A nonradiographic strategy to real‐time monitor the position of three‐dimensional‐printed medical orthopedic implants by embedding superparamagnetic Fe<sub>3</sub>O<sub>4</sub> particles

Li, Yike; Chen, Peng; Wu, Zhenhua; Shi, Congcan; Chen, Peng; Xu, Yizhuo; Chen, Xiaojun; Chen, Manhui; Li, Yuxin; Yan, Chunze; Shi, Yunsong; Su, Bin

doi:10.1002/idm2.12133

Cited by 12 publications

(3 citation statements)

References 70 publications

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“…Most importantly, it should be noted that the metamaterials DM-BH, VS-BH, SS-BH (Figures a4–c6 and 6a4–c6) and DM-BI, VS-BI, SS-BI (Figures a4–c6 and 7a4–c6) exclusively generate entirely different positive and negative thermal deformations, namely, mode #B( x + y – ) along the two orthotropic directions. Based on the functional additive manufacturing process, − it is prospective that these newly designed metamaterials provide more flexibility to satisfy the individual requirements raised by such things as the electronic packaging and temperature sensors, as different magnitude, especially different sign, i.e., positive or negative, thermal deformations should be carefully customized along specific directions.…”

Section: Comparison and Discussionmentioning

confidence: 99%

Multimaterial Metamaterials: Customize Targeted Thermal Deformation Modes Responding to Time- and Space-Variant Temperature Stimuli

Wang,

Wei

et al. 2024

ACS Appl. Mater. Interfaces

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Customizing the engineering targeted thermal deformations is of vital significance for dimensional stability or shape morphing in materials and structures. However, current metamaterials are designed solely in the homogeneous form to respond only to the time-variant temperature (TVT) stimuli, far behind the practical engineering scenario and demands. Here, a new strategy is originally proposed and experimentally verified to design a series of both homogeneous and inhomogeneous multimaterial metamaterials, which uniquely output various thermal deformation modes, responding to time-variant and space-variant temperature (SVT) stimuli. Specifically, in addition to the regular isotropic thermal deformations, the metamaterials could exclusively output the entirely different positive and negative thermal deformations along the two orthotropic directions. Besides, stimulated by both TVT and SVT, the metamaterials provide more flexibility to customize the targeted thermal deformations. That is, the uniform thermal deformations could be well customized by the metamaterials stimulated by either TVT or SVT. More importantly, the customizability is remarkably broadened, as the nonuniform, specifically, mathematicized linear and nonlinear thermal deformations, are elaborately customized. Overall, these originally devised metamaterials open a new avenue for the purpose of customizing the engineering targeted thermal deformations in various modes under both TVT and SVT stimuli.

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Section: Comparison and Discussionmentioning

confidence: 99%

Multimaterial Metamaterials: Customize Targeted Thermal Deformation Modes Responding to Time- and Space-Variant Temperature Stimuli

Wang,

Wei

et al. 2024

ACS Appl. Mater. Interfaces

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“…In addition, the sensor has the ability to sense tactile pressure like biological skin by measuring capacitance rise from the electrode and dielectric layer compression. Among the multimaterial methods for manufacturing tactile sensors, advanced processes such as high-temperature selective laser sintering (HT-SLS), 3D printing, and electrospinning have great application prospects. Based on the characteristics of the raw materials, we use the coating process to achieve the composite of the two materials.…”

Section: Introductionmentioning

confidence: 99%

Bioinspired Flexible Capacitive Sensor for Robot Positioning in Unstructured Environments

Zhou,

Zhang,

Bai

et al. 2024

ACS Appl. Mater. Interfaces

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The evolution of bionic machines into intelligent robots to adapt to real scenarios is inseparable from positioning sensors. However, traditional positioning methods such as camera arrays, ultrasound, or GPS are limited in narrow concealed spaces, harsh temperatures, or dynamic light fields, which hinder the practical application of special robots. Here, we report a flexible sensor inspired by Gnathonemus petersii that enables robots to achieve contactless and high-precision spatial localization independent of the unstructured features of the environment. Sensors are obtained from lowcost materials (carbon nanotubes and polyimides) and simple structures (fibers) and preparation processes (spin-coating). Experiments and simulations confirmed the high resolution (<1 mm) of the sensor over a large distance detection range (>150 mm) and high bandwidth (0−520 MPa) of contact force. Moreover, the sensing capability is still feasible when the sensor is bent to various curvatures and not affected under harsh conditions such as ultralow temperatures (below −78 °C), ultrahigh temperatures (over 250 °C), darkness, or brightness. We demonstrate the practical potential of the proposed sensors for a biomimetic hyperredundant continuum robot to locate and avoid collisions in unstructured environments.

