Due to the complexity of the nail salon work environment, traditional approaches to exposure assessment in this context tend to mischaracterize potential hazards as nuisances. For this investigation, a workable “indoor air” approach was devised to characterize potential hazards and ventilation in Boston, Massachusetts area nail salons which are primarily owned and staffed by Vietnamese immigrants. A community-university partnership project recruited salons to participate in a short audit which included carbon dioxide measurements and evaluation of other air quality metrics. Twenty-two salons participated. Seventy-three percent of the salons had spot carbon dioxide measurements in excess of 700 ppm, the level corresponding to a ventilation rate recommended for beauty salons. Fourteen salons (64%) did not have a mechanical ventilation system to provide fresh air and/or exhaust contaminated air. The lack of adequate ventilation is of significant concern because of the presence of potentially hazardous chemicals in salon products and the common self-report of symptoms among nail technicians. Community and worker health may be improved through adoption of recommended ventilation guidelines and reduction in the hazard potential of nail products.
Over the past 20 years, nail salons have become a common feature of American towns, malls, and city neighborhoods. The rapid growth of the industry has been fueled by the immigration to the United States of Vietnamese and other Asians who have built an economic niche in affordable manicures, pedicures, and artificial nails [
Nail products: chemical ingredients and potential health effects.
Nail products | Common chemical ingredients | OSHA PEL/(TLV if lower) (ppm) | Potential health effects |
---|---|---|---|
Ethyl acetate | 400 | Irritation eyes, skin, nose, throat; dermatitis | |
Butyl acetate | 150 | Irritation eyes, skin, upper respiratory system; headache | |
Ethyl alcohol | 1000 | Irritation eyes, skin, nose; headache, CNS syndrome; cough; liver damage; anemia; reproductive effects | |
Isopropyl alcohol | 400 | Irritation eyes, nose, throat; CNS syndrome, headache; dry, cracking skin | |
Acetone | 1000 [250] | Irritation eyes, nose, throat; headache; CNS syndrome; dermatitis | |
Methyl ethyl ketone | 200 | Irritation eyes, nose, throat; headache; CNS syndrome; dermatitis | |
Nail polish (basecoat, colors, | Toluene | 200 [50] | Irritation eyes, nose, throat; headache; CNS syndrome; dermatitis; dilated pupils, lacrimation; anxiety, muscle fatigue, insomnia; paresthesia; liver, kidney damage; |
Xylene | 100 | Irritation eyes, nose, throat; headache; CNS syndrome; corneal damage; dermatitis; reproductive effects | |
Dibutyl phthalate | 5 mg/m3 | Irritation eyes, upper respiratory system, stomach; reproductive effects (fetotoxic) | |
Nitrocellulose | None [400] | Unknown | |
Toluene Sulfonamide Formaldehyde Resin | None | Dermatitis | |
Titanium dioxide | 10 mg/m3 | Lung fibrosis; potential occupational carcinogen | |
Nail polish removers | Acetone | 1000 [250] | See above |
Ethyl acetate | 400 | See above | |
Butyl Acetate | 150 | See above | |
Ethyl methacrylate | None | Irritation eyes, skin, nose, throat; allergic contact dermatitis; asthma | |
Artificial nails | Methyl methacrylate | 100 [50] | Irritation eyes, skin, nose, throat; allergic contact dermatitis; asthma |
Butyl methacrylate | None | Irritation eyes, skin, nose, throat; allergic contact dermatitis; asthma | |
Methacrylic acid | None [20] | Irritation eyes, skin, mucous membrane; eye, skin burns | |
Methyl ethyl ketone | 200 | See above | |
Nail tips adhesives | Ethyl cyanoacrylate | None [0.2] | Irritation eyes, skin, nose, throat; allergic contact dermatitis; asthma |
Artificial nail removers | Acetone | 1000 [250] | see above |
N-methyl pyrrolidone | None | Dermatitis, reproductive effects | |
Acetonitrile | 40 [20] | Irritation nose, throat; asphyxia; nausea, vomiting; chest pain; CNS syndrome; convulsions; in animals: liver, kidney damage | |
Nail hardener | Formaldehyde |
The inherent properties of nail product ingredients support the concern about the health of people working often very long work weeks in salons. The toxicity of many ingredients in nail products is clearly established (see Table
Few formal industrial hygiene exposure assessment studies have been conducted in nail salons. However, those researchers who have sampled air contaminants have consistently found that nail salon workers are exposed to multiple potentially hazardous chemicals, but at low levels when individual chemicals levels are compared to US Occupational Safety and Health Administration (OSHA) Permissible Exposure Limits and other standards (see Table
Summary of air contaminant levels in nails salons.
