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. Author manuscript; available in PMC: 2016 Apr 1.
Published in final edited form as: J Acad Nutr Diet. 2015 Feb 12;115(4):511–518. doi: 10.1016/j.jand.2014.12.011

Weighing everyday matters: Daily weighing improves weight loss and adoption of weight control behaviors

Dori M Steinberg 1,2, Gary G Bennett 1,3, Sandy Askew 1, Deborah F Tate 2
PMCID: PMC4380831  NIHMSID: NIHMS650647  PMID: 25683820

Abstract

Background

Daily weighing is emerging as the recommended self-weighing frequency for weight loss. This is likely because it improves adoption of weight control behaviors.

Objective

Examine whether weighing everyday is associated with greater adoption of weight control behaviors compared to less frequent weighing.

Design

Longitudinal analysis of a previously conducted 6-month randomized-controlled trial.

Participants/setting

Overweight men and women in Chapel Hill, NC in the Intervention arm (N=47).

Intervention

The intervention focused on daily weighing for weight loss using an e-scale that transmitted weights to a study website, along with weekly e-mailed lessons and tailored feedback on daily weighing adherence and weight loss progress.

Main outcome measures

We gathered objective data on self-weighing frequency from e-scales. At baseline and 6 months, weight change was measured in clinic, and weight control behaviors (total items = 37), dietary strategies, and caloric expenditure from physical activity were assessed via questionnaires. Caloric intake was assessed using an online 24-hour recall tool.

Statistical analyses

We used chi-square tests to examine variation in discrete weight control behaviors and linear regression models to examine differences in weight, dietary strategies, and calorie intake and expenditure by self weighing frequency.

Results

Fifty-one percent of participants weighed everyday (n= 24) over 6 months. The average self-weighing frequency among those weighing less than daily (n=23) was 5.4±1.2 days per week. Daily weighers lost significantly more weight compared to those weighing less than daily (mean difference, −6.1kg; 95% CI −10.2, −2.1; p=.004). The total number of weight control behaviors adopted was greater among daily weighers (17.6 ± 7.6 vs. 11.2 ± 6.4; p=.004). There were no differences by self-weighing frequency in dietary strategies, caloric intake, or caloric expenditure.

Conclusions

Weighing everyday led to greater adoption of weight control behaviors and produced greater weight loss compared to weighing most days of the week. This further indicates daily weighing as an effective weight loss tool.

Keywords: Obesity, Weight Loss, Self-monitoring, Daily weighing, Dietary change

Introduction

Obesity affects more than one-third of Americans1 and is associated with an increased risk for many chronic diseases2 and some cancers.3 The new guidelines for the management of overweight and obesity in adults released from the American College of Cardiology (ACC), American Heart Association (AHA), and The Obesity Society indicate that even a 3% weight loss among over weight and obese individuals can improve risk factors for these chronic diseases.4 Thus, finding ways to produce even small amounts of weight loss can be clinically meaningful. The most successful weight loss treatments include elements of self-monitoring as a means to increase self-awareness about how behaviors impact weight.5,6 This is supported by self-regulation theory, which posits that individuals are better able to self-regulate behaviors when they self-monitor and evaluate current behavior compared to goals.7 This then reinforces current behavior or allows for self-correction. One such self-monitoring strategy is daily self-weighing. Compared to less frequent weighing, daily self-weighing may allow for better self-regulation of body weight as small changes in body weight can be identified on a daily basis and changes in diet and exercise behaviors initiated as a result.8 Although there is emerging evidence that daily weighing can promote greater weight loss compared to less frequent weighing,912 the mechanisms are unclear. Given that daily self-weighing does not impact weight loss directly, but rather via diet and physical activity behaviors that result in caloric deficits, it is important to better understand the behavior changes prompted by daily weighing.

Few studies have examined associations between daily weighing and discrete weight control behaviors. Results suggest that more frequent weighing is associated with greater adoption of diet and exercise behaviors that may promote weight loss.13,14 These studies, however, were conducted cross-sectionally and did not specifically assess whether daily weighing within the context of a behavioral weight loss intervention leads to greater engagement in weight control behaviors compared to less frequent weighing. It is less clear whether daily weighing will trigger uptake of diet and exercise behaviors that promote weight loss, in that it prompts these behavioral changes rather than it happening concurrently. As such, it is important to examine whether there is greater adoption of behaviors known to be associated with weight loss among individuals who are instructed to daily weigh.

