Skip to main content

Protocol of a randomized controlled trial of hearing protection interventions for farm operators

Abstract

Background

Hearing loss and tinnitus are prevalent in America, and noise-induced hearing loss is a leading cause of hearing loss. Noise-induced hearing loss has negative impact on quality of life, physical and emotional functioning, social life, and employment. In addition, noise-induced hearing loss results in heavy social and economic burdens on families and communities from all ethnic and socioeconomic groups. Farmers are a group that is particularly high risk for noise-induced hearing loss, and is underserved by programs designed to limit that risk. They are among the most noise-exposed group of workers, and experience the second highest prevalence of noise-induced hearing loss among all occupational categories. In agriculture, 1.5 million workers (43.3%) report exposure to hazardous noise. Although use of hearing protection devices (HPDs) would protect them from noise-induced hearing loss, use among farmers is low.

Methods/Design

The purpose of this project is to compare the effectiveness of several approaches to influencing hearing protector use. Approaches include: a) an interactive, predictors-based intervention delivered via the Internet; b) a static informational web site; and c) a mailed sampler of hearing protectors. The goals are to further develop an intervention to promote farmers’ use of HPDs, and compare the effectiveness of the interventions delivered in various combinations. Participants will include 701 farmers. Sites will be affiliates of a major farmer organization. Data will be collected at baseline, 6, and 12 months. A random intercept mixed model will be used to explore the fixed effects of the three NIHL prevention interventions over time while adjusting for age and gender. This project will involve a partnership between the University of Michigan and a major farmer organization to accomplish project aims.

Discussion

Results of this study will be used to inform future research-to-practice studies to increase hearing protector use. Increased use of hearing protectors is expected to reduce rates of noise-induced hearing loss and other negative effects of high noise exposure, and improve quality of life in this high-risk and underserved group.

Trial registration

Clinicaltrials.gov NCT01454895 Registered 14 October, 2011.

Peer Review reports

Background

Noise-induced hearing loss (NIHL) is highly prevalent among US workers, particularly among farmers. An estimated 22 million workers are exposed to hazardous noise at work [1] and NIHL is among the most common work-related diseases, and the second-most self-reported occupational disease or injury [2]. Estimates of prevalence rates for NIHL among farmers vary greatly, and have been reported to be 17% [3], 22% [4], 38% [5], 65% [6], and 72% [7]. In comparison studies, farmers were more likely to have hearing loss than non-farmers [3,6,8].

NIHL is characterized by loss of hearing in higher frequencies; it is permanent and incurable, and typically progresses slowly and insidiously with continued exposure to high levels of noise. Most people are unaware that they are affected until it is already moderately severe [9].

NIHL has negative impact on the quality of life of the affected individuals as well as their families and communities, affecting physical and emotional functioning, social life, and employment. In addition, persons with NIHL frequently experience tinnitus, and have increased safety risks due to difficulty hearing warning sounds [10]. Importantly, hearing loss has also been associated with increased risk for injury among farmers [11].

Treatments for NIHL are limited and unsatisfactory, indicating that primary prevention offers the best option for success. Because NIHL is permanent and irreversible, treatment is limited to hearing aids for sound amplification. Most users find hearing aids expensive, unlike their natural hearing, and particularly unsatisfactory when there is background noise or when trying to focus on one speaker when there are other competing sounds [12].

Systems to protect workers from NIHL are not present in the farm work setting. Farmers are unique in that unlike workers in general industry, most farmers are not protected by the OSHA Hearing Conservation Standard (i.e., noise level monitoring and a hearing conservation program for at-risk employees which includes audiometric testing, training, and provision of hearing protection devices) [13]. Also, because most farms in the US are small, family-run organizations, there is no labor advocacy for worker hearing health and work-based health programs [14]. Many farmers may underestimate their exposure to noise hazards and consequences of noise exposure, and may not be knowledgeable about NIHL prevention techniques.

Noise elimination is the most preferred method of prevention of NIHL. However, this approach is often not technically or economically feasible in the farm work environment [14]. Consistent use of hearing protection devices is effective in preventing NIHL [15-17]. While there are several types of hearing protectors marketed (e.g., foam plugs, ear muffs), there is no “best” type of hearing protection; the “best” is the one the user prefers and will wear.

