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Scutoid
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A scutoid is a particular type of geometric solid between two parallel surfaces. The boundary of each of the surfaces (and of all the other parallel surfaces between them) either is a polygon or resembles a polygon, but is not necessarily planar, and the vertices of the two end polygons are joined by either a curve or a Y-shaped connection on at least one of the edges, but not necessarily all of the edges. Scutoids present at least one vertex between these two planes. Scutoids are not necessarily convex, and lateral faces are not necessarily planar, so several scutoids can pack together to fill all the space between the two parallel surfaces. They may be more generally described as a mix between a frustum and a prismatoid.[1][2]
Naming
[edit]The object was first described by Gómez-Gálvez et al. in a paper entitled Scutoids are a geometrical solution to three-dimensional packing of epithelia, and published in July 2018.[1] Officially, the name scutoid was coined because of its resemblance to the shape of the scutum and scutellum in some insects, such as beetles in the subfamily Cetoniinae.[1] Unofficially, Clara Grima has stated that while working on the project, the shape was temporarily called an Escu-toid as a joke after the biology group leader Luis M. Escudero.[3][4] Since his last name, "Escudero", means "squire" (from Latin scutarius = shield-bearer), the temporary name was modified slightly to become "scutoid".
Appearance in nature
[edit]"The shape, however odd, is a building block of multicellular organisms; complex life might never have emerged on Earth without it."
Alan Burdick, We Are All Scutoids: A Brand New Shape, Explained[2]
Epithelial cells adopt the "scutoidal shape" under certain circumstances.[1] In epithelia, cells can 3D-pack as scutoids, facilitating tissue curvature. This is fundamental to the shaping of the organs during development.[1][5][6]
"Scutoid is a prismatoid to which one extra mid-level vertex has been added. This extra vertex forces some of the "faces" of the resulting object to curve. This means that Scutoids are not polyhedra, because not all of their faces are planar. ... For the computational biologists who created/discovered the Scutoid, the key property of the shape is that it can combine with itself and other geometric objects like frustums to create 3D packings of epithelial cells."
- Laura Taalman[7][8]
Scutellum on heteropteran (no. 26)
A beetle with a scutellum, for which the shape was officially named.
Cells in the developing lung epithelium have been found to have more complex shapes than the term "scutoid", inspired by the simple scutellum of beetles, suggests.[9] When "scutoids" exhibit multiple Y-shaped connections or vertices along their axis, they have therefore been called "punakoids" instead,[10] as their shape is more reminiscent of the Pancake Rocks in Punakaiki, New Zealand.
Potential uses
[edit]The scutoid explains how epithelial cells (the cells that line and protect organs such as the skin) efficiently pack in three dimensions.[1] As epithelial tissue bends or grows, the cells have to take on new shapes to pack together using the least amount of energy possible, and until the scutoid's discovery, it was assumed that epithelial cells packed in mostly frustums, as well as other prism-like shapes. Now, with the knowledge of how epithelial cells pack, it opens up many new possibilities in terms of artificial organs. The scutoid may be applied to making better artificial organs, allowing for things like effective organ replacements, recognizing whether a person's cells are packing correctly or not, and ways to fix that problem.[3]
References
[edit]- ^ a b c d e f Gómez-Gálvez, Pedro; Vicente-Munuera, Pablo; Tagua, Antonio; Forja, Cristina; Castro, Ana M.; Letrán, Marta; Valencia-Expósito, Andrea; Grima, Clara; Bermúdez-Gallardo, Marina (27 July 2018). "Scutoids are a geometrical solution to three-dimensional packing of epithelia". Nature Communications. 9 (1): 2960. Bibcode:2018NatCo...9.2960G. doi:10.1038/s41467-018-05376-1. ISSN 2041-1723. PMC 6063940. PMID 30054479.
- ^ a b Burdick, Alan (30 July 2018). "We Are All Scutoids: A Brand-New Shape, Explained". The New Yorker. Retrieved 27 November 2024.
- ^ a b Parker 2018.
- ^ "Supplementary Movie". static-content.springer.com. from Gómez-Gálvez et al. 2018, Electronic supplementary material. Retrieved 27 November 2024.
