.R.; Koteswarareddy, G.; Kumar, Devendra; Reddy, B. Venkata; Narasu, M. Lakshmi

doi:10.1002/app.33517

Cited by 47 publications

(20 citation statements)

References 26 publications

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“…Chain scissions may occur due to oxidation by dissolved oxygen in the soil. The carbonyl index decreases after longer exposures, which could be due to the consumption of the carbonyl groups by microorganisms and/or the formation of esters or the occurrence of the Norrish mechanism 32,33 . The presence of carbonyl groups, such as esters, carboxylic acids, aldehydes and ketones, in a degraded polymer may indicate oxidation and that the material is more vulnerable to degradation 34 .…”

Section: Resultsmentioning

confidence: 99%

Behavior in simulated soil of recycled expanded polystyrene/waste cotton composites

et al. 2013

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Composites consisting of waste cotton yarn (CF) from the textile industry and postconsumer expanded polystyrene (EPS) was followed during 90 days of exposure in simulated soil. The mechanical properties, morphologies and chemical natures of the composites were determined before and after exposure in simulated soil. The composites were made using a single-screw extrusion, a twin-screw extrusion and injection molding. The composites showed an increase of the mechanical properties nearly 50% in relation to the recycled expanded polystyrene (rEPS). After exposure in simulated soil the composites presented losses of mechanical properties. Evidence of the oxidation of the samples was demonstrated by the increase in the values of the carbonyl index after 30 days of exposure in simulated soil. Changes in the color of the surface of the sample were observed after 90 days of exposure and are due to the fungi and bacteria colonization on the surface.

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Section: Resultsmentioning

confidence: 99%

Behavior in simulated soil of recycled expanded polystyrene/waste cotton composites

et al. 2013

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“…Our results are in agreement with the previous studies, previously, after 10 days of incubation maximum reduction (60%) in tensile strength (TS) of the heat treated polythene was reported with Mucor rouxii [NRRL 1835] 73 . After three months of testing period maximum reduction in TS (63%) of the polythene was reported with A. oryzae 58 followed by 51% reduction in PE (Mangnease sterate treated LDPE exposed to UV irradiation) with the same fungi ( A. oryzae ) 74 . Vijaya and Reddy 52 followed the ASTM standard and assessed the degradation (by compositing) of polythene (HDPE) along with municipality solid waste and recorded highest 20% reduction in tensile of HDPE after 1 year of testing duration.…”

Section: Discussionmentioning

confidence: 99%

Potential of fungi isolated from the dumping sites mangrove rhizosphere soil to degrade polythene

Sangale

Shahnawaz

Ade

2019

Sci Rep

121

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Polythene is the most widely used plastic around the globe. Among the total plastic waste generated, polythene contributes the maximum share (64%). Various strategies/methods are being utilized to deal with the increasing rate of plastic waste, but among all the methods, bioremediation is regarded as the ecofriendly and widely accepted method. In the current investigation, we have attempted to discover the elite polythene deteriorating fungi (isolated from the rhizosphere soil of Avicennia marina ). From 12 different eco-geographical locations along the West Coast of India, total 109 fungal isolates were recorded. The polythene deteriorating fungi were screened at varied pH (3.5, 7 and 9.5) based on changes in weight and tensile strength of the treated polythene at ambient temperature with continuous shaking for 60 days. BAYF5 isolate (pH 7) results in maximum reduction in weight (58.51 ± 8.14) whereas PNPF15 (pH 3.5) recorded highest reduction in tensile strength (94.44 ± 2.40). Surprisingly, we have also reported weight gain, with highest percent weight gain (28.41 ± 6.99) with MANGF13 at pH 9.5. To test the reproducibility of the results, the elite polythene degrading fungal isolates based on weight loss and reduction in tensile strength were only used for repetition experiment and the results based on the reduction in tensile strength were found only reproducible. Polythene biodegradation was further confirmed using Scanning Electron Microscopy (SEM) and Fourier Transform Infrared Spectroscopy (FTIR) analysis. The most efficient polythene deteriorating fungal isolates were identified as Aspergillus terreus strain MANGF1/WL and Aspergillus sydowii strain PNPF15/TS using both morphological keys and molecular tools.

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“…One of the solutions for these problems is recycling, but it is very costly and moreover, the recycled products have poorer qualities . Natural degradation of these plastics within short and specified life span is one of the alternatives to deal with such issues and becomes the demand of the situation . From last two decades, an increase in the investigations concerning total or partial substitution of synthetic plastics by biodegradable materials, viz.…”

Section: Introductionmentioning

confidence: 99%

Blends of high density polyethylene and poly(l‐lactic acid): Mechanical and thermal properties

Madhu

Bhunia

Bajpai

2013

Polymer Engineering & Sci

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The blends of high‐density polyethylene (HDPE) and poly(l‐lactic acid) (PLLA) were prepared by melt blending method in an extrusion mixer with a postextrusion blown film attachment. The ratios of HDPE/PLLA blends were taken as 100/0, 95/5, 90/10, 85/15, and 80/20. The 80/20 blend was further compatibilized by adding maleic anhydride‐grafted polyethylene in different ratios (up to 8 wt%). Based on the mechanical properties of the films, the compositions HDPE80 (80% HDPE and 20% PLLA) and HD80C4 (80% HDPE, 20% PLLA, and 4% compatibilizer) were found to be optimum and considered for further analysis. The thermal properties of these selected blends were investigated by means of thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC). TGA study revealed that the addition of the PLLA somewhat decreased the thermal stability of HDPE. DSC investigation showed that the blends were partially miscible only. X‐ray diffraction (XRD) analysis enlightened that the crystallinity of blends was slightly increased with addition of PLLA. Immiscibility of the two polymers was diminished in the presence of compatibilizer, as indicated by the scanning electron microscopy (SEM) of the blends. These partially biodegradable blends may be used for flexible packaging applications. POLYM. ENG. SCI., 54:2155–2160, 2014. © 2013 Society of Plastics Engineers

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Effect of pro‐oxidants on biodegradation of polyethylene (LDPE) by indigenous fungal isolate, Aspergillus oryzae

Cited by 47 publications

References 26 publications

Behavior in simulated soil of recycled expanded polystyrene/waste cotton composites

Behavior in simulated soil of recycled expanded polystyrene/waste cotton composites

Potential of fungi isolated from the dumping sites mangrove rhizosphere soil to degrade polythene

Blends of high density polyethylene and poly(l‐lactic acid): Mechanical and thermal properties

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