The problem of NIHL has been identified as a priority by federal agencies, including Healthy People 2020 [18], the National Institute for Occupational Safety and Health [19], and the National Institutes for Deafness and Communication Disorders [20].

There is evidence that interventions are needed, and can be successful in relieving this problem without negative impacts and at low costs. Use of hearing protectors is an effective method of preventing NIHL when engineering or administrative controls are not feasible or economical [21-23]. Epidemiological studies show that the need for interventions to increase hearing protector use among farmers is high, and that unlike some other worker groups, there is no ceiling effect limiting effectiveness of interventions [24-26]. Studies have identified predictors of hearing protector use among farmers, and have demonstrated that farmers are interested in increasing their use of hearing protectors [25]. Predictors-based and Internet-based interventions have been effective in other groups [27-31], and the proposed study seeks to apply this existing research to a test of interventions for farmers, a high risk and underserved group.

The proposed study takes advantage of existing organizations of farmers by partnering with the single largest farm organization in the US. This partnership will serve to optimize recruitment and retention of participants while minimizing costs. Members of the farm organization are farm operators; many are employers of farm laborers and therefore influential in determining the use of hearing protectors by laborers.

The proposed study will answer important questions in development of behavioral interventions to widely dispersed populations. It will connect with participants through their trade association together with using Internet-based health information. These methods have potential for reaching an otherwise difficult-to-reach rural and widely dispersed population. Together with an efficacious intervention, the program has potential for excellent health impact. Results from the proposed study will provide a model for future behavioral intervention research in a dispersed population and create new approaches for the prevention of NIHL, a serious preventable impairment.

Theoretical framework: the farmers’ use of hearing protection model

A variety of factors have been found to be predictors of HPD use in multiple studies of workers, including farmers. These factors are included in the Farmers’ Use of Hearing Protectors Model (Figure 1), and serve as a guide for the proposed study. In a previous study [25], this parsimonious model was effective in predicting HPD use in 74% of cases.

Figure 1
figure 1

Predictors of farmers’ use of hearing protection model.

Perceived Barriers to HPD Use are impediments [32] resulting in discomfort or difficulty in communication, and have consistently shown a negative and significant relationship to HPD use in studies of factory workers [33], construction workers [32,34], and farmers ([24,25,35], McCullagh, MC.: Farmers’ preference for use of hearing protectors, unpublished), Perceived Benefits of HPD Use are users’ ideas about the positive consequences of HPD use. Benefits were found to be positively related to HPD use in studies of factory and construction workers [32,33] and farmers [24]. Availability (and accessibility) of HPDs have had a positive and significant relationship to HPD use in studies of industrial workers [33] and farmers [24,25,35]. Self-efficacy of HPD Use is the extent to which an individual has confidence in one’s own ability to use HPDs [32], has had a positive and significant relationship to HPD use in studies of factory [33] and construction workers [32]. Two studies of farmers [24,25] showed a positive, but non-significant relationship between self-efficacy and HPD use. Interpersonal Influences are the individual’s perceptions of the behaviors, beliefs or attitudes of others, operationalized in three subscales: Interpersonal Norms, Modeling, and Support [32]. Interpersonal Norms are the respondents’ beliefs about how much others think they should wear hearing protection. Interpersonal Support refers to encouragement or praise from family, friends, and coworkers about the respondents’ use of hearing protection. Interpersonal Modeling is how much respondents believe family members and other farmers use hearing protection when exposed to noise. Administration of the Farmers’ Interpersonal Influences on Use of HPDs Scales (“Norms,” “Modeling,” and “Support”) showed significant and positive relationships to HPD use in the convenience sample of farmers [24], but not in a random sample of farmers [25].

Demographic Factors (age and gender) are non-modifiable factors, but important to assess. In one survey of farmers [24], women reported use of HPDs more frequently, while other studies [25,36] indicated men are more frequent users. Age was found to have a non-significant relationship to HPD use in two studies [24,25]. There are no published studies examining the relationship between race or ethnicity and HPD use.