- ^ Boddy, Jessica (27 July 2018). "The 'Scutoid' Is Geometry's Newest Shape, and It Could Be All Over Your Body". Gizmodo. Retrieved 27 November 2024.
- ^ Georgiou, Aristos (27 July 2018). "Scientists have discovered a brand-new three-dimensional shape". Newsweek. Retrieved 27 November 2024.
- ^ Taalman, Laura [@mathgrrl] (28 July 2018). "Have you read the @Nature article introducing the new mathematical shape called the SCUTOID? This cutting-edge science is now 3D printable: https://www.thingiverse.com/thing:3024272" (Tweet). Retrieved 27 November 2024 – via Twitter.
- ^ Taalman, Laura (29 July 2018). "Pair of Packable Scutoids". mathgrrl.com. Retrieved 27 November 2024.
- ^ Gómez, Harold F.; Dumond, Mathilde; Hodel, Leonie; Vetter, Roman; Iber, Dagmar (5 October 2021). "3D cell neighbour dynamics in growing pseudostratified epithelia". eLife. 10 e68135. doi:10.7554/eLife.68135. PMC 8570695. PMID 34609280.
- ^ Iber, Dagmar; Vetter, Roman (12 May 2022). "3D Organisation of Cells in Pseudostratified Epithelia". Frontiers in Physics. 10 898160. Bibcode:2022FrP....10.8160I. doi:10.3389/fphy.2022.898160. hdl:20.500.11850/547113.
External links
[edit]- Parker, Matt (3 August 2018). "The scutoid: did scientists discover a new shape?". youtube.com. Stand-up Maths. Retrieved 27 November 2024.
- M, Katie (2018). "Model of a scutoid". youtube.com. according to Burdick 2018, this video was the first one online after the publication of the original paper (Gómez-Gálvez et al. 2018). Retrieved 27 November 2024.
Scutoid
View on Grokipediafrom Grokipedia
A scutoid is a geometric solid with at least one vertex offset from the parallel basal and apical surfaces, featuring non-convex, often curved boundaries that facilitate efficient three-dimensional packing of cells between curved tissue layers.[1] This shape, distinct from prisms or frustums due to its twisted structure resembling the scutellum (thorax shield) of certain insects like Cetoniidae beetles, was first identified in 2018 through computational modeling and 3D imaging of epithelial tissues in Drosophila melanogaster.[1] Scutoids enable epithelial cells to maintain stable junctions and minimize energy in non-flat configurations, such as tubes or spheroids, where traditional columnar shapes would lead to gaps or overlaps.[1]
In biological contexts, scutoids predominate in curved epithelia, comprising up to 75% of cells in Drosophila salivary glands and 20% in early egg chambers, with their prevalence increasing in tissues where the basal-to-apical surface area ratio exceeds 1, such as 1.6 in embryo folds or 7 in salivary glands.[1] Recent studies have expanded this understanding, revealing that scutoids emerge dynamically during tissue proliferation and compaction, as observed in sea star (Patiria miniata) embryos where cell density increases trigger rapid scutoid adoption—over 60% within 15% of the interphase following division—to reorganize 3D packing without disrupting epithelial integrity.[2] This process highlights scutoids' role not only in static curvature but also in active morphogenesis driven by local and global density changes.[2]
The discovery of scutoids has implications for developmental biology and bioengineering, as their geometry could inform the design of artificial tissues and organoids by optimizing cell arrangement in 3D scaffolds to mimic natural folding and stability. Recent work has also explored scutoid geometries in designing topologically interlocking materials for engineering applications.[1][3] Mathematically, scutoids can be modeled using Voronoi tessellations on cylindrical coordinates, underscoring their emergence as a solution to packing problems in non-Euclidean spaces.[1] Ongoing research continues to explore their prevalence across species and potential applications in regenerative medicine.[2]
Geometry
Definition
A scutoid is a geometric solid with two parallel polygonal bases of potentially different numbers of sides (n and m), connected by non-planar lateral faces, with at least one vertex offset from the base planes, introducing a characteristic "twist."[1] According to the original description, a scutoid is characterized by at least one vertex lying in a plane different from that of its two main surfaces (basal and apical), with non-planar, often concave lateral faces.[1] This structure distinguishes the scutoid from standard prisms or frusta by allowing topological changes such as a transition in the number of sides between bases, such as from a hexagon to a heptagon, while maintaining parallelism between the bases.[1] Visually, the scutoid resembles a bent prism or an intermediate form between a cube and a twisted pyramid, enabling efficient non-layered three-dimensional packing without requiring stacked layers.[1] The key structural elements include the parallel bases and lateral surfaces comprising triangular and quadrilateral faces (with at least one triangular face), which contribute to potential chirality in specific configurations by imparting a directional asymmetry to the twist.[1][3] The scutoid's geometry is parameterized through its vertices, edges, and faces, satisfying Euler's formula for polyhedra, .[1] This formulation captures the shape's topological properties, emphasizing the additional complexity introduced by the offset vertices and the twisting lateral connections.[1] Such packing efficiency is particularly relevant in modeling epithelial cell arrangements.[1]Mathematical Properties
