Your search keyword '"Owyeung, Rachel"' showing total 11 results

1. Development of deep eutectic solvent systems and their formulation: Assessment of solubilization potential on poorly water-soluble drugs.

Author

Shah, Brijesh M., Owyeung, Rachel E., and Sonkusale, Sameer

Subjects

EUTECTIC reactions, SOLUBILIZATION, DRUG solubility, DOCETAXEL, DRUGS, SOLUBILITY

Abstract

Modern strategies to deliver drugs efficiently via less toxic non-aqueous carriers like deep eutectic solvents (DES) has grown tremendously. Herein, we develop several synthetic and natural DES to improve solubility of poorly soluble drug, docetaxel (DTX). Menthol:thymol-based natural DES showed 1500-folds higher solubility for DTX than that in water. FTIR-spectroscopy confirmed reduced crystallinity and stable encapsulation of DTX in DES through formation of hydrogen-bond. DTX-DES was developed further into self-emulsified formulation that upon dilution formed nanostructured globules (< 200 nm) and released 20-folds higher DTX than pure drug thereby highlighting the potential of DES for designing formulations of poorly soluble drugs. [ABSTRACT FROM AUTHOR]

Published

2024

2. Soft Injectable Sutures for Dose‐Controlled and Continuous Drug Delivery.

Author

Alsaedi, Mossab K., Lone, Omar, Nejad, Hojatollah Rezaei, Das, Riddha, Owyeung, Rachel E., Del‐Rio‐Ruiz, Ruben, and Sonkusale, Sameer

Published

2024

3. Smart sensing flexible sutures for glucose monitoring in house sparrows.

Author

Alsaedi, Mossab K., Riccio, Rachel E., Sharma, Atul, Xia, Junfei, Owyeung, Rachel E., Romero, L. Michael, and Sonkusale, Sameer

Subjects

ENGLISH sparrow, GLUCOSE analysis, CHEMICAL detectors, GLUCOSE, SUTURES, ARTIFICIAL implants, GLUCOSE oxidase

Abstract

There is a need for flexible chemical sensors for the ecological and physiological research of avian species such as house sparrows (Passer domesticus). Current methods in this field are invasive and require multiple physical interactions with the birds. Emerging research in flexible bioelectronics can enable realization of implantable devices that are mechanically compliant with the underlying tissues for continuous real-time sensing in situ. However, challenges still remain in forming an intimate flexible interface. One of the promising flexible bioelectronic platforms for tissue-embedded sensing is based on functionalizing surgical sutures or threads. Threads have three-dimensional flexibility, high surface-area-to-volume ratio, inherent wicking properties, and are easily functionalizable using reel-to-reel dip coating. Threads are ideal as they are lightweight, therefore, would not interfere with flight motion and would only require minimal interaction with the bird. However, the challenge remains in achieving a highly conductive yet flexible electrode for electrochemical sensing using materials such as gold. In this study, we address this issue through novel gold deposition directly on thread substrate followed by enzyme immobilization to realize flexible electrochemical glucose biosensors on medical-grade sutures. These sensors were calibrated and tested in a range that is wide enough to include the expected range of glucose concentration in house sparrows (0–8.55 mM). Glucose monitoring in house sparrows will provide insights into energy metabolism and regulation during stress responses. In addition, the stability, repeatability, and selectivity of the sensor were tested with final validation in a real bird. Our innovative gold-coated, thread-based flexible electrochemical glucose sensor can also be used in other small and large animals. This can also be extended to monitoring other metabolites in future. [ABSTRACT FROM AUTHOR]

Published

2023

4. A frequency-adjustable helical antenna using shape memory alloy.

Author

Wang, Wei, Asci, Cihan, Zeng, Wenxin, Owyeung, Rachel, and Sonkusale, Sameer

Subjects

SPIRAL antennas, SHAPE memory alloys, ANTENNAS (Electronics), DEFORMATIONS (Mechanics)