A limited number of studies have found other factors (e.g., noise annoyance [37], perceived susceptibility to NIHL [37], perception that health problems were preventable [35]) to have a significant relationship to HPD use in non-farming samples. Perceived negative effects of NIHL on family was significantly related to HPD use in a sample of farmers [26].

Methods

Overview of design and methods

The purpose of this project is to identify interventions that will increase the use of HPDs, thereby reducing NIHL. The specific aim of this study is to contrast the effects of three alternative strategies (“Interactive Web,” IWI a “Static Web,” SWI, and a sampler of HPDs, HPD I) in various combinations, on HPD use and use-related attitudes/beliefs. The study uses a randomized-controlled design. It will be conducted in partnership with a major farmer organization. The University Health and Behavior Science IRB reviewed the study protocol and determined that it is exempt from ongoing IRB review.

Sample, enrollment, and retention

Participants in this study will be farm operators age 18 or older, who are active in production at least 20 hours per week on average, have ability to read English, and have computer and Internet access. A farm operator is the person who runs the farm, making the day-to-day decisions [38].

One or more study team members will attend selected farm trade group meetings to recruit subjects. Recruitment will continue until the enrollment quota is met. Prospective subjects will log onto a designated Web site, where the enrollment process will be managed. In addition to the data collected from direct user entry during enrollment, metadata will also be collected for use in later analysis.

Random assignment to study conditions

After participants provide informed consent and enroll in the study, they will be assigned to the five study conditions (Table 1) by a random assignment of treatments in blocks produced by Stata software [39]. Recruitment will continue until the enrollment quota is met, resulting in five approximately equal-sized groups.

Table 1 Study Conditions

Follow-up

At 6 and 12 months, participants in all five groups will receive an invitation by e-mail to log on to complete post-tests online.

Interventions

The study compares five prospective parallel groups receiving three distinct interventions, delivered in various combinations (Table 1). Participants in Groups 1 and 3 will be offered (Interactive or Static) Web-based information and, following verification of completion, a sampler of HPDs will be supplied to them. Participants in Groups 2 and 4 will be offered (Interactive or static) Web-based information and asked to verify completion. Participants in Group 5 will simply receive a sampler of HPDs on completion of the pretest.

Interactive Web Intervention (IWI)

This intervention will include targeted messages focusing on farmer-friendly techniques for adopting use of HPDs, interactive learning techniques (e.g., sound level meter), role modeling techniques (e.g., farmer testimonials), and cognitive, demonstration, persuasion techniques. Intervention delivery is not linear; participants will select the sequence of features they visit, as well as the time spent in each feature and number of visits to the site. Their patterns of use will be tracked by the enrollment and data collection systems and used in analysis.

The standard (“static”) information promoting HPD use delivered via Internet will consist of a previously developed informational brochures (i.e., Have You Heard? [40] and They’re Your Ears Protect Them [41].

The proposed study will provide a sampler of HPDs to a sub-sample of each group of farmers receiving the Interactive and Static Web Interventions and to a group of farmers who do not receive a web based intervention. The sampler will include the most commonly-used types of devices (i.e., muffs, foam plugs, pre-molded plugs, and semi-aurals).

The study will include development of the informational Web site, inclusive of elements previously developed (e.g., video testimonials and HPD insertion techniques, animated graphics). Near final systems will be tested with a sample of the target population (confirmative testing interviews). Fidelity of the intervention is assured because delivery of information via the Internet ensures a consistent presentation of the Interactive and Static interventions.

Outcome measures

Outcome measures will include self-reported frequency of HPD use and related attitudes/beliefs, measured at 6 and 12 months post-intervention. The outcome variables for the study are based on the Predictors of Farmers’ Use of Hearing Protection Model and include cognitive and affective factors that are specific to the behavior of HPD use (i.e., frequency of HPD use, perceived barriers, self-efficacy, access, interpersonal influences).

