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20 resultsShowing papers similar to Biodegradation of Polystyrene by Tenebrio molitor, Galleria mellonella, and Zophobas atratus Larvae and Comparison of Their Degradation Effects
ClearBiodegradation of Polystyrene by Plastic-Eating Tenebrionidae Larvae
Researchers tested the ability of mealworm (Tenebrio molitor) and superworm (Zophobas morio) larvae to biodegrade polystyrene foam through feeding experiments with different dietary conditions. They found that both species could consume and break down polystyrene, with gut microorganisms playing a key role in the degradation process. The study suggests that insect-based biodegradation could offer a biological approach to addressing polystyrene waste in the environment.
Biodegradation of Polystyrene by Plastic-Eating Tenebrionidae Larvae
Researchers examined the biodegradation of polystyrene by Tenebrionidae beetle larvae, testing the ability of plastic-eating mealworm larvae to break down the highly stable, hydrophobic polymer. The study characterized polymer molecular weight changes, gut microbiome contributions, and metabolic byproducts, demonstrating that larval gut bacteria play a key role in PS depolymerization.
Biodegradation of polystyrene microplastics by superworms (larve of Zophobas atratus): Gut microbiota transition, and putative metabolic ways
Researchers fed polystyrene microplastics to superworms (Zophobas atratus larvae) and found reduced survival and weight, along with major shifts in gut microbial communities including an increase in Hafnia-Obesumbacterium. Metabolomic analysis identified three metabolic pathways through which superworm gut microbes break down polystyrene.
Optimizing polystyrene degradation, microbial community and metabolite analysis of intestinal flora of yellow mealworms, Tenebrio molitor.
Yellow mealworm larvae fed only expanded polystyrene were found to biodegrade the plastic, with the efficiency depending on temperature and humidity conditions. The gut microbiome of the larvae played a key role, and researchers identified metabolic pathways involved in polystyrene breakdown, advancing understanding of insect-based plastic biodegradation.
Biodegradation of Different Types of Plastics by Tenebrio molitor Insect
This study reviewed the potential of mealworm beetle larvae (Tenebrio molitor) to biodegrade multiple plastic types through gut microbiota activity, finding that the larvae could break down various polymers including polystyrene and polyethylene, making entomoremediation a promising avenue for plastic waste reduction.
Comparison of three insect larvae biodegrading polyethylene and role of the intestinal bacterial strains in polyethylene degradation by Galleria mellonella larvae
Compared to two other insect species, Galleria mellonella waxworm larvae showed the highest polyethylene degradation ability, with gut bacterial strains identified as key contributors to plastic breakdown in a process transferable outside the host.
Gut Microbiome and Degradation Product Formation during Biodegradation of Expanded Polystyrene by Mealworm Larvae under Different Feeding Strategies
Researchers found that mealworm larvae successfully degrade polystyrene under different feeding strategies, with gut microbiome composition and degradation byproduct profiles varying by diet, demonstrating that diet manipulation can optimize the biological plastic-degradation capacity of the mealworm system.
Biodegradation of Expanded and Extruded Polystyrene with Different Diets by Using Zophobas atratus Larvae (Coleoptera: Tenebrionidae)
Zophobas atratus larvae (superworms) biodegraded both expanded and extruded polystyrene, with supplement diets of oatmeal, wheat bran, and cornmeal significantly enhancing consumption and degradation rates, and gel permeation chromatography confirming significant molecular weight reduction of the polystyrene.
Complete digestion/biodegradation of polystyrene microplastics by greater wax moth (Galleria mellonella) larvae: Direct in vivo evidence, gut microbiota independence, and potential metabolic pathways
Researchers provided direct in vivo evidence that greater wax moth larvae can completely digest polystyrene microplastics, demonstrating that biodegradation occurs independently of gut microbiota and identifying potential metabolic pathways involved in the breakdown process.
Plastic Biodegradation through Insects and their Symbionts Microbes: A Review
This review examines how insects and their gut microbes can break down plastic waste, covering species like mealworms and waxworms that can digest polyethylene and polystyrene. The bacteria living in insect guts are responsible for much of this plastic-degrading activity. Insect-based biodegradation could offer a scalable biological solution to reducing plastic pollution.