Occupational exposure limits | Mean 8 hr time weighted Avg concentrations | ||||||
OSHA PEL | ACGIH TLV | NIOSH IA | NIOSH IIB | Froines and GarabrantC | Hiipakka and SamimiD | MaxfieldE | |
Vapors (ppm) | |||||||
MMA | 100 | 50 | n.d. (<3.6) | 5.3 | |||
(vented) | |||||||
EMA | None | None | 9.4 | 7.0 | 7.3 | 4.5 | |
(vented) | 0.7 | ||||||
Toluene | 200 | 50 | 0.8 | ||||
Isopropyl Alcohol | 400 | 400 | 15.6 | ||||
Butyl Acetate | 150 | 0.4 | |||||
Acetone | 1000 | 10.0 | |||||
Nuisance dusts (mg/m3) | |||||||
Unvented, hand filing | 0.15 | ||||||
Unvented, Machine filing | 15 | 10 | 1.4 | 0.28 | |||
Vented, Machine filing | 0.24 |
A[
Several chemicals (methacrylates, acetone) used in nail salons emit vapors that have low odor thresholds. Under certain conditions, these odors can be detectable in adjacent businesses. However, concentrations of these vapors, as measured on the day of the NIOSH survey, do not constitute a health hazard to the workers and customers of at Tina and Angela’s Nail salon or to adjacent businesses.
Despite failing to find hazardous exposures, like other investigators, NIOSH recommended that salons assure adequate ventilation—both general and local exhaust—to provide fresh air and the exhausting of contaminated air.
While salon chemical concentrations are unlikely to exceed established exposure limits, work-related health complaints by nail salon workers are common. One survey of Boston area nail technicians found that self-reported work-related health symptoms such as skin and respiratory irritation, difficulty breathing, headaches, and trouble concentrating were reported by significant percentages of the workers surveyed (see Table
Self-reported work-related* health effects and among Vietnamese-American nail technicians (
Health effect | Frequency (%) |
---|---|
Respiratory irritation | 16 (23%) |
Difficulty breathing | 8 (11%) |
Any respiratory symptom (difficulty breathing, regular cough, sinus/nasal, irritation) | 21 (30%) |
Headaches | 31 (44%) |
Difficulty concentrating | 20 (28%) |
Allergic to something at work | 17 (25%) |
Seen a doctor for work-related health problem | 15 (21%) |
*
Source: [
Though limited in number and scope, other studies have also found health effects in this worker population: Hiipakka and Samimi’s symptom survey of 20 nail technicians and controls found greater prevalence of respiratory irritation in nail technicians [
As in the case of troublesome indoor air quality in office environments, a finding of low exposure levels in nail salons may not equate to a finding of a healthful work environment. Indeed, chemical-by-chemical exposure assessment in nail salons is not likely to answer questions about the relevance of exposures to potential health effects. Exposures are likely to be to a mixture of multiple chemicals, chemicals in vapor and dust forms, and to chemicals without exposure limits or accepted epidemiological findings. Air contaminant sampling and comparison to occupational exposure limits cannot generally address the effects of chemicals most relevant to salon exposures and workers: skin absorption, skin contact, sensitization, reproductive health concerns, headaches, neuropsychological effects, and/or respiratory, dermal, or sensory irritation. Additionally, the diversity of potential salon exposures and exposure factors (e.g., range of products, extended hours of work) would require an extraordinary number of samples in order to establish reference frameworks that would assure baseline safety. Even such results would expire rapidly as products changed.
Given these contextual factors, an “indoor air” approach to exposure assessment was suggested for evaluation of the nail salon work environment. This study piloted a qualitative assessment strategy that would quickly identify the presence or absence of various relevant exposure determinants: the presence of volatile toxic compounds, disagreeable odors, inadequate ventilation, and health complaints related to nail salon work that might suggest an extreme type of indoor air quality problem and distinguish between “better” and “worse” conditions [
The American Society of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE) recommends that beauty salons maintain 25 cubic feet per minute (cfm) (0.71 cubic meter per minute) of fresh air per person via mechanical ventilation [
Our project, like others, faced challenges in conducting research in the nail salon setting [
Short air quality audits were conducted in 22 salons over three months in early summer 2006 in the Greater Boston area. The field researcher (one of the authors) is occupational health graduate student and a native Vietnamese speaker. Though a convenience sample, salons were selected from different geographic areas that represent the distribution of salons throughout the area. Five salons were recruited to participate by one of the authors. Of these five, four had been featured in a marketing, outreach, and education project conducted by the university-community partnership: the “Healthy Nail Salon Work Environment” bilingual calendar. In addition to recruiting from Viet-AID’s network, several salons were recruited “on-the-spot.” The field researcher approached salons during nonbusy periods and requested participation in the audit. Of the 47 that were approached, 17 agreed to participate. All salon representatives signed Informed Consent Forms in Vietnamese or English approved by the University of Massachusetts Institutional Review Board. Participating salons received a copy of the calendar, a $20 grocery store certificate, and a full report in English and Vietnamese on the findings of the audit and recommendations for air quality improvement.
The audit recorded basic business information as provided by a salon owner or worker, the researcher’s observations of air movement equipment and natural ventilation, and measured temperature, humidity, and carbon dioxide level. Carbon dioxide level was used as a surrogate for the salon’s ventilation rate. In an occupied space, carbon dioxide levels can be compared to natural outside levels (300–600 ppm) to evaluate the adequacy of fresh air (people are the principal source of carbon dioxide indoors). Temperature, humidity, and carbon dioxide were measured with a calibrated TSI Q-Trak monitor. The monitor was placed in the work area and allowed to equilibrate without any person within three feet of the monitor. Audit data was transferred to an Excel spreadsheet and basic analysis was conducted within Excel.