The HPD Use instruments (Appendix G) measuring the concepts from the theoretical model, together with their corresponding alpha reliability coefficients are described in Table 2. Development of these scales included pretest, revision, and review for construct validity by an expert panel; the process is described elsewhere [24,36]. All have alpha coefficients near or above .70. Additional variables measured will include demographic characteristics, functional hearing ability, satisfaction with the intervention, and social desirability bias (short form of the Marlowe-Crowne social desirability scale) [42].

Table 2 Scale Means, Standard Deviations, and Alpha Coefficients

Analysis and sample size estimates

Power analysis was conducted using PASS software [43] to determine the sample size needed to provide 80% power to detect important effects that we expect to see in the research, based on comparisons between conditions with alpha of .05 two tailed, given findings from past studies. Given how low use of HPDs is among farmers, we expect to produce and detect changes of 13% in percent time use between conditions with a standard deviation of .3, thus an effect size d of .43 which is a bit smaller than what Cohen (1992) defined as medium sized. A sample size of 85 per group is needed to have 80% power to detect an effect size d = .43. With a second posttest at 12 months we have allowed for a loss of up to 40%, so will recruit 709 subjects total to retain 425 or 85 per group.

Data analysis plan

Descriptive statistics will determine frequency distributions, percentage distributions, and means and standard deviations. Distributions of variables will be examined to detect and correct values outside of the legal range. They will also be examined for the normality of their distribution and transformed as appropriate so they meet the assumptions of the statistical analysis. Cronbach’s alphas will be used to assess internal consistency of multiple item scales as a measure of reliability. Scales with alphas of at least .63 will be considered usable. The various experimental groups will be compared on baseline values of variables. Independent variables found to differ between groups at baseline will be added to the analyses as covariates.

A random intercept mixed model will be used to explore the fixed effects of the three NIHL prevention interventions over time adjusting for age and gender as covariates. The model will include a random intercept for subjects to control for non-independence of repeated measures. A compound symmetric covariance structure will be specified in the model. Each of the outcomes: use of HPDS, attitudes, and beliefs will be modeled separately in order to investigate the effects of web interventions and mailed hearing protection devices. The data will be analyzed within two research designs. First will be the complete factorial design 2 (interactive vs. static web) x 2 (sent HPDs) x 3 (times: baseline, 6 months, and 12 months). This will not include the condition in which participants are simply sent HPDs. The second design will include all conditions in an incomplete factorial 3 (interactive web vs, static web vs. no web) X (sent HPDs) x 3 (times: baseline, 6 months, 12 months). SAS 9.3 (SAS Institute Inc., Cary, NC, USA) and SPSS 22 will be used for all analyses. A p-value of < .05 will indicate statistical significance.

Tests of hypotheses 1 and 2

  1. 1.

    Participants receiving interactive Web interventions will have higher HPD use and more favorable use-related attitudes/beliefs than participants not receiving Interactive Web interventions;

  2. 2.

    Participants receiving the mailed HPD Intervention will have higher HPD use and more positive use-related attitudes/beliefs than participants not receiving the mailed HPD Intervention.

The dependent measures used for all the aims are quantitative variables: the individual’s percentage of time using HPDs, and relevant attitudes/beliefs, as outlined in Table 1. Either before or after transformation they will be normally distributed so will be analyzed by linear random intercept mixed models.

All analyses to test Hypotheses 1 and 2 will include baseline data collection and will focus on the tests of interactions of time with web format and with sending HPDs. Tests of these interactions with time will indicate whether changes over time are equivalent in different groups, for example whether participants exposed to the interactive web intervention increased use of HPDs more than participants exposed to the static web intervention. Follow-up analyses will present mean use and mean scores on attitudes/beliefs by time and condition as estimated by the mixed model. The same analysis focusing on different interactions with time will be conducted to test hypothesis 2. Naturally, they will test the interactions of time with provision of HPDs to test the hypothesis that provision of HPDs will increase use and improve use-related attitudes/beliefs.