Influence of Polymer Size on Polystyrene Biodegradation in Mealworms (Tenebrio molitor): Responses of Depolymerization Pattern, Gut Microbiome, and Metabolome to Polymers with Low to Ultrahigh Molecular Weight
Mealworms fed polystyrene microplastics of varying molecular weights (low to ultrahigh) over 24 days showed significant differences in biodegradation rate, gut microbiome composition, and metabolic profiles. Lower molecular weight polystyrene was biodegraded more efficiently, suggesting that polymer molecular weight is a key factor in insect-mediated plastic degradation.
Mechanisms and Perspectives of Microplastic Biodegradation by Insects and Their Associated Microorganisms
This review examined how insects and their gut microbiota contribute to microplastic biodegradation, summarizing known degradation mechanisms and the microorganisms involved. The authors found that several insect species harbor gut bacteria capable of depolymerizing common plastics like polystyrene and polyethylene, though degradation rates remain too slow for practical remediation at scale.
Tenebrio molitor: possible source of polystyrene-degrading bacteria
Researchers identified that Klebsiella oxytoca bacteria, found in the gut of mealworm beetles (Tenebrio molitor), may be key players in breaking down polystyrene plastic, pointing to insects as a potential source of microbe-based plastic biodegradation solutions.
Plastic biodegradation by in vitro environmental microorganisms and in vivo gut microorganisms of insects
Researchers reviewed seven years of studies on plastic biodegradation by environmental microorganisms and insect gut microbes. The study found that while microbial degradation in environmental conditions is extremely slow, certain insects can biodegrade plastics like polystyrene and polyethylene at much faster rates, likely through gut microbe-dependent processes.
Generation and Fate of Nanoplastics in the Intestine of Plastic-Degrading Insect (Tenebrio molitor Larvae) during Polystyrene Microplastic Biodegradation
Researchers tracked what happens to nanoplastics inside mealworm larvae as they digest polystyrene microplastics. They found that nanoplastics were generated during digestion and initially accumulated in gut tissues and glands, but concentrations declined over four weeks and eventually fell below detection limits, suggesting the larvae and their gut microbes can work together to break down even these tiny plastic particles.
Isolation of Plastic Digesting Microbes from the Gastrointestinal Tract of Tenebrio Molitor
Researchers isolated bacteria from the gut of Tenebrio molitor mealworm larvae that are capable of degrading polystyrene and polyethylene microplastics. The identified gut microbes showed plastic-degrading enzymatic activity, suggesting potential for bioremediation applications.
The interplay of larval age and particle size regulates micro-polystyrene biodegradation and development of Tenebrio molitor L.
Researchers found that three-month-old mealworm larvae are optimal for polystyrene microplastic biodegradation, showing the highest consumption rates and confirmed depolymerization in their frass, with comparable survival to control groups when co-fed with wheat bran.
Biodegradation of aged polyethylene (PE) and polystyrene (PS) microplastics by yellow mealworms (Tenebrio molitor larvae)
Yellow mealworm larvae were able to consume and biodegrade both fresh and aged polyethylene film and polystyrene foam over a 35-day period. While aged plastics slightly slowed larval growth, the worms still broke down the plastic with help from their gut bacteria, confirmed by chemical analysis showing structural changes in the consumed plastic. This biological approach to plastic degradation could help reduce the amount of plastic waste that eventually breaks down into microplastics in the environment.
Understanding the Ecological Robustness and Adaptability of the Gut Microbiome in Plastic-Degrading Superworms (Zophobas atratus) in Response to Microplastics and Antibiotics
Researchers studied superworms (Zophobas atratus larvae) that can eat and break down five major types of plastic, including polyethylene, polypropylene, and polystyrene. They found that the gut microbiome of these insects adapted to digest different plastics even when challenged with antibiotics, suggesting the larvae and their gut bacteria work together in a robust system that could inform future plastic biodegradation strategies.
BIODEGRADATION OF POLYSTYRENE BY PLASTIVORES GREATER WAXWORMS LARVAE (Galleria mellonella).
Researchers investigated the biodegradation of polystyrene by Greater Waxworm larvae (Galleria mellonella), using weight loss measurements, morphology analysis, and FTIR spectroscopy to confirm that the larvae could consume and chemically alter polystyrene whose structure resembles beeswax. The findings identify Galleria mellonella as a promising biological agent for reducing polystyrene accumulation in the environment.