Smart-phone based computational microscopy using multi-frame contact imaging on a fiber-optic array

Navruz, İsa; Coşkun, Ahmet F.; Wong, Justin; Mohammad, Saqib; Tseng, Derek; Nagi, Richie; Phillips, Stephen W.; Ozcan, Aydogan

doi:10.1039/c3lc50589h

Cited by 112 publications

(76 citation statements)

References 49 publications

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“…Navruz et al developed a smartphone-based microscopy utilizing a multi-frame image acquisition scheme and rapid digital processing on the phone for microscopic imaging of blood smears. (Navruz et al, 2013). But, spatial resolution of this microscope was still around micrometer scale.…”

Section: Microscopic Bio-imaging On Smartphonementioning

confidence: 95%

Biosensors and bioelectronics on smartphone for portable biochemical detection

Zhang

Liu

2016

Biosensors and Bioelectronics

562

216

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Section: Microscopic Bio-imaging On Smartphonementioning

confidence: 95%

Biosensors and bioelectronics on smartphone for portable biochemical detection

Zhang

Liu

2016

Biosensors and Bioelectronics

562

216

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“…Therefore, molecular microscopy can be made with low-cost processing on smartphones, enabling users to make a wide range of blood or urine tests [9], [10], [11], [12], [13]. Some of these solutions have already been exploited to create commercial products 1 With one more layer of abstraction, the smart phones could use other sensors, apart from the embedded or attached ones to provide even more fine-grained health services.…”

Section: Related Workmentioning

confidence: 97%

Privacy-Aware Large-Scale Virological and Epidemiological Data Monitoring

Patsakis

Clear

Laird

et al. 2014

2014 IEEE 27th International Symposium on Computer-Based Medical Systems

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Modern mobile and wearable devices are enabling the realization of so-called ubiquitous computing. This provides citizens the technological means to contribute to urban management by becoming sensors within a smart city. Notwithstanding, the health sector is a very crucial factor for city management, imposing restrictions to the decisions directly or indirectly. The question that arises is given the current technological advances, could we collect health related data from citizens without violating their privacy? In this work we propose a methodology that can be used to allow citizens to send their data without disclosing their identity, while simultaneously enabling almost real-time urban-scale virological and epidemiological data monitoring.

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“…Recent technological developments have led to a rapid increase in advanced mobile analytical measurement tools aiming at various biomedical and environmental applications [13][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28][29][30][31] . The Google Glass as a wearable computer provides a hands-free computational interface with a camera and some spatio-temporal sensors that can be used in several diagnostic and medical applications [32][33][34] .…”

Section: Introductionmentioning

confidence: 99%

Field quantification of plant chlorophyll content using Google Glass

et al. 2015

Self Cite

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Quantification of plant health is crucial for agriculture and can even be used to monitor environmental factors and climate related changes. Plant health is known to be directly related to the chlorophyll content of leaves, which correlates with the capacity of the leaves to transmit or absorb light. The gold-standard method for measuring the chlorophyll concentration of a leaf is based on chemical extraction, which is complex, destructive and time-consuming. As an alternative, here we present a field-portable, cost-effective, and colorimetric method to quantify the chlorophyll content of leaves using Google Glass. For this purpose, we created a custom designed handheld device which is battery-powered and 3D-printed to separately provide uniform illumination of a selected region of interest on the leaf surface using red and white light-emitting-diodes (LEDs). The design of this device minimizes the interference of ambient light conditions to our chlorophyll measurements performed through the Glass camera. We tested this platform by using fifteen randomly selected plant species from UCLA Botanical Garden and imaging fully-grown leaves of these species using Glass. An image-processing algorithm was developed to process the acquired images and obtain the chlorophyll concentration information using the red channel intensities in our region-of-interest for both the white and red LED illumination conditions. The results obtained by this algorithm are in good agreement with the SPAD indices measured for each plant, demonstrating that Google Glass, in combination with our custom-designed illumination platform, can expand its functionality to be used as a chlorophyll meter in field-settings.

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Smart-phone based computational microscopy using multi-frame contact imaging on a fiber-optic array

Cited by 112 publications

References 49 publications

Biosensors and bioelectronics on smartphone for portable biochemical detection

Biosensors and bioelectronics on smartphone for portable biochemical detection

Privacy-Aware Large-Scale Virological and Epidemiological Data Monitoring

Field quantification of plant chlorophyll content using Google Glass

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