A thermal microjet system with tapered micronozzles fabricated by inclined UV lithography for transdermal drug delivery

Yoon, Yong-Kyu; Park, Jung Hwan; Lee, Jeong-Woo; Prausnitz, Mark R.; Allen, Mark G.

doi:10.1088/0960-1317/21/2/025014

Cited by 19 publications

(8 citation statements)

References 28 publications

(33 reference statements)

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“…The inkjet devices were based on the squeeze mode design and produced uniform droplets at these high frequencies. The inkjet devices in this study produced droplets at rates of 100 times more than conventional inkjet devices . The improved performances of inkjet devices may be partly attributed to the presence of a constriction in the capillary tube.…”

Section: Discussionmentioning

confidence: 79%

Development of High‐Throughput Glass Inkjet Devices for Pharmaceutical Applications

Ehtezazi

Dempster

Martin

et al. 2014

Journal of Pharmaceutical Sciences

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The application of the inkjet method to pharmaceutical products is promising. To make this realistic, not only does the throughput of this method need to be increased, but also the components should be inert to pharmaceutical preparations. We present designs of glass based inkjet devices that are capable of producing droplets at high rates. To achieve this, inkjet devices from capillary tubes were manufactured with orifice diameters of 5µm, 10µm and 20µm and were actuated with diaphragm piezoelectric disks. Also, a pressure capsule was formed by creating a manifold at a distance from the orifice tip. Placing the piezoelectric disk at 0.5 mm distance from the tip allowed formation of a jet at 3.2MHz in certain designs, but for a short period of time due to overheating. The length of the pressure capsule, its inlet diameter and the nozzle tip geometry were crucial to lower the required power. Actuating an inkjet device with 10µm orifice diameter comfortably at 900 kHz and drying the droplets from 1% salbutamol sulphate solution allowed formation of particles with diameters of 1.76±0.15µm and the geometric standard deviation of 1.08. In conclusion, optimising internal design of glass inkjet devices allowed production of high throughput droplet ejectors.

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Section: Discussionmentioning

confidence: 79%

Development of High‐Throughput Glass Inkjet Devices for Pharmaceutical Applications

Ehtezazi

Dempster

Martin

et al. 2014

Journal of Pharmaceutical Sciences

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show abstract

“…Many practical applications of 3D micro-and nano-structures have been reported, such as Vgrooves for fiber holder (Ling & Lian, 2007), mesh structures for microfilter (Sato et al, 2004), inclined surfaces for the optical pick-up head (Huang et al, 2004), pyramid array for optical display (Yoon et al, 2006;Shieh et al, 2005), some complex microstructures for micromixer (Baek et al, 2011;Sato et al, 2006) and drug delivery (Han et al, 2007;Yoon et al, 2011), and periodic array for photonic crystal. In this section, we will demonstrate our exploitation of micro-and nano-structures applications on 45° inclined mirrors and microfilter system, fabricated by the prism-assisted photolithography.…”

Section: Application Of Micro-and Nano-structuresmentioning

confidence: 99%

Fabrication of 3D Micro- and Nano-Structures by Prism-Assisted UV and Holographic Lithography

Jiang¹,

Shen²,

Wang³

2013

Updates in Advanced Lithography

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“…Metal microneedle structures are often formed using an electroplating process onto a seeding layer that is predefined by a polymer micromold 14 . Polymer 3D microneedle structures are created using stainless steel molding technology 15 , inclined ultraviolet (UV) exposure technology 16 , polydimethylsiloxane molding technology 17,18 , and etched lens backside exposure technology 19 . Because these approaches require special equipment or platforms, microneedle structures that are fabricated either by assembling 2D probe combs or etching bulk materials are expensive and time consuming.…”

Section: Introductionmentioning

confidence: 99%

A flexible three-dimensional electrode mesh: An enabling technology for wireless brain–computer interface prostheses

2016

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The neural interface is a key component in wireless brain-computer prostheses. In this study, we demonstrate that a unique three-dimensional (3D) microneedle electrode on a flexible mesh substrate, which can be fabricated without complicated micromachining techniques, is conformal to the tissues with minimal invasiveness. Furthermore, we demonstrate that it can be applied to different functional layers in the nervous system without length limitation. The microneedle electrode is fabricated using drawing lithography technology from biocompatible materials. In this approach, the profile of a 3D microneedle electrode array is determined by the design of a two-dimensional (2D) pattern on the mask, which can be used to access different functional layers in different locations of the brain. Due to the sufficient stiffness of the electrode and the excellent flexibility of the mesh substrate, the electrode can penetrate into the tissue with its bottom layer fully conformal to the curved brain surface. Then, the exposed contact at the end of the microneedle electrode can successfully acquire neural signals from the brain. INTRODUCTIONBrain-computer prostheses provide a bridge for humans to understand and communicate with the nervous system. Neural interfaces are a key component enabling wireless brain-computer prostheses for long-term implantation. In the last decades, researchers have developed various types of neural interfaces based on advanced functional materials and fabrication technology [1][2][3] . Because a two-dimensional (2D) structure can be shaped precisely and easily, most neural interfaces are fabricated into planar geometries, which are known as neural probes. However, neural tissues are normally three-dimensional (3D) structures, and 2D neural probes are limited to recording signals from only planar brain regions

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A thermal microjet system with tapered micronozzles fabricated by inclined UV lithography for transdermal drug delivery

Cited by 19 publications

References 28 publications

Development of High‐Throughput Glass Inkjet Devices for Pharmaceutical Applications

Development of High‐Throughput Glass Inkjet Devices for Pharmaceutical Applications

Fabrication of 3D Micro- and Nano-Structures by Prism-Assisted UV and Holographic Lithography

A flexible three-dimensional electrode mesh: An enabling technology for wireless brain–computer interface prostheses

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