Test of hypothesis 3: participants visiting the Web site more frequently will have higher HPD use than those visiting less frequently

We will assess the number of times that each individual accesses the Website and test the effect of number of views (separately for the Interactive Web Intervention and Static Web Intervention). We suspect that people with more exposures to the Website will show more impact of it (for both the Interactive Web Intervention and Static Web Intervention). However we do not expect the number of visits to be great so do not expect to have power to detect these effects. The method of analysis will depend on the distribution of number of visits. If there is little variability in number of visits this will be treated as a dichotomous predictor variable. If more variable, it will be treated as a continuous predictor. Whether significant or not, results will provide evidence about how the Interactive and Static Web Interventions work.

Test of hypothesis 4. There will be no interaction between intervention delivery mode (interactive vs. Static) and the mailed HPD intervention

Analyses to test Hypothesis 4 will be conducted by a 2 (Interactive Web vs Static Web) x 2 (providing HPDs) x 3 (times: within subjects) random intercept linear mixed model. The condition of mailed HPD intervention will not be included in these analyses. As with analysis of the other hypotheses, the focus is on the interaction(s) with time. Inclusion of a pretest time in the design and analysis means that the analysis is really about changes over time. In analyses to test Hypothesis 3, the key question is whether the changes over time are different in the group that receives both the Interactive Web Intervention and HPDs than would be expected by adding the effects of Interactive Web Intervention and supply of HPDs. The significance test of the three-way interaction will test this. We hypothesize that this three-way interaction will not be significant. However a significant interaction would be interesting, too.

Discussion

The proposed study is novel in that it focuses on a population in which there is no previously reported randomly controlled trials promoting HPD use. It is also unique in that it compares the effectiveness of previously untried (targeted, Web-based, mailed) interventions to increase HPD use.

This RCT test of interventions is designed to determine the most effective approach to increasing participants’ HPD use. The moderately large, randomly-selected sample offers an opportunity to compare effectiveness of several approaches, and to generalize results to the larger population. Results will also determine the need for future program modifications, e.g., test of booster(s). Further, given a successful test of the new interactive intervention in this project, there is potential for dissemination to reach a larger number of farmers. Results of this study will inform future Web-based interventions, interventions aimed at dispersed populations, and interventions to increase use of personal protective equipment.

References

  1. Tak S, Calvert GM. Hearing difficulty attributable to employment by industry and occupation: an analysis of the National Health Interview Survey - United States, 1997 to 2003. J Occup Environ Med. 2008;50(1):46–56.

    Article  PubMed  Google Scholar 

  2. Conway H, Simmons J, Talbert T. The purposes of occupational medical surveillance in US industry and related health findings. J Occup Med. 1993;35(7):670–86.

    Article  CAS  PubMed  Google Scholar 

  3. Thelin JW, Joseph DJ, Davis WE, Baker DE, Hosokawa MC. High-frequency hearing loss in male farmers of Missouri. Public Health Rep. 1983;98(3):268–73.

    CAS  PubMed  PubMed Central  Google Scholar 

  4. Gomez MJ, Hwang SA, Sobotova L, Stark AD, May JJ. A comparison of self-reported hearing loss and audiometry in a cohort of New York farmers. J Speech Lang Hear Res. 2001;44(6):1201–8.

    Article  CAS  PubMed  Google Scholar 

  5. Stewart M, Scherer J, Lehman ME. Perceived effects of high frequency hearing loss in a farming population. J Am Acad Audiol. 2003;14:100–8.

    Article  PubMed  Google Scholar 

  6. Marvel ME, Pratt DS, Marvel LH, Regan M, May JJ. Occupational hearing loss in New York dairy farmers. Am J Ind Med. 1991;20(4):517–31.

    Article  CAS  PubMed  Google Scholar 

  7. Beckett WS, Chamberlain D, Hallman E, May J, Hwang SA, Gomez M, et al. Hearing conservation for farmers: source apportionment of occupational and environmental factors contributing to hearing loss. J Occup Environ Med. 2000;42:806–13.

    Article  CAS  PubMed  Google Scholar 

  8. Rabinowitz PM, Sircar KD, Tarabar S, Galusha D, Slade MD. Hearing loss in migrant agricultural workers. J Agromed. 2005;10(4):9–17.

    Article  Google Scholar 

  9. Morata TCD,DE. Occupational hearing loss. Occup Med. 1995;10(3):495–689.

    Google Scholar 

  10. Hetu R, Getty L, Quoc HT. Impact of occupational hearing loss on the lives of workers. Occup Med. 1995;10(3):495–512.

