Bhattacharyya A , Antoney PUH, Reddy R, Omkar AM (2015) Nanotechnology And Butterflies: A Mini Review. Journal of Applied Biosciences 41: 27 - 32. Chandra S, Sukumaran S (2020) Physiological, Biochemical and Neurochemical responses of Cirrhinus mrigala upon short term exposure to Cerium oxide. International Journal of Aquatic Biology 7(6): 368-373. Fleischhaker F, Zentel R (2005) Photonic crystals from core-shell colloids with incorporated highly fluorescent quantum dots. Chemistry of Materials 17(6): 1346-1351. Gan Z, Turner MD, Gu M (2016) Biomimetic gyroid nanostructures exceeding their natural origins. Science Advances 2(5): e1600084. Garrett NL, Sekine R, Dixon MW, Tilley L, Bambery KR, Wood BR (2015) Bio-sensing with butterfly wings: naturally occurring nano-structures for SERS-based malaria parasite detection. Physical Chemistry Chemical Physics 17(33): 21164-21168. Han J, Su H, Zhang D, Chen J, Chen Z (2009) Butterfly wings as natural photonic crystal scaffolds for controllable assembly of CdS nanoparticles. Journal of Materials Chemistry 19(46): 8741-8746. Joung YH (2013) Development of implantable medical devices: from an engineering perspective. International Neurourology Journal 17(3): 98. Kovac M (2016) Learning from nature how to land aerial robots. Science 352(6288): 895-896. Kumar V, Michael, N (2012) Opportunities and challenges with autonomous micro aerial vehicles. The International Journal of Robotics Research 31(11): 1279-1291. Lee JO, Park H, Du J, Balakrishna A, Chen O, Sretavan D, Choo H (2017) A microscale optical implant for continuous in vivo monitoring of intraocular pressure. Microsystems & Nanoengineering 3(1):1-9. Lei R, Zhai H, Nie J, Zhong W, Bai Y, Liang X, Wang, Z. L (2019) Butterfly?Inspired Triboelectric Nanogenerators with Spring?Assisted Linkage Structure for Water Wave Energy Harvesting. Advanced Materials Technologies 4(3): 1-12. Li L, Connors MJ, Kolle M, England GT, Speiser DI, Xiao X, Ortiz C (2015) Multifunctionality of chiton biomineralized armor with an integrated visual system. Science 350(6263): 952-956. Li Q, Zeng Q, Shi L, Zhang X, Zhang KQ (2016) Bio-inspired sensors based on photonic structures of Morpho butterfly wings: a review. Journal of Materials Chemistry C 4(9): 1752-1763. Mille C, Tyrode EC, Corkery RW (2011) Inorganic chiral 3-D photonic crystals with bicontinuous gyroid structure replicated from butterfly wing scales. Chemical Communications 47(35): 9873-9875. Narasimhan V, Siddique RH, Lee JO, Kumar S, Ndjamen B, Du J, Choo H (2018) Multifunctional biophotonic nanostructures inspired by the longtail glasswing butterfly for medical devices. Nature nanotechnology 13(6): 512-519. Ortega Ancel A, Eastwood R, Vogt D, Ithier C, Smith M, Wood R, Kova? M (2017) Aerodynamic evaluation of wing shape and wing orientation in four butterfly species using numerical simulations and a low-speed wind tunnel, and its implications for the design of flying micro-robots. Interface focus 7(1):1-13. Perva S, Swamy K, Chandrashekar N, Subramanian R, Sukumaran, S, Chandra SP, S (2020) Physio-biochemical responses of Indian major carp Catla catla upon sub-chronic exposure to tin oxide nanoparticles. Egyptian Journal of Aquatic Biology and Fisheries 24(4): 509-520. Prum RO, Quinn T, Torres RH (2006) Anatomically diverse butterfly scales all produce structural colours by coherent scattering. Journal of Experimental Biology 209(4): 748-765. Puneeth HR, Chandra SSP (2020) A review on potential therapeutic properties of Pomegranate (Punica granatum L.). Plant Science Today 7(1): 9-16. Ranjitha T, Sharath Chandra SP (2020) Biological and ecological impact of iron and iron nanoparticles across diverse array of fish models: a review. Ecology, Environment and Conservation 26 (1):180-184. Rashmi N, Ranjitha T, Sharath Chandra SP (2019) Chromium and their Derivatives Causes Physiological and Biochemical Modifications in Diverse Fish Models: A Review. Biomedical and Pharmacology journal 12(4): 2049-2053. Saba M, Wilts BD, Hielscher J, Schröder-Turk GE (2014) Absence of circular polarisation in reflections of butterfly wing scales with chiral gyroid structure. Materials Today: Proceedings 1: 193-208. Saranathan V, Osuji CO, Mochrie SG, Noh H, Narayanan S, Sandy A, Prum RO (2010) Structure, function, and self-assembly of single network gyroid (I4132) photonic crystals in butterfly wing scales. Proceedings of the National Academy of Sciences 107(26): 11676-11681. Sharath Chandra SP, Sukumaran S (2020) Magnesium chloride impairs physio-biochemical and neurochemical responses in cirrhinus mrigala (Hamilton, 1822) upon short term exposure. Biointerface Research in Applied Chemistry 10(1): 4934-4938. Siddique RH, Gomard G, Hölscher H (2015) The role of random nanostructures for the omnidirectional anti-reflection properties of the glasswing butterfly. Nature Communications 6(1): 1-8. Wanasekara ND, Chalivendra VB (2011) Role of surface roughness on wettability and coefficient of restitution in butterfly wings. Soft Matter 7(2):373-379. Wilts BD, Zubiri BA, Klatt MA, Butz B, Fischer MG, Kelly ST, Schröder-Turk GE (2017) Butterfly gyroid nanostructures as a time-frozen glimpse of intracellular membrane development. Science advances 3(4): e1603119. Zhang W, Zhang D, Fan T, Ding J, Gu J, Guo, Q, Ogawa H (2006) Biomimetic zinc oxide replica with structural color using butterfly (Ideopsis similis) wings as templates. Bioinspiration & Biomimetics 1(3):89. |