Remote-controlled insect navigation using plasmonic nanotattoos

Developing insect cyborgs by integrating external components (optical, electrical or mechanical) with biological counterparts has a potential to offer elegant solutions for complex engineering problems.1 A key limiting step in the development of such biorobots arises at the nano-bio interface, i.e. between the organism and the nano implant that offers remote controllability.1,2 Often, invasive procedures are necessary that tend to severely compromise the navigation capabilities as well as the longevity of such biorobots. Therefore, we sought to develop a non-invasive solution using plasmonic nanostructures that can be photoexcited to generate heat with spatial and temporal control. We designed a ‘nanotattoo’ using silk that can interface the plasmonic nanostructures with a biological tissue. Our results reveal that both structural and functional integrity of the biological tissues such as insect antenna, compound eyes and wings were preserved after the attachment of the nanotattoo. Finally, we demonstrate that insects with the plasmonic nanotattoos can be remote controlled using light and integrated with functional recognition elements to detect the chemical environment in the region of interest. In sum, we believe that the proposed technology will play a crucial role in the emerging fields of biorobotics and other nano-bio applications.

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Experimental Validation of Minimax Entropy Principle in Ultrasound Images

Recent Advances in Electrical & Electronic Engineering (Formerly Recent Patents on Electrical & Electronic Engineering) ◽

10.2174/2352096511666180912120956 ◽

2019 ◽

Vol 12 (6) ◽

pp. 487-493

Author(s):

Neha Mehta ◽

Svav Prasad ◽

Leena Arya

Keyword(s):

Region Of Interest ◽

Ultrasound Images ◽

Human Gallbladder ◽

New Approach ◽

Non Invasive ◽

Entropy Principle ◽

Significant Performance ◽

Considerable Impact ◽

Ultrasonic Devices ◽

Measure Of Uncertainty

Ultrasound imaging is one of the non-invasive imaging, that diagnoses the disease inside a human body and there are numerous ultrasonic devices being used frequently. Entropy as a well known statistical measure of uncertainty has a considerable impact on the medical images. A procedure for minimizing the entropy with respect to the region of interest is demonstrated. This new approach has shown the experiments using Extracted Region Of Interest Based Sharpened image, called as (EROIS) image based on Minimax entropy principle and various filters. In this turn, the approach also validates the versatility of the entropy concept. Experiments have been performed practically on the real-time ultrasound images collected from ultrasound centers and have shown a significant performance. The present approach has been validated with showing results over ultrasound images of the Human Gallbladder.

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Microwave thermometry with potential application in non-invasive monitoring of hyperthermia

Journal of Inverse and Ill-Posed Problems ◽

10.1515/jiip-2020-0102 ◽

2020 ◽

Vol 28 (5) ◽

pp. 739-750

Author(s):

Morteza Ghaderi Aram ◽

Larisa Beilina ◽

Hana Dobsicek Trefna

Keyword(s):

Least Squares Method ◽

Regularization Parameter ◽

Region Of Interest ◽

Optimal Choice ◽

Adaptive Finite Element Method ◽

Adaptive Finite Element ◽

Non Invasive ◽

Full Wave ◽

Reconstruction Quality ◽

Regularization Techniques

AbstractIntegration of an adaptive finite element method (AFEM) with a conventional least squares method has been presented. As a 3D full-wave forward solver, CST Microwave Studio has been used to model and extract both electric field distribution in the region of interest (ROI) and S-parameters of a circular array consisting of 16 monopole antennas. The data has then been fed into a differential inversion scheme to get a qualitative indicator of how the temperature distribution evolves over a course of the cooling process of a heated object. Different regularization techniques within the Tikhonov framework are also discussed, and a balancing principle for optimal choice of the regularization parameter was used to improve the image reconstruction quality of every 2D slice of the final image. Targets are successfully imaged via proposed numerical methods.

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A Novel Paradigm for Engineering Education: Virtual Internships With Individualized Mentoring and Assessment of Engineering Thinking

Journal of Biomechanical Engineering ◽

10.1115/1.4029235 ◽

2015 ◽

Vol 137 (2) ◽

Cited By ~ 12

Author(s):

Naomi C. Chesler ◽

A. R. Ruis ◽

Wesley Collier ◽

Zachari Swiecki ◽

Golnaz Arastoopour ◽

...

Keyword(s):

Engineering Education ◽

First Year ◽

Collaborative Environment ◽

Large Numbers ◽

Engineering Problems ◽

Complex Engineering ◽

Potential Impact

Engineering virtual internships are a novel paradigm for providing authentic engineering experiences in the first-year curriculum. They are both individualized and accommodate large numbers of students. As we describe in this report, this approach can (a) enable students to solve complex engineering problems in a mentored, collaborative environment; (b) allow educators to assess engineering thinking; and (c) provide an introductory experience that students enjoy and find valuable. Furthermore, engineering virtual internships have been shown to increase students'—and especially women's—interest in and motivation to pursue engineering degrees. When implemented in first-year engineering curricula more broadly, the potential impact of engineering virtual internships on the size and diversity of the engineering workforce could be dramatic.

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