    CAS  PubMed  Google Scholar 

  11. Choi SW, Peek-Asa C, Sprince NL, Rautiainen RH, Donham KJ, Flamme GA, et al. Hearing loss as a risk factor for agricultural injuries. Am J Ind Med. 2005;48(4):293–301.

    Article  PubMed  Google Scholar 

  12. NIDCD. Quick statistics. [http://www.nidcd.nih.gov/health/statistics/quick.htm]. Accessed 08/09, 2009.

  13. Suter AH. The hearing conservation amendment: 25 years later. Noise Health. 2009;11(42):2–7.

    Article  PubMed  Google Scholar 

  14. Murphy D. Safety and health for production agriculture. St. Joseph, MI: American Society of Agricultural Engineers; 1992.

    Google Scholar 

  15. Sataloff RT, Sataloff J. Occupational hearing loss. New York: Marcel Deckker; 1993.

    Google Scholar 

  16. Savell JF, Toothman EH. Group mean hearing threshold changes in a noise-exposed industrial population using personal hearing protectors. Am Ind Hyg Assoc J. 1987;48(1):23–7.

    Article  CAS  PubMed  Google Scholar 

  17. Hong OS, Chen SP, Conrad KM. Noise induced hearing loss among male airport workers in Korea. AAOHN J. 1998;46(2):67–75.

    CAS  PubMed  Google Scholar 

  18. United States Department of Health and Human Services. Healthy people 2020. Washington, DC: US Department of Health and Human Services; 2010.

    Google Scholar 

  19. National Institute for Occupational Safety and Health (NIOSH). National Agriculture, Forestry and Fishing Agenda. [http://www.cdc.gov/niosh/nora/comment/agendas/AgForFish/pdfs/AgForFishDec2008.pdf]. 05/10, 2009.

  20. NIDCD. National Institute on Deafness and Other Communication Disorders Health Disparities Strategic Plan Fiscal Years 2004–2008. [http://www.nidcd.nih.gov/about/plans/strategic/FY2004-08-HDplan.htm]. Accessed 05/09, 2009.

  21. Franks JR, Stephenson M, Merry CJ. Preventing occupational hearing loss: a practical guide. Bethesda, Md: US Department of Health and Human Services; 1996.

    Google Scholar 

  22. NIOSH. Preventing occupational hearing loss: A practical guide (Publication No. 96-110). Washington, DC: NIOSH; 1996.

    Google Scholar 

  23. Suter A. Best practices in hearing loss prevention: The handicap resulting from noise-induced hearing impairment. Washington, D.C: NIOSH; 2001.

    Google Scholar 

  24. McCullagh MC, Lusk SL, Ronis DL. Factors influencing use of hearing protection among farmers: a test of the Pender Health Promotion Model. Nurs Res. 2002;51(1):33–9.

    Article  PubMed  Google Scholar 

  25. McCullagh MC, Ronis DL, Lusk SL. Predictors of use of hearing protection among a representative sample of farmers. Res Nurs Health. 2010;33(6):528–38.

    Article  CAS  PubMed  Google Scholar 

  26. Gates DM, Jones MS. A pilot study to prevent hearing loss in farmers. Public Health Nurs. 2007;24(6):547–53.

    Article  PubMed  Google Scholar 

  27. van den Berg MH, Schoones JW, Vliet Vlieland TP. Internet-based physical activity interventions: a systematic review of the literature. J Med Internet Res. 2007;9(3):e26.

    Article  PubMed  PubMed Central  Google Scholar 

  28. Joseph CLM, Peterson EL, Havstad S, Johnson CC, Hoerauf S, Stringer S, et al. Web-based, tailored asthma management program for urban African-American high school students. Am J Respir Crit Care Med. 2007;175(9):888–95.

    Article  PubMed  PubMed Central  Google Scholar 

  29. Strecher VJ, McClure J, Alexander G, Nair V, Konkel JM, Greene S, et al. Web-based smoking cessation components and tailoring depth: results of a randomized trial. Am J Prev Med. 2008;34(5):373–81.

