Inkjet Metrology: High-Accuracy Mass Measurements of Microdroplets Produced by a Drop-on-Demand Dispenser

Verkouteren, R. Michael; Verkouteren, Jennifer R.

doi:10.1021/ac901563j

Cited by 92 publications

(109 citation statements)

References 50 publications

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“…Due to the stringent regulatory environment for pharmaceutical manufacturing, it is likely that precise volume/dosage data must be recorded. This may, in future, be carried out using in-line holographic techniques (Martin et al 2011), simple optical imaging (with the compromise of a larger stand-off distance) or ultra-precise gravimetric analysis (Verkouteren et al 2009). These positive confirmation approaches are very difficult to achieve even in an industrial environment and there are no simple solutions yet applicable to a future pharmacy-, hospital-or home-based printer.…”

Section: Drop Formationmentioning

confidence: 99%

Inkjet printing for pharmaceutics – A review of research and manufacturing

Daly

Harrington

Martin

et al. 2015

International Journal of Pharmaceutics

274

185

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Abstract:Global regulatory, manufacturing and consumer trends are driving a need for change in current pharmaceutical sector business models, with a specific focus on the inherently expensive research costs, high-risk capital-intensive scale-up and the traditional centralised batch manufacturing paradigm. New technologies, such as inkjet printing, are being explored to radically transform pharmaceutical production processing and the end-to-end supply chain. This review provides a brief summary of inkjet printing technologies and their current applications in manufacturing before examining the business context driving the exploration of inkjet printing in the pharmaceutical sector. We then examine the trends reported in the literature for pharmaceutical printing, followed by the scientific considerations and challenges facing the adoption of this technology. We demonstrate that research activities are highly diverse, targeting a broad range of pharmaceutical types and printing systems. To mitigate this complexity we show that by categorising findings in terms of targeted business models and Active Pharmaceutical Ingredient (API) chemistry we have a more coherent approach to comparing research findings and can drive efficient translation of a chosen drug to inkjet manufacturing.

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Section: Drop Formationmentioning

confidence: 99%

Inkjet printing for pharmaceutics – A review of research and manufacturing

Daly

Harrington

Martin

et al. 2015

International Journal of Pharmaceutics

274

185

View full text Add to dashboard Cite

show abstract

“…The droplet formation process was captured at 15,000 fps. The droplets were collected in a silicone oil bath to prevent evaporation and weighed using a precision scale with a resolution of 0.0001 g (MS-70, A&D Ltd.); the mass thus measured was converted into the droplet volume [10].…”

Section: Experiments Setupmentioning

confidence: 99%

A pneumatically driven inkjet printing system for highly viscous microdroplet formation

Choi

Kim

2016

Micro and Nano Syst Lett

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This paper introduces a pneumatically driven inkjet printing system that forms highly viscous microdroplets in the nanoliter volume range. The printing system has a unique printing mechanism that uses a flexible membrane and an effective backflow stopper. While typical inkjet systems can handle liquids with a limited range of viscosity due to energy loss by viscous dissipation at the nozzle and ineffective backflow management within their systems, our printing system can print liquids with viscosity as high as 384.5 cP. In the viscosity range 1-384.5 cP, we investigated printing characteristics such as printed droplet volume, standoff distance, and maximum possible frequency. The droplet formation showed outstanding reliability, with the droplet volume exhibiting a coefficient of variation less than 1.07 %. Our printing system can be directly used in inkjet applications with functional liquids over a broad viscosity range.

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“…To trigger the solenoid valve (with a response time of 1 ms), an electric pulse signal was controlled through LabVIEW and the data acquisition device (NI-DAQ USB-6251). To analyze the dispensed volume, a microbalance with a weight resolution of 0.1 mg (A&D Ltd., Japan) was used to measure the mass of dispensed droplets, 18 which were collected in a silicone oil bath to prevent evaporation. The figure in units of mass …”

Section: B Experimental Setupmentioning

confidence: 99%

Plug-in nanoliter pneumatic liquid dispenser with nozzle design flexibility

et al. 2015

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This paper presents a novel plug-in nanoliter liquid dispensing system with a plugand-play interface for simple and reversible, yet robust integration of the dispenser. A plug-in type dispenser was developed to facilitate assembly and disassembly with an actuating part through efficient modularization. The entire process for assembly and operation of the plug-in dispenser is performed via the plug-and-play interface in less than a minute without loss of dispensing quality. The minimum volume of droplets pneumatically dispensed using the plug-in dispenser was 124 nl with a coefficient of variation of 1.6%. The dispensed volume increased linearly with the nozzle size. Utilizing this linear relationship, two types of multinozzle dispensers consisting of six parallel channels (emerging from an inlet) and six nozzles were developed to demonstrate a novel strategy for volume gradient dispensing at a single operating condition. The droplet volume dispensed from each nozzle also increased linearly with nozzle size, demonstrating that nozzle size is a dominant factor on dispensed volume, even for multinozzle dispensing. Therefore, the proposed plug-in dispenser enables flexible design of nozzles and reversible integration to dispense droplets with different volumes, depending on the application. Furthermore, to demonstrate the practicality of the proposed dispensing system, we developed a pencil-type dispensing system as an alternative to a conventional pipette for rapid and reliable dispensing of minute volume droplets. V C 2015 AIP Publishing LLC.

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Inkjet Metrology: High-Accuracy Mass Measurements of Microdroplets Produced by a Drop-on-Demand Dispenser

Cited by 92 publications

References 50 publications

Inkjet printing for pharmaceutics – A review of research and manufacturing

Inkjet printing for pharmaceutics – A review of research and manufacturing

A pneumatically driven inkjet printing system for highly viscous microdroplet formation

Plug-in nanoliter pneumatic liquid dispenser with nozzle design flexibility

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