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“…The rapid growth of the global population and the continuous expansion of the modern economy have resulted in the exhaustive exploitation of fossil fuels and the massive production of environmental pollutants. Therefore, scientists have made tremendous efforts to explore and utilize renewable energy sources, especially focusing on nanofluid-based energy harvesting technologies, such as osmotic power generation. − Osmotic energy generated at the junction of sea and river has drawn tremendous attention due to its sustainability, widespread presence, and minimal variability in power output compared to intermittent energy sources like solar and wind power. − In addition to such natural salinity gradient, industrial processes (e.g., dyeing, weaving, medicine synthesis, and paper production) also produce huge volumes of waste organic solvents containing various concentrations of inorganic salts . Besides, the recycling of electrode materials in power batteries also yield massive organic waste solution containing salts of lithium, cobalt, and manganese .…”

mentioning

confidence: 99%

Boosting Osmotic Energy Harvesting from Organic Solutions by Ultrathin Covalent Organic Framework Membranes

Fang,

Yan,

Ying

et al. 2024

Nano Lett.

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Extracting osmotic energy from waste organic solutions via reverse electrodialysis represents a promising approach to reuse such industrial wastes and helps to mitigate the ever-growing energy needs. Herein, a molecularly thin membrane of covalent organic frameworks is engineered via interfacial polymerization to investigate its ion transport behavior in organic solutions. Interestingly, a significant deviation from linearity between ion conductance and reciprocal viscosity is observed, attributed to the nanoscale confinement effect on intermolecular interactions. This finding suggests a potential strategy to modulate the influence of apprarent viscosity on transmembrane transport. The osmotic energy harvesting of the ultrathin membrane in organic systems was studied, achieving an unprecedented output power density of over 84.5 W m −2 at a 1000-fold salinity gradient with a benign conversion efficiency and excellent stability. These findings provide a meaningful stepping stone for future studies seeking to fully leverage the potentials of organic systems in energy harvesting applications.

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A nonradiographic strategy to real‐time monitor the position of three‐dimensional‐printed medical orthopedic implants by embedding superparamagnetic Fe₃O₄ particles

Cited by 12 publications

References 70 publications

Multimaterial Metamaterials: Customize Targeted Thermal Deformation Modes Responding to Time- and Space-Variant Temperature Stimuli

Multimaterial Metamaterials: Customize Targeted Thermal Deformation Modes Responding to Time- and Space-Variant Temperature Stimuli

Bioinspired Flexible Capacitive Sensor for Robot Positioning in Unstructured Environments

Boosting Osmotic Energy Harvesting from Organic Solutions by Ultrathin Covalent Organic Framework Membranes

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A nonradiographic strategy to real‐time monitor the position of three‐dimensional‐printed medical orthopedic implants by embedding superparamagnetic Fe3O4 particles

Cited by 12 publications

References 70 publications

Multimaterial Metamaterials: Customize Targeted Thermal Deformation Modes Responding to Time- and Space-Variant Temperature Stimuli

Multimaterial Metamaterials: Customize Targeted Thermal Deformation Modes Responding to Time- and Space-Variant Temperature Stimuli

Bioinspired Flexible Capacitive Sensor for Robot Positioning in Unstructured Environments

Boosting Osmotic Energy Harvesting from Organic Solutions by Ultrathin Covalent Organic Framework Membranes

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Product

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A nonradiographic strategy to real‐time monitor the position of three‐dimensional‐printed medical orthopedic implants by embedding superparamagnetic Fe₃O₄ particles