We recently conducted WEIGH, a 6-month randomized controlled trial assessing the efficacy of weight loss intervention focusing on daily weighing as compared to a delayed intervention control group.9 Participants were instructed to weigh daily using network connected e-scales and were provided with tailored feedback and skills training via weekly emails. Using the e-scales we were able to capture an objective measure of self-weighing frequency. We also measured various diet, exercise, and behavioral outcomes associated with weight loss success. As such, this study provides a unique opportunity to assess the relationship between daily weighing and weight control behaviors, along with nuanced differences in weight loss by self-weighing frequency. We hypothesized, based on self-regulation theory, that daily weighing would lead to greater adoption of weight control behaviors as compared to less frequent weighing.

Methods

Study Design

As previously stated, we present a secondary analysis from the WEIGH study. A detailed description of the study design, intervention and report of the main outcomes has been previously published.9 Briefly, eligibility criteria included adults aged 18–60 years, body mass index (BMI) of 25–40, Internet access, and no medical conditions that might affect participation. Participants were recruited predominantly from the Chapel Hill, NC area. Following eligibility screening, informed consent was obtained and baseline measures were collected. Participants (N=91) were then randomized to a 6-month daily self-weighing intervention (n=47) or a delayed intervention control group (n=44). All participants were reassessed at 3 and 6 months. Data collection occurred from February to August 2011 in Chapel Hill, North Carolina. The University of North Carolina at Chapel Hill institutional review board approved and monitored the study.

Intervention Description

Intervention participants were instructed to weigh themselves daily and were provided with network-connected e-scales. The e-scale uses the wireless cellular network to transmit weight data. Weights were then automatically transferred to a website that displayed individualized graphs of weight change over time. Participants were able to log on to the website and view these graphs. Participant data on self-weighing frequency and weight change were also displayed in a separate researcher interface. These data informed an algorithm that was used to provide tailored feedback on self-weighing frequency and weight loss to each participant via weekly e-mails. The e-mails also included behavioral weight-control lessons based on topics from gold standard weight loss trials and other Internet-based trials that were adapted for the WEIGH study.1517 These lessons provided information on evidence-based strategies for weight loss, along with mini exercises for self-reflection and problem solving. The delayed control group received no intervention during the study period and was blinded to the focus on daily weighing. They received a modified version of the intervention after the 6-month study period was complete. We did not collect any data other than weight from the control group after they received the delayed intervention. As such, the current analysis is focused on participants in the intervention group.

Measures

Demographics

At baseline, a variety of demographic variables were collected to help characterize the sample including age, sex, race/ethnicity (American Indian/Alaskan Native; Asian; Black or African-American; Hispanic, Latino, Portuguese, or Cape Verdean; White; Other), and education [Grade School (6 years or less); Junior High school (7–9 years); High School (10–12 years); Vocational Training (beyond High School); Some College (less than 4 years); College/University degree; Graduate or Professional Education].

Anthropometric

At baseline and 6 months, blinded evaluation staff collected height at baseline using a wall-mounted stadiometer, and weight using a calibrated and standardized digital scale at the UNC Weight Research Program clinic. Percent of body weight lost and absolute weight loss were calculated from baseline to 6 months.

Self-weighing frequency

Self-weighing frequency was measured objectively throughout the intervention using the e-scales. E-scale data included the weight measurement and the date and time of day of weighing. The maximum number of person-days for e-scale measurement totaled 168 days, equivalent to 24 weeks of intervention. The total number of days weighed was calculated for each participant. Average number of days weighed per week was calculated by dividing the total number of days weighed by 24. For participants with multiple weights on each day, we marked it as one day of weighing. To better assess differential outcomes among those who weighed daily versus less often, we created two categories: participants with an average weighing frequency = 7 days per week (n=24) vs. those with an average weighing frequency of anything less than 7 days per week (n=23).

To better characterize the weighing behaviors of the participants prior to starting WEIGH, we assessed weighing frequency over the previous 3 months via self-report using a single item: “Over the past 3 months, how often did you weigh yourself on average?” and included 7 response options: several times per day, one time per day, several times per week, one time per week, less than one time per week, less than one time per month, never weigh myself. These were then categorized into 3 categories: weighing daily, weighing weekly, or weighing less than weekly.

