N95 respirator mask breathing leads to excessive carbon dioxide inhalation and reduced heat transfer in a human nasal cavity

Salati, Hana; Khamooshi, Mehrdad; Vahaji, Sara; Christo, Farid; Fletcher, David F.; Inthavong, Kiao

doi:10.1063/5.0061574

Cited by 33 publications

(38 citation statements)

References 43 publications

(31 reference statements)

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“…Those elevated carbon dioxide levels of inhaled air, particularly under N95 masks, have also been found in physiologic relevant short-time modeling studies. This confirms a constant increase leading to an averaged 1% inhaled CO 2 per breath during simulations of eight breathing cycles in 33.65 seconds [21] (see Figure 8 of mentioned publication with animation of CO 2 distribution with and without a respirator). Another modeling study shows that wearing N95 masks results in carbon dioxide accumulation, the volume fraction of CO 2 reaches 1.2% after 7 breathing cycles and is then maintained at 3.04% on average.…”

Section: Effects Of Masks On Carbon Dioxide Re-breathingsupporting

confidence: 71%

“…Secondly, the CO 2 sampling point chosen by Geiss above the tip of the nose on the bridge of the nose is suboptimal for mask measurements. This is because it is not close enough to the openings involved in breathing, which are shielded from the rest of the dead space of the mask by the protruding tip of the nose (see figure 1A in Geiss publication to illustrate the questionable placement of sensor [26] and compare it to the gas distribution video in Salati [21]). Thirdly, it is not optimal to place the sampling point at the highest point.…”

Section: Effects Of Masks On Carbon Dioxide Re-breathingmentioning

confidence: 99%

“…Thirdly, it is not optimal to place the sampling point at the highest point. This is because carbon dioxide is heavier than other air components (approximately 44 g/mol in CO 2 compared to 32 g/mol in O 2 and 28 g/mol in N 2 ) and could accumulate there over time to a lesser extent than in the lower parts of the dead space of the mask [21]. In contrast, Butz provided a positioning of the sensor close to the mouth attached to the cheek [18], like Blad [20] and Sinkule [23], who placed it close to the breathing orifice (mouth opening), while Rhee and Roberge chose the nasolabial fold [25,27].…”

Section: Effects Of Masks On Carbon Dioxide Re-breathingmentioning

confidence: 99%

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Possible toxicity of chronic carbon dioxide exposure associated with mask use, particularly in pregnant women, children and adolescents -a scoping review

Kisielinski¹,

Wagner

Hirsch

et al. 2022

Preprint

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Literature was systematically reviewed regarding CO exposure and facemask use. Observational and experimental data are helpful for a risk-benefit assessment for masks as a popular non-pharmaceutical intervention against SARS-CoV2 in the populace. Masks impede breathing by increasing the resistance and dead space volume leading to a re-breathing of CO with every breath taken. Fresh air has around 0.04% CO, while wearing masks more than 5 minutes bears a possible chronic exposure to carbon dioxide of 1.41% to 3.2% of the inhaled air. Although the buildup is usually within the short-term exposure limits, long-term consequences must be considered due to experimental data. US Navy toxicity experts set the exposure limits for submarines carrying female crews to 0.8% CO based on animal studies indicating an increased risk for stillbirths. Additionally, in mammals chronically exposed to 0.3% CO experimental data demonstrates teratogenicity with irreversible damage of neurons and reduced spatial learning caused by brainstem neuron apoptosis and a reduced blood level of the insulin-like growth factor 1. With significant impact on three readout parameters (morphological, functional, marker) this chronic 0.3% CO exposure has to be defined as being toxic. Additional data exists on the exposure of chronic 0.3% CO in adolescent mammals causing neuron destruction, which includes less activity, increased anxiety and impaired learning and memory. There is a possible negative impact risk by imposing extended mask mandates especially for vulnerable subgroups. Circumstantial evidence exists that extended mask use may be related to current observations of stillbirths and to reduced verbal motor and overall cognitive performance in children born during the pandemic. Extended masking in pregnant women, children and adolescents has not been thoroughly tested and studied. As a result of the animal experimental data available, a risk-benefit analysis is urgent and a need exists to rethink mask mandates, which provide appropriate warnings.