Scutoids facilitate efficient three-dimensional packing in curved spaces by minimizing the free energy associated with surface tension, outperforming prismatic configurations in biophysical models of epithelial sheets. In Voronoi-based simulations of cylindrical geometries, the adoption of scutoid shapes increases with the ratio of basal to apical surface areas (), achieving complete scutoid packing at , which corresponds to lower overall line-tension energy compared to prism-like alternatives.[1] This efficiency arises from the scutoid's ability to accommodate apico-basal intercalations, reducing the energetic cost of bending without requiring cell rearrangements.[1] The stability of scutoid lattices is governed by line-tension minimization, where the shape transitions between prismatic and scutoid forms occur at critical aspect ratios of (approximately 0.577) and (approximately 1.732), as derived from the energy functional for cell boundaries. The functional for the dimensionless energy in a simplified model is expressed as: where represents the normalized length of the horizontal boundary segment, and similar forms apply for vertical transitions; minimization yields stable scutoid equilibria with reduced energy.[1] Triangular lateral faces in scutoid geometries contribute to rigidity, enhancing resistance to collapse in three-dimensional assemblies.[1] Furthermore, topological interlocking emerges from the offset vertices and non-planar faces, forming self-stabilizing structures where individual scutoids cannot be extracted without lattice deformation, as demonstrated in finite-element analyses of assemblies.[3] Scutoids exhibit chirality in certain configurations, such as pentagonal and hexagonal variants, due to the inherent twist that lacks mirror symmetry, resulting in left- and right-handed enantiomers.[3] Unlike Platonic solids, scutoids possess no full rotational symmetry, though some possess reflectional symmetry across specific planes (e.g., the xz-plane for hexagonal scutoids).[3] For base polygons with and sides where , the lateral faces transition via a combination of trapezoidal and triangular elements, enabling seamless packing.[1] Comparative simulations indicate that scutoids prioritize structural integrity over uniform faceting in curved packing scenarios.[1]Discovery
Research Process
The research on scutoids originated from efforts to understand the three-dimensional packing of epithelial cells in curved biological tissues, such as during skin folding or organ development, where traditional models like prismatic or frustum shapes failed to adequately explain efficient packing without excessive energy costs.[1] Researchers sought to model cell shapes beyond simple columnar forms using computational simulations, motivated by the need to elucidate morphogenetic processes and advance tissue engineering applications.[1] The investigation employed computational modeling based on Voronoi diagrams to simulate epithelial tissues in both tubular and spheroidal geometries, incorporating biophysical principles like line-tension minimization to predict stable cell configurations under varying curvature and aspect ratios.[1] These in silico models were complemented by experimental analysis of real tissues, including confocal microscopy of Drosophila salivary glands, embryos, egg chambers, and Zebrafish epithelia at epiboly stages, with 3D reconstructions generated using immunohistochemistry markers such as sqh-GFP and phalloidin staining to visualize cell junctions and apical-basal polarity.[1] Key findings revealed twisted, non-prismatic cell shapes—later termed scutoids—that emerged in simulations during apical-basal intercalations to minimize tissue energy, particularly in regions of high curvature defined by surface ratios (R_b/R_a) exceeding 1.5, where up to 100% of cells adopted such forms in extreme cases.[1] Confirmation in biological samples showed scutoid-like cells comprising 10-20% in moderately curved Drosophila egg chambers and up to 75% in highly curved salivary glands, demonstrating their prevalence during tissue bending across species.[1] These results were initially published on July 27, 2018, in Nature Communications, where the authors proposed scutoids as a geometrical solution to the challenges of 3D epithelial packing.[1]Naming
