As a leading cause of disability and premature mortality in the USA and worldwide, diabetes can result in serious health complications including heart disease, blindness, kidney failure and lower-extremity amputations( Reference van Dieren, Beulens and van der Schouw 1 ). In 2012, an estimated 28·9 million American adults aged 20 years and above had diagnosed or undiagnosed diabetes and an additional 86 million had prediabetes( 2 ). A healthy diet is a crucial regime for diabetes management( Reference Evert and Boucher 3 ). Patients with diabetes should limit their consumption of foods high in sugar, salt or fat; carefully monitor the time and quantity of carbohydrate intake; consume a variety of fruits, vegetables and whole-grain foods on a daily basis; and eat smaller portions and spread out their meals over the day. The nutrition facts label is an essential source for consumers to obtain nutrition-related information on food products and serves as a population-level policy intervention with unparalleled reach( Reference Campos, Doxey and Hammond 4 ). Nutrition facts labels may help patients with diabetes manage their condition through making healthier food choices.
A long line of research documents consumers’ understanding and use of nutrition facts labels, as well as their impact on dietary behaviour( Reference Drichoutis, Lazaridis and Nayga 5 – Reference Grunert and Wills 8 ). A substantial proportion of US consumers report regular use of nutrition facts labels to guide their selection of food products( Reference Drichoutis, Lazaridis and Nayga 5 – Reference Grunert and Wills 8 ). The perception on the credibility of nutrition facts labels appears high and there is a consistent association between nutrition facts label use and diet quality( Reference Drichoutis, Lazaridis and Nayga 5 – Reference Grunert and Wills 8 ). The American Diabetes Association recommends that patients ‘use the information on the nutrition facts label to compare foods and make better choices’( 9 ). However, little is known regarding the prevalence of nutrition facts label use among the diabetic population and whether that differs between people with and without diabetes and across diagnosis status. Behavioural theories and interventions emphasize the importance of cues in prompting motivation for behaviour change( Reference Lawson and Flocke 10 ). A specific type of cue, labelled a ‘teachable moment’, describes a naturally occurring health or life event that motivates individuals to spontaneously engage in risk-reducing health-promoting behaviour( Reference McBride, Emmons and Lipkus 11 ). While chronic illnesses like diabetes are a major threat to health and quality of life, disease diagnosis itself could serve as a critical teachable moment for patients to initiate behaviour change( Reference Demark-Wahnefried, Aziz and Rowland 12 – Reference Mills and Pierce 15 ). At a diagnosis of diabetes or prediabetes, patients may be particularly concerned about their health status and willing to accept recommendations on behaviour modification in an effort to effectively manage their diabetic condition. Physicians and other nutrition/health professionals may seize this window of opportunity to provide patients with tailored messages and advice regarding food choices, physical activity and other health behaviours. Nutrition education programmes may also take advantage of diabetes diagnosis to improve effectiveness, reduce cost and adapt to a larger population.
The impact of chronic condition diagnosis on behaviour modification as a teachable moment has been consistently documented in smoking cessation( Reference Falba 16 – Reference Wray, Herzog and Willis 24 ), but findings remain mixed for other types of health behaviours such as drinking and physical activity( Reference Margolis 19 – Reference van Gool, Kempen and Penninx 22 , Reference Bidstrup, Dalton and Christensen 25 – Reference Williams, Steptoe and Wardle 27 ). To our knowledge, the present study serves as the first attempt to evaluate the role of diabetes diagnosis as a potential teachable moment in nutrition facts label use. If diabetes/prediabetes diagnosis qualifies for a teachable moment, we would expect that patients with diagnosed diabetes/prediabetes pay more attention to their daily diet in an effort to better manage their diabetic condition compared with their counterparts who suffer from the same illness but are unaware of it (i.e. people with undiagnosed diabetes/prediabetes). On the other hand, we would expect the grocery shopping and diet behaviours among those with undiagnosed diabetes/prediabetes to be similar to those of people without diabetes/prediabetes, since the former group may not pay additional attention to their daily diet due to their unawareness of their diabetic condition. Therefore, we hypothesized that: (i) people with diagnosed diabetes/prediabetes are more likely to use nutrition facts labels in guiding their daily food purchases compared with people with undiagnosed diabetes/prediabetes; and (ii) the prevalence of nutrition facts label use does not differ between people with undiagnosed diabetes/prediabetes and people without diabetes/prediabetes. Using data from a nationally representative repeated cross-sectional survey, we tested this hypothesis by examining the relationship between diabetes diagnosis status and nutrition facts label use among US adults aged 20 years and above.