Weight control behaviors

Two questionnaires assessing weight control behaviors were administered at baseline and 6 months. The weight management strategies questionnaire (WMSQ)18 is a 37-item questionnaire assessing utilization of eating and exercise behaviors that are associated with producing a caloric deficit for weight loss and typically discussed in weight loss trials19 Each item had 5 response options including never/hardly ever, some of the time, about half of the time, much of the time, and always or almost always. In order to assess frequent engagement in these behaviors, which is suggestive of adoption, we dichotomized the items to examine those who engaged in these behaviors at least “much of the time.” A total count of how many behaviors were engaged in was also calculated to assess overall adoption weight control behaviors. This questionnaire was used in previous trials assessing daily self-weighing for weight gain prevention,18,20 and has since been validated.21 These strategies were emphasized in the emailed lessons provided to all intervention participants.

The Eating Behavior Inventory (EBI) is a 26-item questionnaire assessing adoption of dietary weight control behaviors typically targeted in weight control programs and known to be associated with weight loss.22,23 The questionnaire includes both positive and negative behaviors, and negative behaviors are reverse scored. In contrast to the WMSQ, the EBI is a summary measure and the individual behaviors are scored to calculate a total score. An example of a positive behavior includes “I refuse food offered to me by others,” and an example of a negative behavior includes, “I eat when I am not really hungry.” Evidence indicates that EBI scores increase at the end of weight loss intervention and higher scores are associated with better weight loss outcomes.23 Total scores were calculated and participants missing more than one item were excluded (baseline: n=1; 6 months: n=3). Previous reliability estimates of the EBI suggest moderate-to-high reproducibility.22

Caloric intake and expenditure

At baseline and 6 months, caloric intake was measured via two 24-hour recalls using the Automated Self-Administered 24-Hour Dietary Recall (ASA-24) tool from the National Cancer Institute (NCI).24,25 Average caloric intake was calculated across the two days at each time point. At the same times, the Paffenbarger Exercise Habits Questionnaire was administered to capture weekly energy expenditure from leisure time physical activity.26,27

Statistical Analysis

Chi-square and Fisher exact tests and t-tests were conducted to compare differences in sociodemographic characteristics. Differences in the proportions of participants reporting high adoption (defined as at least “much of the time”) of each of the individual weight control behaviors on the WMSQ by self-weighing frequency were examined using chi-square tests. For participants with missing data at 6 months, baseline values were imputed. Those missing both baseline and 6-months data were excluded (n=1). Thus, the total N is 46 for the WMSQ questions. For the remaining outcomes, we conducted intent-to-treat analyses (N=47) using linear regression models to examine the effect of self weighing frequency on weight change, BMI change, percent weight loss, EBI total score change, caloric intake change, and caloric expenditure change at 6 months For all variables, baseline observation carried forward was used for missing values. Models were also analyzed adjusting for age, baseline BMI, and self-reported self-weighing frequency at baseline. All continuous variables were determined to meet assumptions of normality with the exception of caloric expenditure. A natural log transformation was applied to caloric expenditure to create a more normal distribution. Raw means are presented with statistical tests performed using the transformed data. Analyses were conducted using SPSS for Mac (Version 19, Chicago, IL). A cut-off value of alpha <0.05 was used to assess statistical significance.

Results

Self-weighing Frequency

Overall compliance to self-weighing was high among intervention participants: 51% weighed every day; 76% weighed ≥ 6 days per week, and 94% weighed ≥5 days/week. The average self-weighing frequency among those weighing less than daily was 5.4 (SD: 1.2) days per week.

Baseline Characteristics

Table 1 highlights the baseline characteristics by self-weighing frequency of participants. On average, participants were 43 (SD: 11.4) years old, obese (BMI: 33.2 SD: 4.0 kg/m2), female (70%), White (77%), and college-educated (77%). At baseline, few participants were weighing daily; about half the sample (52%) reported weighing less than weekly, 37% reported weighing weekly, and 11% reported weighing daily over the 3 months before the study. Baseline characteristics did not differ by self-weighing frequency.

Table 1.