The term "scutoid" was coined by a team of researchers from the University of Seville and Lehigh University to describe a novel geometric solid, deriving its name from the Latin word scutum, meaning "shield," combined with the suffix "-oid," which indicates a shape resembling the root term. This etymology draws inspiration from the shield-like scutum and scutellum structures found in the thoraces of certain insects, such as beetles in the family Cetoniidae, due to the scutoid's visual resemblance to these protective, curved features in a dorsal view.[1][4] This choice reflects a deliberate effort to highlight the form's functional analogy in natural systems rather than a purely abstract geometric descriptor.[5][6] The name first appeared in a 2018 paper published in Nature Communications, where it was introduced without any prior mathematical or geometric precedent, distinguishing the scutoid from established polyhedra.[1]Biological Significance
Role in Epithelial Tissues
Scutoids facilitate efficient packing in epithelial tissues through apico-basal intercalation, a process in which cells rearrange by shifting their positions along the apico-basal axis to form non-columnar structures that accommodate tissue curvature.[1] This intercalation allows epithelial sheets to bend without requiring planar neighbor exchanges, thereby reducing shear stress that would otherwise arise from columnar arrangements in deformable tissues.[1] The resulting scutoid shapes, characterized by a twisted prism-like geometry with at least one vertex offset between apical and basal surfaces, enable cells to maintain contact with different neighbors at the tissue's top and bottom layers.[1] Biophysical models demonstrate that scutoids contribute to energy minimization in epithelial packing by optimizing line tension along cell interfaces, leading to lower total surface energy compared to prismatic cell configurations.[1] This process involves actin-myosin contractility, which generates the tensile forces necessary for cells to adopt and stabilize the scutoid form during tissue remodeling.[1] Specifically, in Voronoi-based simulations of epithelial monolayers, scutoid transitions occur when the aspect ratio of the tissue exceeds critical thresholds (approximately ε > √3), favoring configurations that reduce overall interfacial energy.[1] By promoting seamless curvature, scutoids ensure tissue integrity during organ formation, preventing gaps or overlaps that could compromise barrier function in epithelia.[1] The triangular faces of scutoids play a key role in this by facilitating neighbor exchanges in four-cell motifs, where short edges (angles <30°) allow vertices to shift along the apico-basal axis without disrupting adjacency.[1] This mechanism supports stable three-dimensional packing under mechanical deformation. The adoption of scutoid shapes is triggered by mechanical cues such as changes in cell density or external pressure, which increase the energetic favorability of intercalation.[7] Tissue compaction, often resulting from proliferation, heightens these cues and elevates the probability of scutoid formation, particularly immediately post-mitosis when cells experience localized compression from neighbors.[7]Observations in Nature
Scutoids were first empirically identified in 2018 through high-resolution 3D imaging of epithelial tissues in the fruit fly Drosophila melanogaster. In the curved regions of Drosophila larval salivary glands and developing egg chambers, scutoid-shaped cells constituted up to 20% of the packing cells, with higher proportions—reaching 75%—observed in highly curved structures like the salivary gland epithelium. These findings highlighted scutoids as a common adaptation in bent epithelia, enabling efficient cell packing without disrupting tissue integrity.[1] In vertebrate systems, scutoid-like structures have been documented in epithelial tissues during embryogenesis, including model organisms that inform human development. For instance, 3D reconstructions of zebrafish embryonic epithelia at the 50% epiboly stage revealed scutoids comprising about 3% of cells in curved domains, supporting their role in early tissue folding.[1] Among other invertebrates, scutoids have been observed in sea star (Patiria miniata) embryos, as detailed in a 2024 investigation using live-cell imaging. In these embryos, scutoid adoption increased significantly immediately following cell division, particularly under compressive pressure from tissue compaction, with over 60% of scutoids forming within 15% of interphase in compacted gastrulating regions to accommodate local curvature changes.[7] This dynamic shift underscores scutoids' prevalence in pressure-induced epithelial rearrangements during development. A 2025 study further identified scutoids during epithelial stratification in models, indicating their role in layering beyond simple curvature.[8] Scutoids are notably absent from flat monolayers where uniform prismatic cell shapes suffice for packing. This distribution emphasizes their specialization for three-dimensional tissue sculpting in diverse species.[1]Applications and Developments