Methods
Survey setting and participants
Individual-level data came from the National Health and Nutrition Examination Survey (NHANES) 2005–2006, 2007–2008 and 2009–2010 waves. NHANES is a programme of studies conducted by the National Center for Health Statistics to assess the health and nutritional status of children and adults. The programme began in the early 1960s and has periodically conducted separate surveys focusing on different population groups or health topics. Since 1999, NHANES has been conducted continuously in two-year cycles and has a changing focus on a variety of health and nutrition measurements. A multistage probability sampling design is used to select participants representative of the civilian, non-institutionalized US population. Certain population subgroups are oversampled to increase the reliability and precision of health status indicator estimates for these groups.
Use of nutrition facts label
In a survey respondent’s home, a trained interviewer presented the respondent with a hand card and asked the question: ‘Here is an example of a food label. This part of the food label is called the Nutrition Facts panel. How often do you use the Nutrition Facts panel when deciding to buy a food product? Would you say always, most of the time, sometimes, rarely, or never?’ Any use of nutrition facts label is defined by grouping the answers of ‘always’, ‘most of the time’ and ‘sometimes’, with the reference group consisting of the answers of ‘rarely’ and ‘never’. Regular use of nutrition facts label is defined by the answers of ‘always’ and ‘most of the time’, with the reference group consisting of the answers of ‘sometimes’, ‘rarely’ and ‘never’.
Diabetes measures
Following the definitions adopted in the Centers for Disease Control and Prevention weekly report( Reference Li, Geiss and Burrows 28 ), we classified survey respondents into five mutually exclusive categories based on their self-reported diabetes diagnosis and laboratory test result: (i) diagnosed diabetes; (ii) diagnosed prediabetes; (iii) undiagnosed diabetes; (iv) undiagnosed prediabetes; and (v) no diabetes/prediabetes. Diagnosed diabetes was identified by the answer of ‘yes’ to the interview question ‘Have you ever been told by a doctor or health professional that you have diabetes or sugar diabetes?’ Diagnosed prediabetes was identified by the answer of ‘yes’ to the interview question ‘Have you ever been told by a doctor or other health professional that you have any of the following: prediabetes, impaired fasting glucose, impaired glucose tolerance, borderline diabetes or that your blood sugar is higher than normal but not high enough to be called diabetes or sugar diabetes?’ and the answer of ‘prediabetes’ when asked whether one had diabetes. Undiagnosed diabetes was identified by having fasting plasma glucose (FPG)≥126 mg/dl or glycated Hb (HbA1c)≥6·5 % but reporting absence of diagnosed diabetes. Undiagnosed prediabetes was identified by having 100 mg/dl≤FPG<126 mg/dl or 5·7 %≤HbA1c<6·5 % but reporting absence of diagnosed diabetes/prediabetes. Respondents with no diabetes/prediabetes were identified by having FPG<100 mg/dl and HbA1c<5·7 % and reporting absence of diagnosed diabetes/prediabetes.
Of the 7763 non-pregnant survey respondents aged 20 years and above assigned to a morning fasting session, the following participants were excluded from the analyses: missing test results for FPG or HbA1c, n 431; missing values for self-reported diabetes/prediabetes diagnosis, n 156; missing values for nutrition facts label use, n 1157; and missing values for other individual characteristics, n 909. The remaining 5110 survey respondents were included in the analysis.
