AIMC Topic: Crustacea

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Assessing the effects of a 660 nm diode laser on crustacean eyes.

PloS one May 6, 2025
Sustainable management of crustacean fisheries requires accurate and timely data for population modelling, but many stocks are data deficient. To address this challenge, a novel device using Class 3R 660 nm diode lasers and Artificial Intelligence al...
Animals Lasers, Semiconductor Penaeidae Crustacea Eye
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Molecular phylogenetic investigations of Triops granarius (Lucas, 1864 (Branchiopoda: Notostraca) from the type locality of the former Apus orientalis Tiwari, 1952 and three other localities in the Western Ghats of India.

Zootaxa Dec 14, 2018
We investigated the phylogenetic position of Triops granarius populations from four localities in the Western Ghats using partial sequences of three mitochondrial genes (COI, 12S rRNA and 16S rRNA) publicly available on the GenBank database. One of t...
Animals Phylogeny India RNA, Ribosomal, 16S DNA Barcoding, Taxonomic Crustacea
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Modeling and optimization of Newfoundland shrimp waste hydrolysis for microbial growth using response surface methodology and artificial neural networks.

Marine pollution bulletin Jun 14, 2016
The hydrolyzed protein derived from seafood waste is regarded as a premium and low-cost nitrogen source for microbial growth. In this study, optimization of enzymatic shrimp waste hydrolyzing process was investigated. The degree of hydrolysis (DH) wi...
Neural Networks, Computer Temperature Animals Hydrolysis Waste Products Crustacea Food-Processing Industry Newfoundland and Labrador
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A network model comprising 4 segmental, interconnected ganglia, and its application to simulate multi-legged locomotion in crustaceans.

Journal of computational neuroscience Apr 23, 2015
Inter-segmental coordination is crucial for the locomotion of animals. Arthropods show high variability of leg numbers, from 6 in insects up to 750 legs in millipedes. Despite this fact, the anatomical and functional organization of their nervous sys...
Neural Networks, Computer Computer Simulation Animals Models, Neurological Walking Insecta Synapses Sensation Locomotion Crustacea Neural Pathways Feedback, Physiological Central Pattern Generators Ganglia, Invertebrate
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Exploring the purity of chitin from crustacean sources using deep eutectic solvents: A machine learning approach.

Journal of applied biomaterials & functional materials Jan 1, 2024
OBJECTIVE: Chitin a natural polymer is abundant in several sources such as shells of crustaceans, mollusks, insects, and fungi. Several possible attempts have been made to recover chitin because of its importance in biomedical applications in various...
Machine Learning Animals Crustacea Deep Eutectic Solvents Animal Shells Chitin
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