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Section: Effects Of Masks On Carbon Dioxide Re-breathingsupporting

confidence: 71%

Section: Effects Of Masks On Carbon Dioxide Re-breathingmentioning

confidence: 99%

Section: Effects Of Masks On Carbon Dioxide Re-breathingmentioning

confidence: 99%

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Possible toxicity of chronic carbon dioxide exposure associated with mask use, particularly in pregnant women, children and adolescents -a scoping review

Kisielinski¹,

Wagner

Hirsch

et al. 2022

Preprint

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“…Aerosol generation from coughs has inspired many studies to investigate the droplet-laden cough jet and puff dynamics through experimental and computational methods, 3–6 as well as review articles of the fluid dynamics of respiratory droplets 7–9 and mitigation strategies for reducing viral transmission. 10,11 …”

Section: Introductionmentioning

confidence: 99%

Large eddy simulation of cough jet dynamics, droplet transport, and inhalability over a ten minute exposure

et al. 2021

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High fidelity simulations of expiratory events such as coughing provide the opportunity to predict the fate of the droplets from the turbulent jet cloud produced from a cough. It is well established that droplets carrying infectious pathogens with diameters of remain suspended in the air for several hours and transported by the air currents over considerable distances (e.g., in meters). This study used a highly resolved mesh to capture the multiphase turbulent buoyant cloud with suspended droplets produced by a cough. The cough droplets' dispersion was subjected to thermal gradients and evaporation and allowed to disperse between two humans standing 2 m apart. A nasal cavity anatomy was included inside the second human to determine the inhaled droplets. Three diameter ranges characterized the droplet cloud, , which made up 93% of all droplets by number; 5 to 100 μ m comprised 3%, and m comprising 4%. The results demonstrated the temporal evolution of the cough event, where a jet is first formed, followed by a thermally driven puff cloud with the latter primarily composed of droplets under 5 μ m diameter, moving with a vortex string structure. After the initial cough, the data were interpolated onto a more coarse mesh to allow the simulation to cover ten minutes, equivalent to 150 breathing cycles. We observe that the critical diameter size susceptible to inhalation was , although most inhaled droplets after 10 min by the second human were approximately . These observations offer insight into the risk of airborne transmission and numerical metrics for modeling and risk assessment.

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“…This result is in agreement with some current studies showing increased CO 2 levels inside an N95-type respirator. 29,30 …”

mentioning

confidence: 99%

Infrared-based visualization of exhalation flows while wearing protective face masks

Koroteeva

Shagiyanova

2022

Physics of Fluids

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Since the onset of the COVID-19 pandemic, a large number of flow visualization procedures have been proposed to assess the effect of personal protective equipment on respiratory flows. This study suggests infrared thermography as a beneficial visualization technique because it is completely noninvasive and safe and, thus, can be used on live individuals rather than mannequins or lung simulators. Here, we examine the effect of wearing either of three popular face coverings (a surgical mask, a cloth mask, or an N95 respirator with an exhalation valve) on thermal signatures of exhaled airflows near a human face while coughing, talking, or breathing. The flow visualization using a mid-wave infrared camera captures the dynamics of thermal inhomogeneities induced by increased concentrations of carbon dioxide in the exhaled air. Thermal images demonstrate that both surgical and cloth face masks allow air leakage through the edges and the fabric itself, but they decrease the initial forward velocity of a cough jet by a factor of four. The N95 respirator, on the other hand, reduces the infrared emission of carbon dioxide near the person's face almost completely. This confirms that the N95-type mask may indeed lead to excessive inhalation of carbon dioxide as suggested by some recent studies.

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N95 respirator mask breathing leads to excessive carbon dioxide inhalation and reduced heat transfer in a human nasal cavity

Cited by 33 publications

References 43 publications

Possible toxicity of chronic carbon dioxide exposure associated with mask use, particularly in pregnant women, children and adolescents -a scoping review

Possible toxicity of chronic carbon dioxide exposure associated with mask use, particularly in pregnant women, children and adolescents -a scoping review

Large eddy simulation of cough jet dynamics, droplet transport, and inhalability over a ten minute exposure

Infrared-based visualization of exhalation flows while wearing protective face masks

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