Individual characteristics
The following individual characteristics were controlled for in the regression analysis: a dichotomous variable for female (male in the reference group); three dichotomous variables for age groups (35–49 years of age, 50–64 years of age and 65 years of age and above, with 20–34 years of age in the reference group); three dichotomous variables for race/ethnicity (non-Hispanic African American, non-Hispanic other race/multi-race and Hispanic, with non-Hispanic white in the reference group); a dichotomous variable for college education and above (with high school or lower education in the reference group); two dichotomous variables for marital status (divorced/separated/widowed and never married, with married in the reference group); two dichotomous variables for household income level (130 %≤income to poverty ratio (IPR)<300 % and IPR≥300 %, with IPR<130 % in the reference group); a dichotomous variable for obesity (non-obese people in the reference group); a dichotomous variable for ever or current smoker (never smoker in the reference group); a dichotomous variable for good or excellent self-rated health (poor or fair self-rated health in the reference group); a dichotomous variable for any public or private health insurance coverage (no health insurance in the reference group); four dichotomous variables for each of the chronic conditions of arthritis, CHD, stroke and cancer; and two dichotomous variables for NHANES 2007–2008 and 2009–2010 waves (2005–2006 wave in the reference group).
Besides the common individual demographic (sex, age, race/ethnicity) and socio-economic (education, marital status and income level) variables, we also intended to control risky behaviour (smoking) and health/disease status (self-rated health and chronic illnesses) in the regression analysis, because these factors may confound in our estimated relationship between diabetes diagnosis (‘exposure’) and nutrition facts label use (‘outcome’) by correlating with both the exposure and the outcome. We further included health insurance status in the model, because the uninsured could be less likely to use health-care services and have a diabetes diagnosis.
Statistical analyses
Logistic regression analyses were conducted to examine the relationship between diabetes diagnosis status and nutrition facts label use among US adults, adjusted by individual characteristics. Separate regression models were estimated for the two dependent variables: a dichotomous variable for any use of nutrition facts labels and a dichotomous variable for regular use of nutrition facts labels. The key independent variables were four dichotomous variables for having diagnosed diabetes, diagnosed prediabetes, undiagnosed diabetes and undiagnosed prediabetes, with those reporting no diabetes/prediabetes in the reference group. We calculated the adjusted prevalence of nutrition facts label use by diabetes status based on logistic regression estimates. The differences in the adjusted prevalence of nutrition facts label use across diabetes status were tested using Wald tests.
All statistical analyses were conducted using the statistical software package Stata 14·0 SE version. The NHANES sampling design was incorporated in both descriptive statistics and regression analyses.
Human subjects review
NHANES was approved by the National Center for Health Statistics Research Ethics Review Board. The present analysis used NHANES de-identified public data and was deemed exempt by the University of Illinois at Urbana–Champaign Institutional Review Board.
Results
Table 1 reports nutrition facts label use, diabetes diagnosis status and other individual characteristics of adult survey respondents in the NHANES 2005–2010 waves. Among a total of 5110 respondents, the population-weighted prevalence of any nutrition facts label use was 72·59 % and that of regular nutrition facts label use was 41·54 %. Nearly a quarter (23·00 %) of survey respondents had diabetes or prediabetes, where undiagnosed prediabetes accounted for 10·09 %, undiagnosed diabetes for 0·86 %, diagnosed prediabetes for 4·06 % and diagnosed diabetes accounted for 7·99 %.
NHANES, National Health and Nutrition Examination Survey; IPR, income to poverty ratio.
Individual-level data (n 5110) from NHANES 2005–2010 waves. NHANES sampling design was incorporated in estimating the percentages.