Abstract

There is a need to develop low-cost and compact frequency reconfigurable antennas with continuous frequency tuning capability. Existing approaches rely on dedicated electrical, mechanical, or MEMS-based approaches to reconfigure the antenna, which requires extra components and fabrication steps. In this paper, we propose a physics-based approach to realize tunable helical antennas based on a shape memory alloy (SMA). By utilizing the temperature-induced irreversible mechanical deformation of the SMA, the temperature-controlled antenna can continuously change its resonant frequency and lock the state when the desired frequency response is achieved. The height of the helical antenna changes in response to applied temperatures. No additional circuitry or mechanical modules are required for the reconfiguration of the antenna geometry. The fabricated helical antenna can shift resonant frequency between 150 and 195 MHz with a tuning sensitivity of 284 kHz/°C. [ABSTRACT FROM AUTHOR]

Published

2023

5. Rapid cleanroom-free fabrication of thread based transistors using three-dimensional stencil-based patterning.

Author

Kumar, Tanuj, Owyeung, Rachel E, and Sonkusale, Sameer R

Published

2021

6. Opportunities for ionic liquid/ionogel gating of emerging transistor architectures.

Author

Owyeung, Rachel E., Sonkusale, Sameer, and Panzer, Matthew J.

Subjects

IONIC liquids, TRANSISTORS, DIELECTRICS, SEMICONDUCTORS, SURFACE area, GATES

Abstract

Ionic liquid/ionogel gate dielectrics can provide significant advantages for transistor architectures that utilize high surface area semiconductors and/or nonplanar substrates because of their cleanroom-free, liquid-based processability and their inherently large electrostatic double layer capacitance. These attributes of ionogels have already enabled the facile fabrication of several up-and-coming transistor devices geometries for which a highly conformal interface between the electrolyte gate dielectric and the semiconductor is readily achievable, and remote gating with a nonaligned gate electrode is possible. Further, ionogel gating can improve device performance to maximize current densities at low operating voltages. This Perspective highlights three classes of emerging transistor architectures, namely, vertical transistors, surround gate transistors, and thread/fiber-based transistors, and provides several key examples of instances where ionogel gating has either already enabled or still stands to improve device fabrication and performance. [ABSTRACT FROM AUTHOR]

Published

2021

7. Thread-based multiplexed sensor patch for real-time sweat monitoring.

Author

Terse-Thakoor, Trupti, Punjiya, Meera, Matharu, Zimple, Lyu, Boyang, Ahmad, Meraj, Giles, Grace E., Owyeung, Rachel, Alaimo, Francesco, Shojaei Baghini, Maryam, Brunyé, Tad T., and Sonkusale, Sameer

Subjects

DETECTORS, ELECTROLYTES, METABOLITES, HYDROGEN-ion concentration, CONDUCTOMETRIC analysis, MICROPROCESSORS

Abstract

Sensor platforms that exploit the fibrous textile threads as substrates offer great promise since they can be directly sewn, woven or stitched on to any clothing. They can also be placed directly in intimate contact with the skin. In this work, we present a thread-based sensing platform in the form of a multiplexed sensing patch for continuous simultaneous on-skin monitoring of sweat. The patch performs real-time, on-body measurements of important biomarkers present in sweat such as electrolytes (sodium and ammonium ions), metabolites (lactate) and acidity (pH). Flexible threads coated with conductive inks were used as sensing electrodes. Selective potentiometric detection of electrolytes and pH was made possible through ion-selective membrane deposition and pH-sensitive polyaniline coating on threads, respectively. An amperometric enzymatic sensing scheme with lactate oxidase was used for the detection of lactate. An array of the thread sensors is integrated onto a patch with connectivity to a miniaturized circuit module containing a potentiostat, microprocessor and wireless circuitry for wireless smartphone readout. Extensive in vitro validation and an in vivo human pilot study involving a maximal exertion test show the promise of this platform for real-time physiological monitoring of human performance/fitness under stress, as well as diagnostic monitoring through sweat analysis. [ABSTRACT FROM AUTHOR]

Published

2020

8. Single Event Recording of Temperature and Tilt Using Liquid Metal With RFID Tags.

Author

Wang, Wei, Owyeung, Rachel, Sadeqi, Aydin, and Sonkusale, Sameer

Abstract

There is a need for economical monitoring of fragile goods that are sensitive to temperature, tilt or vibrations during transit. The mishandling of these goods could permanently alter or damage them. Existing methods rely on electronic devices that need a continuous power source for sensing and data logging. This article introduces a simple battery-free economical solution for recording a singular event of temperature crossing or a tilt activity using liquid metal, namely eutectic gallium indium (EGaIn) coupled to a Radio-Frequency Identification (RFID) tag. The crossing of a threshold of either temperature or tilting angle results in EGaIn flow, which activates or deactivates the RFID tag permanently. This change is irreversible; thus, the sensor memorizes the specific temperature or tilt event. This built-in memory function and wireless communication of the RFID sensor enables economical monitoring of temperature and motion-sensitive goods during transport without the need for a battery. In this paper, we have further reduced cost by fabricating these temperature and tilt sensors on paper substrates. [ABSTRACT FROM AUTHOR]

