Broadly Available Imaging Devices Enable High-Quality Low-Cost Photometry

Christodouleas, Dionysios C.; Nemiroski, Alex; Kumar, Ashok Ashwin; Whitesides, George M.

doi:10.1021/acs.analchem.5b01612

Cited by 119 publications

(93 citation statements)

References 42 publications

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“…Recentemente, Christodouleas et al 14 mostraram que um scanner de mesa pode substituir um leitor de microplacas, fazendo a quantificação de diversos corantes e leituras de placas de teste ELISA (ensaio de imunoabsorção enzimática, Enzyme-Linked Immunosorbent Assay).…”

Section: (1)unclassified

Determinação de fosfato em refrigerantes utilizando um scanner de mesa e análise automatizada de dados: um exemplo didático para ensino de química

Colzani¹,

Rodrigues²,

Fogaça³

et al. 2017

Quim. Nova

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PHOSPHATE COLORIMETRIC ANALYSIS USING A DESKTOP SCANNER AND AUTOMATED DIGITAL IMAGE ANALYSIS:A DIDATICAL EXAMPLE TO TEACH COLORIMETRIC ANALYSES. We propose here the quantification of the phosphorus content in cola drinks by molybdenum blue method. Molybdenum blue method was carried out in the wells of a microplate, where method miniaturization represents reduction in reagents required, improved safety, reduced waste stream, and increased sample throughput. The phosphate concentration was determinate using scanned images of the microplate. Extraction of RGB values was carried out using ImageJ, the pugling Readplate was used allowing extraction of RGB values of all wells simultaneously. A Microsoft Excel spreadsheet is afforded in Google Drive, it organize data taken from ImageJ to afford calibrations curves and phosphate concentration in cola drinks. Calibration curves were prepared at 500-2500 µg L -1 of P with good linearity (R > 0.95). Phosphate concentrations in cola drinks determinate using digital images method are statistically equivalent to concentrations determined using a spectroscopic method at a 95% confidence interval.Keywords: RGB; digital image; ImageJ; phosphate. INTRODUÇÃONas últimas décadas, vários métodos colorimétricos foram adaptados para microplacas, em especial, na área clínica e em análises ambientais. As vantagens de adaptar os métodos tradicionais são a redução no uso de reagentes e consequente menor geração de resíduos químicos. No entanto, o uso de técnicas de microescala empregando microplacas, em sala de aula, é provavelmente limitada pelo custo elevado (ordem de US$ 10.000) dos leitores de microplacas. 1 Normalmente, as imagens digitais utilizam o sistema Red, Green e Blue (RGB) para a definição de cores. Nesse sistema, cada tom de cor é definido por três canais: R (vermelho), G (verde) e B (azul), que variam como índices inteiros entre 0 e 255, onde o 0 corresponde à cor preta e o 255 corresponde ao R ou G ou B puros. Desta forma, no sistema RGB, um tom de cor corresponde a um ponto em um espaço tridimensional formado pelos eixos R, G e B, sendo possível a geração de 16 milhões de cores diferentes (256 3 ). 2A absorbância é definida de acordo com a Equação 1. A potência de um feixe (P), transmitida através de uma célula com a solução do analito, é comparada com a potência que atravessa uma célula idên-tica contendo somente o solvente ou o branco dos reagentes (P 0 ). De acordo com a lei Beer-Lambert, a absorbância (A) é proporcional a concentração do analito. (1)Kohl et al.3 desenvolveram uma prática de ensino que mostrou que o princípio da absorbância pode ser facilmente demonstrada utilizando soluções coloridas e análises de imagens digitais. A prática de ensino consistia em fotografar um conjunto de cubetas contendo corante amarelo em diferentes concentrações e uma cubeta contendo apenas água destilada. Os valores de G foram obtidos para as cubetas que continham o corante amarelo e G 0 foi obtido da cubeta que continha apenas água destilada. Posteriormente, estes valores foram u...