Table 2 reports nutrition facts label use by diabetes diagnosis status. The population-weighted prevalence of any nutrition facts label use was substantially higher among those with diagnosed prediabetes (81·90 %) and diabetes (82·50 %) in comparison to those with undiagnosed prediabetes (71·90 %) and diabetes (62·18 %). Analogously, the population-weighted prevalence of regular nutrition facts label use was substantially higher among those with diagnosed prediabetes (48·93 %) and diabetes (54·68 %) in comparison to those with undiagnosed prediabetes (41·32 %) and diabetes (30·60 %).
NHANES, National Health and Nutrition Examination Survey.
Individual-level data (n 5110) from NHANES 2005–2010 waves. Any use of nutrition facts label is defined as using labels sometimes, mostly or always. Regular use of nutrition facts label is defined as mostly or always using labels. NHANES sampling design was incorporated in estimating the percentages.
Table 3 reports the estimated odds ratios of nutrition facts label use in logistic regression analyses. After adjusting for individual characteristics, the odds of any and regular nutrition facts label use among people with diagnosed diabetes were 110 % (adjusted odds ratio (AOR)=2·10; 95 % CI=1·62, 2·73) and 94 % (AOR=1·94; 95 % CI 1·55, 2·43) higher, respectively, than among their counterparts without diabetes/prediabetes. In contrast, no difference in the odds of any (AOR=0·86; 95 % CI 0·47, 1·59) and regular nutrition facts label use (AOR=0·76; 95 % CI 0·40, 1·46) was found between those with undiagnosed diabetes and those without diabetes/prediabetes. The odds of any and regular nutrition facts label use among people with diagnosed prediabetes were 48 % (AOR=1·48; 95 % CI 0·97, 2·26) and 28 % (AOR=1·28; 95 % CI 0·91, 1·80) higher, respectively, than among their counterparts without diabetes/prediabetes, although these differences were not statistically significant at P<0·05. In contrast, no difference in the odds of any (AOR=0·92; 95 % CI 0·71, 1·20) and regular nutrition facts label use (AOR=1·03; 95 % CI 0·80, 1·34) was found between those with undiagnosed prediabetes and those without diabetes/prediabetes. As for other individual characteristics, females, middle-aged and older adults (50 years of age and above), people with college education and above, with good or excellent self-rated health and covered by health insurance were significantly more likely to use nutrition facts labels compared with males, younger adults, people with high school or lower education, with poor or fair self-rated health and without health insurance coverage.
NHANES, National Health and Nutrition Examination Survey; IPR, income to poverty ratio; ref., reference category.
Individual-level data (n 5110) from NHANES 2005–2010 waves. Any use of nutrition facts label is defined as using labels sometimes, mostly or always. Regular use of nutrition facts label is defined as mostly or always using labels. Logistic regressions were conducted to estimate the odds ratios of nutrition facts label use among US adults, accounting for NHANES sampling design.
*P<0·05, **P<0·01, ***P<0·001.
Table 4 reports the adjusted prevalence of any and regular nutrition facts label use based on the logistic regression estimates. The adjusted prevalence of any nutrition facts label use was substantially higher among those with diagnosed diabetes (85·93 %) in comparison to undiagnosed diabetes (71·50 %; P<0·001); and the adjusted prevalence of any nutrition facts label use was also noticeably higher among those with diagnosed prediabetes (81·16 %) in comparison to undiagnosed prediabetes (72·83 %; P<0·05). Analogously, the adjusted prevalence of regular nutrition facts label use was substantially higher among those with diagnosed diabetes (55·60 %) in comparison to undiagnosed diabetes (32·88 %; P<0·001). The adjusted prevalence of regular nutrition facts label use also tended to be higher among those with diagnosed prediabetes (45·28 %) in comparison to undiagnosed prediabetes (39·95 %), although the difference was not statistically significant at P<0·05.
NHANES, National Health and Nutrition Examination Survey.
Individual-level data (n 5110) from NHANES 2005–2010 waves. Any use of nutrition facts label is defined as using labels sometimes, mostly or always. Regular use of nutrition facts label is defined as mostly or always using labels. Logistic regressions were conducted to estimate the adjusted prevalence of nutrition facts label use among US adults, accounting for NHANES sampling design.