    Article  PubMed  PubMed Central  Google Scholar 

  30. Alexander GL, McClure J, Calvi J. A randomized clinical trial evaluating online interventions to improve fruit and vegetable consumption. Am J Public Health. 2010;100(2):319–26.

    Article  PubMed  PubMed Central  Google Scholar 

  31. Ubel PA, Smith DM, Zikmund-Fisher BJ, Derry HA, McClure J, Stark A et al. Testing whether decision aids introduce cognitive biases: results of a randomized trial. Patient Educ Couns. In press.

  32. Lusk SL, Ronis DL, Hogan MM. Test of the health promotion model as a causal model of construction workers’ use of hearing protection. Nurs Res Health. 1997;20:183–94.

    Article  CAS  Google Scholar 

  33. Lusk SL, Ronis DL, Kerr MJ, Atwood JR. Test of the Health Promotion Model as a causal model of workers’ use of hearing protection. Nurs Res. 1994;43(3):151–7.

    Article  CAS  PubMed  Google Scholar 

  34. Kerr MJ, Lusk SL, Ronis DL. Explaining Mexican American workers’ hearing protection use with the health promotion model. Nurs Res. 2002;51(2):100–9.

    Article  PubMed  Google Scholar 

  35. Wadud E, Kreuter M, Clarkson S. Risk perception, beliefs about prevention, and preventive behaviors of farm workers. J Agric Saf Health. 1998;4:15–24.

    Article  Google Scholar 

  36. Karlovich RS, Wiley TL, Tweed T, Jensen DV. Hearing sensitivity in farmers. Public Health Rep. 1988;103(1):61–71.

    CAS  PubMed  PubMed Central  Google Scholar 

  37. Melamed S, Bruhis S. The effects of chronic industrial noise exposure on urinary cortisol, fatigue and irritability: a controlled field experiment. J Occup Environ Med. 1996;38:252–6.

    Article  CAS  PubMed  Google Scholar 

  38. USDA. Farm Structure: Glossary. [http://www.ers.usda.gov/topics/farm-economy/farm-household-well-being/glossary.aspx]. Accessed 05/22, 2009

  39. StataCorp. Stata: Release 13. Statistical Software. College Station, TX: StataCorp LP; 2013.

    Google Scholar 

  40. National Institute for Occupational Safety and Health (NIOSH). They're your ears: Protect them. [http://www.cdc.gov/niosh/docs/2007-175/]. Accessed 05/10, 2009.

  41. National Institute for Occupational Safety and Health (NIOSH). Have you heard? Hearing loss caused by noise is preventable. [http://www.cdc.gov/niosh/docs/2007-176/]. Accessed 05/10, 2009.

  42. Ray JJ. The reliability of short social desirability scales. J Soc Psychol. 1984;123:133–4.

    Article  Google Scholar 

  43. Hintze JL. SPSS 2008 User’s Guide. Kaysville, Utah: SPSS, Inc; 2008.

    Google Scholar 

Download references

Acknowledgements

Financial support for this project was received from the Centers for Disease Control and Prevention/National Institute for Deafness and Communication Disorders R01-DC-010827. The content is solely the responsibility of the authors and does not necessarily represent the official views of, the National Institutes of Health.

Author information

Authors and Affiliations

Authors

Corresponding author

Correspondence to Marjorie C McCullagh.

Additional information

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

MCM conceptualized and conducted the study and drafted the manuscript. DLR edited the manuscript. Both authors read and approved the final manuscript.

Rights and permissions

This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly credited. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

Reprints and permissions

About this article

Check for updates. Verify currency and authenticity via CrossMark

Cite this article

McCullagh, M.C., Ronis, D.L. Protocol of a randomized controlled trial of hearing protection interventions for farm operators. BMC Public Health 15, 399 (2015). https://0-doi-org.brum.beds.ac.uk/10.1186/s12889-015-1743-0

Download citation

  • Received:

  • Accepted:

  • Published:

  • DOI: https://0-doi-org.brum.beds.ac.uk/10.1186/s12889-015-1743-0

Keywords