Baseline characteristics by self-weighing frequency of intervention participants in the WEIGH Study, 2011 (n=47)

Weighing everyday
(n=24)
Weighing less than 7
days per week (n=23)
p-value
Age in years, Mean (SD) 44.4 (11.0) 41.3 (11.8) 0.33
Sex, N (%) 0.59
  Male 8 (33) 6 (26)
  Female 16 (67) 17 (74)
Race/ethnicity, N (%) 0.91
  Black 3 (13) 3 (13)
  White 18 (75) 18 (78)
  Other 3 (13) 2 (9)
Education, N (%) 0.36
    High School, Vocational, or Some College 9 (38) 2 (9)
  College Graduate or Greater 15 (62) 21 (91)
Weight (kg), Mean (SD) 95.3 (18.5) 93.6 (12.8) 0.72
BMI (kg/m2), Mean (SD) 33.4 (4.4) 33.0 (3.6) 0.75
Self-weighing Frequency, N (%) 0.84
  Daily 3 (13) 2 (9)
  Weekly 8 (33) 9 (41)
  Less than one time/week 13 (54) 11 (50)

Weight and BMI Change

Weight loss over the study period was significantly greater among participants who weighed 7 days (daily weighers) compared to those who weighed less than 7 days per week (Figure 1). Daily weighers lost on average 9.2 kg (SD: 8.0) at 6 months compared to 3.1 kg (SD: 5.4) lost among those weighing less than daily (mean difference, −6.1kg; 95% CI −10.2, −2.1; p=.004). This equates to a percent weight loss of 9.4% (SD: 7.1) among daily weighers compared to 3.2% (SD: 5.3) among those who weighed less than daily (mean difference, −6.2%; 95% CI −9.9, −2.5; p=.002). We observed similar findings for absolute BMI change (mean difference, −2.10 kg/m2; 95% CI −3.3, −0.7; p=.004).

Figure 1.

Figure 1

Anthropometric changes by self-weighing frequency among intervention participants (n=47) enrolled in the WEIGH study, 2011. Means (SD) reported.

*Average self-weighing frequency in this group was 5.4, (SD: 1.2) days per week

Weight Control Behaviors

As shown in Table 2, participants who adhered to daily weighing throughout the intervention engaged more frequently in weight control behaviors associated with weight loss. Compared to those who weighed on average less than daily, a greater proportion of daily weighers reported reducing calorie intake by 500–1000 calories per day (30% vs. 11%; p=.007), reducing between meal snacks (37% vs. 17%; p=.008), reducing the number of times they ate out at restaurants other than fast food restaurants (30% vs. 13%; p=.02), reducing frequency or portion sizes of desserts (41% vs. 20%; p=.003), making one or two small changes to activity everyday (26% vs. 9%; p=.01), reducing the amount of time watching TV (23% vs. 7%; p=.01), exercising for a period of 30 minutes of more (41% vs. 20%; p=.003), removing high calorie foods from home or office (39% vs. 15%; p=.001), and increasing daily steps (37% vs. 20%; p=.02). We also observed that daily weighers adopted a greater number of total weight control behaviors on the WMSQ compared to those weighing less than daily (17.6 SD: 7.6 vs. 11.2 SD: 6.4; p=.004). For other dietary weight loss strategies, daily weighers reported on average higher EBI scores, lower calorie intake, and greater caloric expenditure compared to those who weighed anything less than daily (Table 3). These differences, however, did not reach statistical significance. Adjusted models produced similar results (data not shown).

Table 2.

Engagement in weight loss strategies measured by the Weight Management Strategies Questionnaire at 6 months by self-weighing frequency among intervention participants in the WEIGH study, 2011 (n=46)*