Discussion
Drawing from the health belief model, a teachable moment is a cueing event that increases perceptions of risk and outcome expectancies, prompts strong emotional responses and causes a redefinition of an individual’s self-concept or social role( Reference Lawson and Flocke 10 , Reference McBride, Emmons and Lipkus 11 ). According to McBride et al. ( Reference McBride, Emmons and Lipkus 11 ), a disease diagnosis is considered a teachable moment because it may increase one’s perceptions of vulnerability and shift expectancies of and value assigned to health outcomes in relation to a specific unhealthy behaviour, bring out strong negative or positive emotional reactions, and alter perceived social norms or self-concept so that an unhealthy behaviour becomes less tolerable. The present study is the first attempt to evaluate the role of diabetes diagnosis as a potential teachable moment in nutrition facts label use. Using data from NHANES 2005–2010 waves, we found that people with diagnosed diabetes/prediabetes were substantially more likely to report nutrition facts label use in their daily grocery shopping compared with those with undiagnosed diabetes/prediabetes, whereas the pattern of nutrition facts label use appeared similar between people with undiagnosed diabetes/prediabetes and those without diabetes/prediabetes. These findings were consistent with our hypothesis based on the notion of teachable moment, which predicted increased efforts to seek healthier diet options following a diabetes diagnosis.
Self-reported use of nutrition facts label may not reflect actual use and translate into healthier grocery shopping behaviour or improved diet quality. Although a majority of US consumers report regular use of nutrition facts labels, in-store observations suggest actual use during food purchase can be lower( Reference Azman and Sahak 29 ). The use of nutrition facts labels varies noticeably across population subgroups. Children, adolescents, obese older adults, individuals with less education and/or nutrition knowledge, people with lower disposable income and those with lower health awareness are less likely to use labels and/or effectively process the nutrition information presented( Reference Satia, Galanko and Neuhouser 30 – Reference Grunert, Wills and Fernández-Celemín 32 ). Moreover, whether consumers can understand and use nutrition facts labels is contingent upon the purpose of the task( Reference Drichoutis, Lazaridis and Nayga 5 – Reference Grunert and Wills 8 ). A majority appears capable to retrieve basic facts and make simple calculations/comparisons between products using numerical information on the label, but their ability and accuracy decline as the complexity of the task increases. Recent systematic reviews on nutrition labelling found that most studies focused on the use of labels to retrieve nutrition information and assess the healthiness of food products, whereas much less is known on whether and to what extent nutrition facts labels modify consumers’ grocery shopping and dietary habits( Reference Campos, Doxey and Hammond 4 – Reference Grunert and Wills 8 ). Elfassy et al. examined the association between hypertension and nutrition facts label use for sodium information among New York City adults( Reference Elfassy, Yi and Eisenhower 33 ). Although individuals with hypertension had 71 % higher odds of frequently using nutrition facts labels for sodium information compared with those with no hypertension, sodium intake was not found to differ by frequency of nutrition facts label use among those with hypertension. A vast majority of existing studies used a cross-sectional survey and/or qualitative study design, so that an estimated association between nutrition facts label use and healthier diet is subject to confounding (e.g. people who value health more are more likely to read nutrition facts labels and also more likely to purchase healthier foods).