The salons in the sample had been in business on an average of four and a half years and none had operated more than 10 years. Two salons were primarily hair salons and had only one manicure table and one manicurist. Most dedicated nail salons had five or more tables and three or more pedicure stations. Three or four nail technicians usually worked in each salon with one salon having as many as 10 workers. Additional nail technicians are usually called in on a Saturday, the busiest day, when these salons averaged 32 manicures and as many as 100. Seventeen out of the 22 salons performed artificial or “sculpted” nail services and the average amount of “nail liquid,” the intensely odorous ethyl methacrylate monomer, used by these shops in a month was 24 ounces. Almost all of the shops visited were storefronts; two others were in malls and another was in the upper floor of a building.
Of the 22 salons in our survey, eight had some form of mechanical ventilation. Although the field researcher was not able to verify that these systems delivered fresh air or that these systems were appropriately designed and operated, he did verify that these systems were functional. As shown in Table
Ventilation characteristics of 22 Boston area nail salons.
Mechanical ventilation | Yes | 8 | 36% |
No | 14 | 64% | |
Ventilation working | Verified | 9 | 41% |
Do not know | 13 | 59% | |
Local exhaust | Yes | 1 | 5% |
No | 21 | 95% | |
Other ventilation (salons using) | Room a/c | 20 | 91% |
Open doors/windows | 13 | 59% | |
Air purifyers | 5 | 23% | |
Room fan | 4 | 18% | |
Exhaust fan | 5 | 23% | |
Table fan | 12 | 55% | |
Shop volume (cubic feet) | Average | 5,674 | |
Low | 1,639 | ||
High | 15,561 |
Table
Air quality metrics in Boston area nail salons (
Temperature (degrees Fahrenheit) | Average | 78 |
Low | 57 | |
High | 90 | |
Relative humidity % | Average | 48 |
Low | 24 | |
High | 73 | |
Carbon dioxide (ppm) | Average | 893 |
GM | 845 | |
Low | 470 | |
High | 1550 | |
700 ppm or more | 16 | |
1000 or more | 6 | |
Number of occupants (including survey staff) | Average | 7 |
Low | 2 | |
High | 14 |
In 27% of the salons, spot carbon dioxide readings exceeded 1000 ppm, the level determined by NIOSH and EPA to indicate inadequate ventilation of generally uncontaminated occupied spaces [
Adequate general ventilation in public and work places is important regardless of the potential contaminants in those spaces. While the small number of salons in our sample prevents us from generalizing, it is likely that most nail salons do not have adequate general ventilation, despite the presence of ventilation systems in some, and a combination of other air moving equipment, such as room air conditioners in others. The lack of adequate ventilation is of significant concern because of the presence of potentially hazardous chemicals in salon products and the common self-report of symptoms among nail technicians.
This is the first study of its kind to evaluate basic business, indoor air quality, and exposure metrics in nail salons. Although this study collected data from a small nonrandom sample of salons and took a limited number of measurements per salon, some basic information was obtained that will serve salon owners, public health advocates, and consumers in their efforts to understand and address the potential hazards in this popular business. In keeping with the public health mandate to reduce hazards at the source, consumer advocates have pressured some manufacturers to reduce the odor, volatility, toxicity, and hazard potential of nail products and some have done so, particularly in response to new European restrictions on toxic cosmetics ingredients (see
Chemical-by-chemical industrial hygiene monitoring is not recommended for exposure assessment in nail salons except, perhaps, in the context of epidemiological studies. Nail technicians are unlikely to be “overexposed” as defined by exposure level standards and such an approach will miss the potential overexposures resulted from mixed chemicals, multiple forms of chemicals, absence of adequate general ventilation, and exposures to chemicals that are absorbed through the skin or cause sensitization (such as dermatitis), reproductive effects, or acute or chronic irritation. Instead, what is recommended is an indoor air exposure assessment strategy to evaluate work environment factors that suggest a potential for health problems and point to workable solutions. This walkthrough audit and interview method looks for sources of potential hazards, including the presence of volatile organic solvents, sensitizing or dermally-absorbed chemicals with recognized toxicities; performs a simple evaluation of work space ventilation; catalogs reported symptoms related to time spent in the salon. The results of this nontechnical assessment could form the basis of recommendations to the salon owner, distinguish between “better” and “worse” salons from the perspective of workers and customers, and advise public health advocates on helpful policy and educational approaches including advocacy of reduction in hazard potential of nail products and promotion of adequate ventilation in salons.
The authors would like to thank the participating salons; Hoa Mai Nguyen and Hiep Chu; Anne Bracker; Drs. Lenore Azaroff, Susan Woskie, and Michael Ellenbecker. The National Institute for Occupational Safety and Health funded this research under Grant K01 OH007956-01. The authors have no conflicts of interests or financial interest in any commercial entity related to this paper.