Weight Control Strategies Weighing everyday
(n=23)
Weighing less than 7 days
(n=23)
P-value
Number (%)
Reduced caloric intake by 500–1000 calories per day 14 (30%) 5 (11%) 0.007
Cut out/reduced sweets or junk food 17 (37%) 11 (24%) 0.07
Cut out/reduced between meal snacks 17 (37%) 8 (17%) 0.008
Cut out/reduced late night snacking 21 (46%) 17 (37%) 0.12
Ate less meat 10 (22%) 8 (17%) 0.55
Ate less carbohydrates 11 (24%) 8 (17%) 0.37
Ate less fat 14 (30%) 11 (24%) 0.38
Reduced portion sizes 14 (30%) 10 (22%) 0.24
Decreased number of times ate out at fast food restaurants 18 (39%) 13 (28%) 0.12
Decreased number of times that ate out at other restaurants 14 (30%) 6 (13%) 0.02
Changed food preparation techniques 10 (22%) 6 (14%) 0.22
Drank less alcohol or changed type of alcoholic drink to reduce calories 12 (26%) 11 (24%) 0.77
Drank less fruit juice or fruit drinks (e.g., 100% fruit juice, fruit punch, lemonade) 16 (35%) 12 (26%) 0.23
Drank less high calorie coffee drinks (e.g., caramel macchiato, cafe mocha) 15 (33%) 17 (37%) 0.52
Increased fruit and vegetable consumption 17 (37%) 12 (26%) 0.13
Increased water consumption 17 (37%) 14 (30%) 0.35
Used frozen entrees such as Lean Cuisine or Smart Ones 9 (20%) 6 (13%) 0.35
Used liquid meal replacements such as Slim Fast 0 (0%) 0 (0%) 1.0
Followed a structured meal plan that limited choices for breakfast, lunch, and dinner (e.g., nutrisystem meals) 4 (9%) 2 (4%) 0.67
Used meal replacement bars such as Power Bars or Zone bars 1 (2%) 1 (2%) 1.0
Decreased frequency or portion sizes of desserts 19 (41%) 9 (20%) 0.003
Skipped meals 1 (2%) 3 (7%) 0.61
Made one or two small changes to activity every day 12 (26%) 4 (9%) 0.01
Used the stairs instead of the elevator 16 (35%) 10 (22%) 0.07
Wore a pedometer 3 (7%) 1 (2%) 0.61
Reduced the amount of time watching TV 11 (24%) 3 (7%) 0.01
Used home exercise equipment 3 (7%) 2 (4%) 1.0
Exercised at a gym or participated in an exercise class 9 (20%) 8 (17%) 0.76
Exercised with a personal trainer 0 (0%) 1 (2%) 1.0
Exercised for a period of 30 minutes or more 19 (41%) 9 (20%) 0.003
Recorded or graphed physical activity 5 (11%) 2 (4%) 0.41
Recorded or wrote down the type and quantity of food eaten 6 (13%) 3 (7%) 0.46
Removed high calorie foods (e.g., cakes, cookies, or candy) from home or office 18 (39%) 7 (15%) 0.001
Attended or participated in a structured weight loss group or program (e.g., Weight Watchers, Jenny Craig) 2 (4%) 1 (2%) 1.0
Followed a specific weight loss diet (e.g. Atkins, South Beach Diet) 0 (0%) 0 (0%) 1.0
Made one or two small changes to your diet every day 12 (26%) 7 (15%) 0.13
Increased daily steps 17 (37%) 9 (20%) 0.02
*

N=46 because one participant did not complete the WMSQ at baseline.

Table 3.

Changes in diet and physical activity behaviors at 6 months by self-weighing frequency among participants in the WEIGH Study, 2011 (n=47)

Weighing everyday
Mean (SD)
(n=24)
Weighing less than 7 days
Mean (SD)
(n=23)
p-value
EBI Total Score*
  Baseline 75.1 (10.7) 70.3 (10.4)
  End Point 91.1 (13.0) 81.7 (9.3)
  Change, 95%(CI) 14.8 (8.8, 20.7) 11.4 (8.1, 14.7) 0.32
Caloric Intake
  Baseline 2014.1 (492.4) 2013.6 (688.6)
  End Point 1413.5 (479.7) 1660.5 (731.9)
  Change, 95%(CI) −600.6 (−876.5, −324.7) −353.1 (−590.3, −116.0) 0.17
Caloric Expenditure**
  Baseline 1038.8 (1178.1) 601.5 (645.4)
  End Point 1264.6 (1140.5) 811.1 (1351.1)
  Change, 95%(CI) +225.7 (−250.9, 702.4) +209 (−410.4, 829.7) 0.23
*

EBI = Eating Behavior Inventory

**

P-value for caloric expenditure is based on the natural log transformed variable. Raw means are presented.

CI = confidence interval

Discussion

Within the context of a daily self-weighing weight loss intervention, individuals who weighed everyday achieved clinically meaningful weight loss that was significantly greater than among those weighing less than daily. The likely reason for this difference is that daily weighers reported greater adoption of weight control behaviors compared to those who weighed less often. Even weighing 5 days per week, which was the average among the “non daily weighers,” led to smaller weight losses, and promoted less utilization of behaviors known to be associated with weight loss. This suggests that daily weighing may trigger the self-regulatory processes that promote behavior change. This may be particularly true for those already primed to make changes to diet and exercise behaviors. Moreover, our findings suggest that weighing even most days of the week may not be enough for optimal self-regulation.