Published

2020

9. Highly stretchable and nonvolatile gelatin-supported deep eutectic solvent gel electrolyte-based ionic skins for strain and pressure sensing.

Author

Qin, Huan, Owyeung, Rachel E., Sonkusale, Sameer R., and Panzer, Matthew J.

Abstract

There is a growing demand for devices that exhibit human skin-like sensory capabilities due to their broad applications in soft robotics and healthcare. Ionically conductive hydrogels have long been studied for wearable, flexible sensor applications; however, the volatility of water inevitably leads to dehydration issues that can limit the long-term use of hydrogel-based devices. In this report, highly stretchable, gelatin biopolymer-supported deep eutectic solvent (DES) gel electrolytes are presented as a promising nonvolatile alternative to hydrogels for ionic skin applications. The DES gel containing 22 wt% gelatin exhibited high stretchability (fracture strain > 300%) and a room temperature ionic conductivity of 2.5 mS cm−1. Capacitive-type pressure and strain sensors fabricated using gelatin-supported DES gel electrolytes provided linear responses over a wide range; an applied pressure as low as 1 kPa could be detected using a 1 V bias. A 3 × 3 sensor array was also constructed, which exhibited excellent performance for identifying the (multi)touch location(s) of applied pressure. These characteristics not only demonstrate the suitability of gelatin-supported DES gels for ionic skin applications, but also present a new class of materials for developing future nonvolatile sensors. [ABSTRACT FROM AUTHOR]

Published

2019

10. Microrheology of gel electrolyte biomaterials based on deep eutectic solvents.

Author

Dholakia, Kishan, Spalding, Gabriel C., Owyeung, Rachel, Cronin-Golomb, Mark, Sonkusale, Sameer, and Panzer, Matthew J.

Published

2020

11. Three dimensional printing of metamaterial embedded geometrical optics (MEGO).

Author

Sadeqi, Aydin, Rezaei Nejad, Hojatollah, Owyeung, Rachel E., and Sonkusale, Sameer

Abstract

Three-dimensional printers have revolutionized many scientific fields with its low-cost, accessibility and ease of printing. In this paper, we show how stereolithography (SLA) based 3D printers can enable realization of innovative 3D optical devices formed through the fusion of metamaterials with geometrical optics or MEGO. It utilizes a combination of desktop SLA 3D printer and metal deposition/coating systems. Using this approach, we present innovative metamaterial embedded optical components such as mushroom-type metamaterials, curved wide-angle metamaterial absorbers/reflectors and a frequency selective moth eye hemispherical absorber. Finally a unique MEGO device formed through the fusion of a frequency selective metamaterial with an optical parabolic reflector has been demonstrated that combines their individual properties in a single device. The fabricated MEGO devices operate in the millimeter wave frequency range. Simulation and measurement results using terahertz continuous-wave spectrometer validate their functionality and performance. With improving resolution in 3D printing, MEGO devices will be able to reach Terahertz and optical frequencies in the near future. Metamaterials: multi-functional optics emerge from 3D printers A technique that uses large area 3D printing and metal layer patterning can realize complex optical devices at a fraction of the cost of typical fabrications. Sameer Sonkusale and colleagues from Tufts University in the United States designed geometric surface patterns, such as tiny forests of mushroom-topped cylinders, capable of interacting strongly with microwave light. Optimizing the conditions needed to 3D print these arrays using photo-curable polymers and to coat them with reflective gold or silver layers led the researchers to explore other unique device possibilities. They created a surface capable of selective high-frequency energy absorption by patterning hemispherical surfaces that resemble an insect's eye. Combining the frequency selective metamaterials with a 3D-printed parabolic lens yielded a prototype that could reduce the expense and size of conventional terahertz spectrometers. [ABSTRACT FROM AUTHOR]

Published

2019