The mineralized cuticle of the mantis shrimps Squilla Mantis which serve as natural hammers, spears and armors, have attracted research attention from various fields due to its amazing mechanical properties which were studied from evolutionary and ecological points of view. Here we aimed to valorize the astonishing mantis shrimp shell waste resulted from fishery and seafood industry as valuable biogenic composite derived from nature, potentially re-usable for novel, smart materials or added-value by-products, aspect which was not deeply considered before. Employing multi-laser Raman spectroscopy and imaging, supported by x-ray diffraction and high-resolution electron microscopy, we discover that the peripheral segments anatomically known as claws and telson, featured completely different composition and morphology, suggesting different applicability. The claw presents a bulk Mg-CaCO3 structure reinforced with fluorapatite coating, while the carotenoid-rich telson presents a porous and anisotropic structure of an amorphous mixture of CaCO3 and CaPO4 in gradient deposition on the chitin-protein scaffold. Resonance Raman spectroscopy showed concentrated pools of astaxanthin carotenoid within the bright red spots visible on telson, Based on our findings, we discuss this material's potential for selective applicability, as a natural source of phosphate-carbonate minerals, antioxidants, biofertilizer, pollutant adsorbent, valuable material for regenerative medicine or even as a cell culture substrate. Knowledge-based approach on this bio-template is the basis for smart recycling of such fishery waste for sustainable development, by opening channels for blue bioeconomy avenue.
Keywords: Astaxanthin; Biogenic waste; Blue bioeconomy; Mantis shrimp; Porous biocomposite; Raman spectroscopy; SEM-EDX; XRD.
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