Enhanced Evaporation of Microscale Droplets With an Infrared Laser

Ferraz-Albani, Luis A.; Baldelli, Alberto; Knapp, Chrissy J.; Jäger, Wolfgang; Vehring, Reinhard; Nobes, David S.; Olfert, Jason S.; Kostiuk, Larry W.

doi:10.1115/1.4034486

Cited by 18 publications

(8 citation statements)

References 36 publications

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“…Two syringes (1 µl and 10 µl) were used to quantify the formalin solution that was inserted in the enclosure through a rubber septum. The quantity of formalin solution inserted in the enclosure quickly evaporates due to high vapor pressure [2,18] and, if not, was then deposited on a filter paper. A reference method was used to validate the accuracy of the low-cost formaldehyde sensor readings.…”

Section: Low-cost Formaldehyde Sensor's Laboratory Evaluationmentioning

confidence: 99%

Real-time measurements of formaldehyde emissions in a gross anatomy laboratory

et al. 2020

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Formaldehyde is recognized to be a carcinogen and a genotoxic indoor pollutant. The National Institute for Occupational Safety and Health (NIOSH) identify 1 ppm as the ceiling limit, a value which should not be exceeded at any time. This low ceiling limit generates the need for real-time monitoring; which can, however, lack in accuracy. In this project, formaldehyde low-cost monitors are both evaluated in a laboratory platform and in an indoor environment. Using a controlled environmental chamber, the formaldehyde sensors show a linear regression coefficient R 2 of 0.98 when compared to the reference method [NIOSH 2016, based on 2,4-dinitrophenylhydrazine (DNPH) derivatization]. Readings taken with the calibrated low-cost monitors in a gross anatomy laboratory, where embalmers, medical students and staff are exposed to formaldehyde and other toxic volatile organic compounds, show that the embalming and dissection processes generate average values of about 900 and 1300 ppb, respectively, when corrected for phenol interference. The corrected average values are within 20% of the reference method values. Real-time data for the same processes show maximum concentrations (1-min average) of about 3.5 ppm in both embalming procedure and dissection laboratory. Therefore, real-time monitoring can show values of formaldehyde exceeding the acceptable exposure short-term limit and ceiling limit.

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Section: Low-cost Formaldehyde Sensor's Laboratory Evaluationmentioning

confidence: 99%

Real-time measurements of formaldehyde emissions in a gross anatomy laboratory

et al. 2020

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“…Light scattering is the most common technique used in recent studies involving portable, real-time PM measurements [22,31]. Benefits of light scattering include the lowcost, suitability for a broad range of PM sizes (0.2-700 µm), ease of calibration, and fast analysis time (about 1 min) [2,4,5].…”

Section: Particulate Matter (Pm)mentioning

confidence: 99%

Particle matter, volatile organic compounds, and occupational allergens: correlation and sources in laboratory animal facilities

et al. 2020

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Exposure to airborne allergens from mice and rats can lead to laboratory animal asthma or allergy. Several biological methods can measure allergens contained in aerosols; however, they are time and cost intensive. An innovative methodology is proposed to warn laboratory animal facility workers of a possible rise in mouse and rat allergens by measuring the relationships between airborne allergens, particulate matter (PM), and volatile organic compounds (VOCs). By using a low-cost sensor (average difference respect to reference methods of 3 and 9% for PM 2.5 and VOC, respectively), Spearman's rank correlation between allergens and time-averaged PM and VOCs was found to be 0.3 and − 0.07, respectively. These numbers indicate a poor correlation between allergens and PM 2.5 and VOC; however, by considering only the spikes in PM minute-by-minute data, the relation between time-average PM and allergens increases up to 0.71. This high value indicates the applicability of PM low-cost sensors in laboratory animal centers as a warning sign of raising values of allergens. Mouse and rat allergens are present in the animals' urine, which can become aerosolized during animal activity, or task activities carried out in the laboratory facility. While previous references established a correlation between activities and mouse and rat allergens, the results are outdated and refer to a limited number of activities. For example, washing lab coats, changing uniforms, sitting in an office space, having lunch, or walking in any corridor are shown in this study to contain on average 1.77, 0.96, 0.65, 0.88, and 1.62 ng/m 3 of rat allergens, respectively. Thus, locations that do not contain any direct source of allergens are positive to the presence of mouse and rat allergens. Keywords Rat and mouse allergies • Task-based allergens • Particulate matter • Volatile organic compound • Real-time monitoring * Alberto Baldelli,

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“…Currently, no exposure limits are suggested for PM 4 . PM 2.5 is also respirable and it is studied by the majority of references focused on IAQ [16,24,29]. PM 2.5 has a PEL of 24-h TWA of 35 µg/m 3 according to US EPA [14].…”

Section: Introductionmentioning

confidence: 99%

Occupational exposure of librarians to mold spores and metal particles: a real-time case study

et al. 2021

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In a university library, activities typical of librarians, such as unpacking boxes, removing books from the shelves, dusting, packing boxes, cataloguing, conservation and repair, photocopying, setting materials for class, and walking in a main hallway, were found to reduce indoor air quality through the production of airborne mold spores, metal dusts, and particulate matter of different size bins. Analyzing three libraries, the activity of conservation generated 9000 spores/m3 of mold spores, nearing the exposure limit of 104 spores/m3 reported for Penicillium sp., and silver nanoparticles of about 15 µg/m3, that over 8 h would exceed the occupational exposure limit of 0.19 µg/m3. For none of the activities, the levels of particulate matter with a diameter lower than 2.5 µm (PM2.5) and 10 µm (PM10) did not exceed the 8-h time weight average limits of exposure. However, by analyzing the 5th percentile of the real-time PM10 data, values of about 1.5 mg/m3, which is concerning for occupational exposure. Measuring real-time exposures of PM could generate an estimation of levels of mold spores and metal dusts in libraries. We demonstrate a high Spearman’s rank correlation (0.70) between the 5th percentile of PM with a diameter lower than 1 µm and different metals. A high linearity (R2 = 0.85) is obtained between the total average of PM with a diameter lower than 10 µm and mold spores/m3.

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Enhanced Evaporation of Microscale Droplets With an Infrared Laser

Cited by 18 publications

References 36 publications

Real-time measurements of formaldehyde emissions in a gross anatomy laboratory

Real-time measurements of formaldehyde emissions in a gross anatomy laboratory

Particle matter, volatile organic compounds, and occupational allergens: correlation and sources in laboratory animal facilities

Occupational exposure of librarians to mold spores and metal particles: a real-time case study

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