Biomedical Implications
The discovery of scutoids has significant implications for tissue engineering, particularly in designing three-dimensional organoids that more accurately replicate the curved architecture of natural epithelial tissues. Traditional organoid models often fail to account for the complex 3D packing required in bent epithelia, leading to unrealistic representations; incorporating scutoid geometries could enhance the fidelity of these models, enabling better simulation of tissue folding during organ development.[1] This advancement supports regenerative medicine by improving scaffolds that promote native-like tissue formation and repair of damaged epithelia.[9] In the context of cancer research, scutoid-informed organoids provide superior platforms for studying metastasis, where disruptions in epithelial packing allow tumor cells to invade surrounding tissues. By mimicking the topological changes observed in pathological states, such as altered scutoid distributions in unhealthy cells, these models facilitate analysis of how curvature influences cell behavior and invasion dynamics.[1][9] Scutoids play a key role in developmental biology, enabling efficient 3D packing during embryogenesis in curved tissues like Drosophila salivary glands and egg chambers.[1] Recent 2024 research demonstrates that scutoid formation in sea star embryos is induced by mechanical compression and increased cell density during tissue compaction, appearing primarily post-cell division to accommodate proliferative stresses.[10]Engineering and Materials Science
In engineering and materials science, the scutoid geometry has been adapted for topological interlocking systems, where scutoid-shaped blocks serve as building units in self-assembling materials. A 2024 study demonstrated that scutoid assemblies, particularly those based on pentagonal or hexagonal bases, outperform traditional polyhedral structures like tetrahedra in stiffness, strength, and toughness under transverse loading, especially at higher friction coefficients (μ = 1.2), without requiring adhesives for cohesion.[3] These systems leverage the scutoid's lateral vertices for geometric interlocking, enabling periodic tessellations such as Cairo or hextile patterns that distribute loads more evenly across the structure.[3] Architectural prototypes have explored scutoid bricks for constructing curved masonry shells, capitalizing on the shape's twisted topology to achieve flexibility and stability in doubly curved facades. In a 2020 design investigation, scutoid-inspired bricks with layered configurations (e.g., hexagon-diamond-diamond) were assembled into physical models that supported significant payloads, such as a 40-pound load, while finite element simulations revealed even stress distribution and reduced localized deformation compared to conventional non-masonry shells.[11] This approach enhances the viability of lightweight, adaptive armor or facade systems by improving overall structural resilience through bio-inspired packing.[11] Manufacturing of scutoid units primarily relies on 3D printing techniques using polymers, facilitating precise replication of the complex geometry for scalable production. Prototypes have been fabricated via PolyJet printing with VeroWhite+ resin for interlocking assemblies and fused deposition modeling with polylactic acid (PLA) at 20% infill for architectural bricks, allowing integration into foams or composites suitable for demanding applications like aerospace components.[3][11] These methods support modular assembly and customization, with robotic extrusion systems enabling larger-scale fabrication of bio-inspired elements.[12] Looking ahead, scutoid geometry holds potential for integration in robotics, particularly for adaptive surfaces in autonomous assembly tasks, as evidenced by 2025 research on Voronoi-based interlocking components inspired by scutoids for constructing resilient habitats.[13] Ongoing efforts in bio-inspired metamaterials continue to investigate these structures for enhanced load-bearing and dynamic response properties in engineering contexts.References
- https://en.wiktionary.org/wiki/scutum