Cost-effective and rapid blood analysis on a cell-phone

Zhu, Hongying; Şencan, İkbal; Wong, Justin; Dimitrov, Stoyan; Tseng, Derek; Nagashima, Keita; Ozcan, Aydogan

doi:10.1039/c3lc41408f

Cited by 256 publications

(203 citation statements)

References 16 publications

(21 reference statements)

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“…Similarly, various point-of-care diagnostic devices have been developed and among them optical imaging and sensing techniques are highly advantageous as they can provide real-time, highresolution and highly sensitive quantitative information, potentially assisting rapid and accurate diagnosis. [30][31][32][33][34][35][36][37][38][39][40] To date, a number of optical techniques have been proposed for point-of-care diagnostics such as in vitro optical devices, [41][42][43][44][45][46][47][48][49][50][51][52][53] including portable optical imaging systems, optical microscopes integrated to cell phones or in vivo optical devices, [54][55][56][57][58][59][60][61][62][63] involving confocal microscopy, microendoscopy and optical coherence tomography techniques. Among these approaches, lens-free computational on-chip imaging 64 has been an emerging technique that can eliminate the need for bulky and costly optical components while also preserving (or even enhancing in certain cases) the image resolution, field of view and sensitivity.…”

Section: Introductionmentioning

confidence: 99%

Handheld high-throughput plasmonic biosensor using computational on-chip imaging

et al. 2014

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We demonstrate a handheld on-chip biosensing technology that employs plasmonic microarrays coupled with a lens-free computational imaging system towards multiplexed and high-throughput screening of biomolecular interactions for point-of-care applications and resource-limited settings. This lightweight and field-portable biosensing device, weighing 60 g and 7.5 cm tall, utilizes a compact optoelectronic sensor array to record the diffraction patterns of plasmonic nanostructures under uniform illumination by a single-light emitting diode tuned to the plasmonic mode of the nanoapertures. Employing a sensitive plasmonic array design that is combined with lens-free computational imaging, we demonstrate label-free and quantitative detection of biomolecules with a protein layer thickness down to 3 nm. Integrating large-scale plasmonic microarrays, our on-chip imaging platform enables simultaneous detection of protein mono-and bilayers on the same platform over a wide range of biomolecule concentrations. In this handheld device, we also employ an iterative phase retrieval-based image reconstruction method, which offers the ability to digitally image a highly multiplexed array of sensors on the same plasmonic chip, making this approach especially suitable for high-throughput diagnostic applications in field settings.

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Section: Introductionmentioning

confidence: 99%

Handheld high-throughput plasmonic biosensor using computational on-chip imaging

et al. 2014

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“…Field-portable microscopes which can perform automated analysis of manually-prepared slides 5,7,8 as well as microfluidics-based portable imaging platforms have been reported in literature. 15,16,22 The automation of sample/slide preparation required in the case of previously reported microscopes 5,7,8 would potentially involve extensive robotic handling and is quiet challenging to implement.…”

Section: Discussionmentioning

confidence: 99%

“…In the recent past, there have been many reports of field portable digital microscope designs. [5][6][7][8][9][10] Although portable, compact and efficient, these microscopes require manpower with expertise to manually prepare the slides for examination. The process of sample preparation can potentially be automated with the application of recent techniques developed in the field of microfluidics.…”

Section: Introductionmentioning

confidence: 99%

A semi-automated, field-portable microscopy platform for clinical diagnostic applications

2015

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Clinical microscopy is a versatile diagnostic platform used for diagnosis of a multitude of diseases. In the recent past, many microfluidics based point-of-care diagnostic devices have been developed, which serve as alternatives to microscopy. However, these point-of-care devices are not as multi-functional and versatile as clinical microscopy. With the use of custom designed optics and microfluidics, we have developed a versatile microscopy-based cellular diagnostic platform, which can be used at the point of care. The microscopy platform presented here is capable of detecting infections of very low parasitemia level (in a very small quantity of sample), without the use of any additional computational hardware. Such a cost-effective and portable diagnostic device, would greatly impact the quality of health care available to people living in rural locations of the world. Apart from clinical diagnostics, it’s applicability to field research in environmental microbiology has also been outlined.

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“…A large number of mobile health solutions have been presented within this field, including applications for emergency medicine, surgery, otolaryngology, ophthalmology, dermatology, radiology, pathology and general medicine [4]. Specific applications such as burn injury consultation [5], oral cancer diagnostics [6], diagnosis of middle-ear infections [7], refraction tests and cataract assessment (Eyenetra, Somerville, MA), skin cancer detection (SkinVision, SkinVision BV, Amsterdam, Netherlands and MoleScope, MetaOptima, Vancouver, BC) and parasite and cancer microscopy-based diagnosis [8–10] to name a few. A series of portable ultrasound systems are available that can display the image on portable devices, providing rugged low-cost systems that do not compromise the image quality (VScan, GE Healthcare, Chicago, IL, and Clarius, Burnaby BC, Canada).…”

Section: Introductionmentioning

confidence: 99%

Medical mobile technologies – what is needed for a sustainable and scalable implementation on a global scale?

Lundin

Dumont

2017

Global Health Action

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Current advances within medical technology show great potential from a global health perspective. Inexpensive, effective solutions to common problems within diagnostics, medical procedures and access to medical information are emerging within almost all fields of medicine. The innovations can benefit health care both in resource-limited and in resource-rich settings. However, there is a big gap between the proof-of-concept stage and implementation. This article will give examples of promising solutions, with special focus on mobile image- and sensor-based diagnostics. We also discuss how technology and frugal innovations could be made sustainable and widely available. Finally, a list of critical factors for success is presented, based on both our own experiences and the literature.

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Cost-effective and rapid blood analysis on a cell-phone

Cited by 256 publications

References 16 publications

Handheld high-throughput plasmonic biosensor using computational on-chip imaging

Handheld high-throughput plasmonic biosensor using computational on-chip imaging

A semi-automated, field-portable microscopy platform for clinical diagnostic applications

Medical mobile technologies – what is needed for a sustainable and scalable implementation on a global scale?

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