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Section: (1)unclassified

Determinação de fosfato em refrigerantes utilizando um scanner de mesa e análise automatizada de dados: um exemplo didático para ensino de química

Colzani¹,

Rodrigues²,

Fogaça³

et al. 2017

Quim. Nova

View full text Add to dashboard Cite

show abstract

“…A scanometry has been used as a microplate reader for high throughput screening of antioxidant based on DPPH as dry reagent on microwell plate as also used by other 28 . However, the proposed method is the first application for antioxidant sensor, measuring antioxidant capacity of GA and plant extracts.…”

Section: Resultsmentioning

confidence: 99%

“…The gray intensity, typically a result of silver enhancement is the measured signal in scanometry 27 . Scanometry was used to characterize optical feature of various dyes, such as disperse orange 3, methyl orange, fluorescein, eosin Y, rhodamine B, trypan blue, prussian blue, malachite green, methylene blue, chlorophyll b, and DPPH, in a microwell plate 28 . As the color intensity in red, green, and blue (RGB) value was mathematically converted to RGB-resolved absorbance, it was shown that flatbed scanner was comparable with spectrophotometer.…”

Section: Introductionmentioning

confidence: 99%

Scanometry as microplate reader for high throughput method based on DPPH dry reagent for antioxidant assay

Hidayat

Fitri

Kuswandi

2017

Acta Pharmaceutica Sinica B

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The stable chromogenic radical 1,1′-diphenyl-2-picrylhydrazyl (DPPH) solution was immobilized on the microwell plate as dry reagent to construct a simple antioxidant sensor. Then, a regular flatbed scanner was used as microplate reader to obtain analytical parameters for antioxidant assay using one-shot optical sensors as scanometry technique. Variables affecting the acquisition of the images were optimized and the analytical parameters are obtained from an area of the sensing zone inside microwell using the average luminosity of the sensing zone captured as the mean of red, green, and blue (RGB) value using ImageJ® program. By using this RGB value as sensor response, it is possible to determine antioxidant capacity in the range 1–25 ppm as gallic acid equivalent (GAE) with the response time of 9 min. The reproducibility of sensor was good (RSD<1%) with recovery at 93%–96%. The antioxidant sensor was applied to the plant extracts, such as sappan wood and Turmeric Rhizome. The results are good when compared to the same procedure using a UV/Vis spectrophotometer.

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“…There are some smartphone based devices that are not found in the app stores, but there is a clear displacement of lab equipment using mobile technology, such as in the areas of microplate reading (Berg et al, 2015;Christodouleas et al 2015;Fu et al, 2016), live cell imaging (Walzik et al, 2015), microfluidics for cancer detection (Barbosa et al, 2015), food allergen detection (Coskun et al, 2013), and immunochromatgraphic detection of bacteria (Rajendran et al, 2014).Nonetheless, there are areas where no changes are expected; and this is the work of dangerous chemical and pathogens (e.g. Biohazard Class 3 work).…”

Section: Resultsmentioning

confidence: 99%

The world of biomedical apps: their uses, limitations, and potential

Gan

Poon

2016

Sci Phone Appl Mob Devices

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Many significant biomedical discoveries of old were made in the private property of famous scientists e.g. Leeuwenhoek and Archimedes. Today, discoveries are made in brightly-lit, hi-tech, ergonomic buildings that house research institutes. While such development is advantageous in many aspects, the spatial restriction of research into well-organized structures may delay and limit the spontaneity necessary for discoveries. The smartphone and peripheral mobile devices have the potential to not only increase the productivity and mobility of biomedical research, but also restore some freedom from spatial constraints. One possible way this can occur is the development of a mobile biomedical lab that allows researchers to carry out core research processes 'on-the-go' without being spatially restrained within a building or availability of equipment. For this exciting prospect, we surveyed the Google and Apple app stores, discussing the limitations and the potential of this area. Based on the developments, it appears to be just a matter of time before the majority of biomedical labs processes and equipment become mobile, centred on the smartphone and peripheral devices.

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Broadly Available Imaging Devices Enable High-Quality Low-Cost Photometry

Cited by 119 publications

References 42 publications

Determinação de fosfato em refrigerantes utilizando um scanner de mesa e análise automatizada de dados: um exemplo didático para ensino de química

Determinação de fosfato em refrigerantes utilizando um scanner de mesa e análise automatizada de dados: um exemplo didático para ensino de química

Scanometry as microplate reader for high throughput method based on DPPH dry reagent for antioxidant assay

The world of biomedical apps: their uses, limitations, and potential

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