A few limitations of the present study should be noted. The evidence indicating the impact of diabetes diagnosis on nutrition facts label use is at best preliminary and should not be interpreted as a causal relationship. The cross-sectional study design precludes examining life events and behaviours by chronological order, so that we do not know whether a modification in nutrition facts label use precedes or follows a diabetes diagnosis. Moreover, people with diagnosed diabetes/prediabetes could be different from those with undiagnosed diabetes/prediabetes in disease history, severity, co-morbidity, etc. and these differences might confound the relationship between diabetes diagnosis and nutrition facts label use. Approximately 34 % of the NHANES sample was excluded from the analysis due to missing values on test results, nutrition facts label use status and/or other individual characteristics. If those who did not report nutrition facts label use were less aware of nutrition labelling compared with those who reported label use, and those who did not undertake FPG and HbA1c testing were more or less likely to have undiagnosed diabetes/prediabetes compared with their counterparts who took the tests, respectively, we could underestimate or overestimate the impact of diabetes diagnosis on nutrition facts label use. Despite relatively large total sample size, undiagnosed diabetes cases (n 106) and diagnosed prediabetes cases (n 330) only occupied 0·86 % and 4·06 % of the sample, respectively. This might compromise model estimation precision and partially explain the lack of statistical significance in the difference of adjusted prevalence of regular nutrition facts label use between those with diagnosed prediabetes and those with undiagnosed prediabetes. The time span of patients living with diabetes/prediabetes might play a role in their nutrition facts label use (e.g. lack of novelty over time or sustained behaviour change after diagnosis), but such data were not available in the NHANES. Physical activity level could confound in the estimated relationship between diabetes diagnosis and nutrition facts label use. However, due to the measurement inconsistency in physical activity across the three waves of NHANES, we were not able to control for it in regression analysis. Finally, NHANES is a probability sample of the US non-institutionalized population and patients in penal/mental facilities, institutionalized older adults and/or military personnel on active duty are not represented.
The prevalence of nutrition facts label use among people with diagnosed diabetes/prediabetes was substantially higher than that among people with undiagnosed diabetes/prediabetes, indicating a new diabetes diagnosis could serve as a window of opportunity for nutrition education and healthy diet intervention. Targeting people with newly diagnosed diabetes may augment intervention effectiveness as they could be particularly receptive to change( Reference Xiang 34 ). Moreover, these people often can be conveniently reached at clinics, hospitals and other health-care settings when attending appointments for their new diagnosis. Health-care providers may seize this opportunity to offer on-site health behaviour counselling (e.g. nutrition and physical activity education, smoking cessation) shortly after delivering the diagnosis/treatment. Even a brief information session by health-care providers can lead to positive behaviour change( Reference Bull and Jamrozik 35 – Reference Greenlund, Giles and Keenan 37 ). This is particularly important given the fact that adults with chronic diseases currently are inadequately advised by health-care providers to adopt a healthier lifestyle( Reference Fallon, Wilcox and Laken 38 – Reference Xiang, Hernandez and Larrison 42 ).
Conclusion
In conclusion, the present study examined the relationship between diabetes diagnosis status and nutrition facts label use among US adults aged 20 years and above using data from a nationally representative survey. People with diagnosed diabetes/prediabetes were noticeably more likely to report nutrition facts label use when making daily food purchase decisions relative to those with undiagnosed diabetes/prediabetes. In contrast, the prevalence of self-reported nutrition facts label use was similar between people with undiagnosed diabetes/prediabetes and those without diabetes/prediabetes. Serving as a potential teachable moment, diabetes diagnosis may positively impact nutrition facts label use and motivate diabetic patients to manage their condition through making healthier food choices. Future research needs to examine the potential dose–response relationship between frequency of nutrition facts label use and FPG/HbA1c level, the pathway linking nutrition facts label use motivated by diabetes diagnosis to actual food purchase and dietary intake, and explore optimal strategies to deliver nutrition interventions in conjunction with diabetes diagnosis/treatment in order to capitalize the benefit from this teachable moment.
Acknowledgements
Financial support: This research received no specific grant from any funding agency in the public, commercial or not-for-profit sectors. Conflict of interest: The author has no funding source or conflict of interest to declare. Authorship: R.A. designed the study, conducted statistical analysis and wrote the manuscript. Ethics of human subject participation: NHANES was approved by the National Center for Health Statistics Research Ethics Review Board. The current analysis used NHANES de-identified public data and was deemed exempt by the University of Illinois at Urbana-Champaign Institutional Review Board.