A Millimeter Scale Flexural Testing System for Measuring the Mechanical Properties of Marine Sponge Spicules

Abstract: Many load bearing biological structures (LBBSs)-such as feather rachises and spicules-are small (<1 mm) but not microscopic. Measuring the flexural behavior of these LBBSs is important for understanding the origins of their remarkable mechanical functions. We describe a protocol for performing three-point bending tests using a custom-built mechanical testing device that can measure forces ranging from 10 to 10 N and displacements ranging from 10 to 10 m. The primary advantage of this mechanical testing device … Show more

“…The geometrically complex siliceous skeletal systems of marine sponges have attracted a great deal of attention from the scientific community due to their multi-scale structural hierarchical organization and remarkable damage tolerance [1][2][3]. For example, the mineralized tubular skeleton from one such species, Euplectella aspergillum, consists of bundles of individual needle-like elements (spicules) that are cemented together to form a diagonally reinforced square lattice-like structure that is further covered by a series of helical ridgelike features [4,5].…”

“…First, single-spicule studies have revealed the presence of an underlying laminated architecture consisting of concentric lamellae of consolidated silica nanoparticles separated by thin organic interlayers. The silica layers decrease in thickness from the spicule core to its periphery, resulting in a functionally graded design that effectively retards crack propagation through the spicules, while simultaneously increasing their buckling resistance [3,6].…”

Mechanical and hydrodynamic analyses of helical strake-like ridges in a glass sponge

“…The geometrically complex siliceous skeletal systems of marine sponges have attracted a great deal of attention from the scientific community due to their multi-scale structural hierarchical organization and remarkable damage tolerance [1][2][3]. For example, the mineralized tubular skeleton from one such species, Euplectella aspergillum, consists of bundles of individual needle-like elements (spicules) that are cemented together to form a diagonally reinforced square lattice-like structure that is further covered by a series of helical ridgelike features [4,5].…”

“…First, single-spicule studies have revealed the presence of an underlying laminated architecture consisting of concentric lamellae of consolidated silica nanoparticles separated by thin organic interlayers. The silica layers decrease in thickness from the spicule core to its periphery, resulting in a functionally graded design that effectively retards crack propagation through the spicules, while simultaneously increasing their buckling resistance [3,6].…”

Mechanical and hydrodynamic analyses of helical strake-like ridges in a glass sponge

Sawtooth patterns in flexural force curves of structural biological materials are not signatures of toughness enhancement: Part I