There is extensive evidence indicating that those who maintain high levels of adherence to self-monitoring of diet are physical activity are most successful with weight loss.6,28 However, in WEIGH, we discouraged participants from tracking diet and exercise behaviors because it is clear that this type of self-monitoring is difficult to sustain,6 even when using eHealth or mobile health approaches.29,30 Despite overall high adherence to daily weighing as the self-monitoring strategy, we observed a similar pattern with how adherence affects outcomes – those who were the most engaged achieved better outcomes. As is reflected in two of the questions asked on the behavioral strategies questionnaire, a small number of participants (N=9) reported recording the foods they had eaten or their physical activity (N=7). There were no differences by self-weighing frequency, suggesting that diet and exercise self-monitoring did not have a major impact on the effects of daily weighing on adoption of behavioral weight control strategies.

As has been shown previously, individuals receiving a weight loss program show improvements in adoption of diet and physical activity strategies associated with weight control.23 More robust mediation analyses have shown that dietary behaviors such as greater fruit and vegetable intake or those measured by the EBI mediate the effect of an eHealth weight loss intervention on weight outcomes.31,32 This isn’t surprising because these programs are designed in such a way to facilitate these behavior changes. We found a similar uptake in adoption of these behaviors. However, despite all participants receiving the same information about making behavior change necessary to see weight loss, participants weighing daily reported higher utilization than those who weighed even 5 days per week. Despite this difference, there still may be utility in weighing most days of the week. Participants weighing less than daily weighed about 5 days per week and still saw clinically meaningful changes in weight and some positive changes in behavior. As such, recommendations for frequent weighing with an emphasis on daily being optimal are useful for overweight and obese individuals trying to lose weight.

Previous work examining differences in diet and exercise behaviors associated with self-weighing frequency has shown similar findings, albeit they were constrained by the limitations of cross-sectional study designs and self-reported self-weighing frequency. Linde and colleagues found that individuals who weighed at least weekly ate less fat and walked more blocks each day, compared to those weighing less than weekly.13 Another study found that adolescents who reported more frequent self-weighing ate less food, less calories, and followed more of a structured diet.14 Understanding the nuanced differences in self-weighing frequency warrants further examination by randomizing to varying self-weighing frequencies, but our findings suggest that weighing everyday may be necessary to achieve behavior change success when trying to lose weight.

A major strength of the study is our use of an objective weight measurement. Most studies have relied on self-report to compare daily to weekly weighing. As a result of the objective measurement, we were able to examine the differences between weighing daily and most days of the week and not just rely on self-reported categorized self-weighing measurement. To our knowledge, there have been no other studies that have had access to daily objective weighing data in this capacity. Gokee-Larose and colleagues examined an intervention that compared daily vs. weekly weighing and utilized a scale that stored weights.10 Although they found no differences between intervention groups, both groups received an intensive behavioral intervention and they did not examine patterns in self-weighing frequency and outcomes using the objective measure. One limitation of the scale with stored weights is that only 30 days of data, can be stored, perhaps preventing an examination of total days weighed and outcomes

Vanwormer and colleagues conducted a trial that similarly provided participants with a networked connected scale that sent weights via the phone line.33 They found similar results showing more frequent self-weighing led to greater weight loss.34 However, it is not clear whether there were differences among those who weighed daily compared to those who weigh less often. The present study adds to these findings by examining daily weighing vs. less frequent weighing and offers unique data on the underlying behavior changes that are perhaps facilitated by daily weighing

Limitations

Although our findings suggest the utility of weighing everyday for greater weight loss and adoption of weight control behaviors, there are several limitations worth mentioning. First, our sample size was small and it is possible that we did not have enough power to evaluate the secondary outcomes of EBI score, caloric intake, and caloric expenditure or adjust for all possible confounders. We did not have a randomized comparison of daily weighing vs. less than daily weighing and it is possible that self-weighing frequency may be a proxy for adherence to the intervention overall. Even with that limitation, it is interesting that among those who weighed 5 days per week, the average among those weighing less than daily, we found significantly smaller weight losses and less frequent engagement with weight control behaviors. Although, those weighing 5 days still produced clinically meaningful weight loss outcomes. As such, the limited variability in self-weighing frequency does not allow us to examine whether weighing less than 5 days per week (e.g., weekly, less than weekly) produces smaller weight losses and fewer behavioral changes compared to weighing 5 days. Future research examining greater variability in self-weighing frequency or randomizing by weighing frequency is warranted. Lastly, we examined weight control strategies by individual items on the questionnaire. It is possible that multiple analyses may increase the odds of spurious findings. Finally, our sample was predominantly female, white, and college-educated. As such, it is not possible for us to infer whether similar findings would be found with a different population.

Conclusions

Daily weighing was associated with greater weight loss than weighing most days of the week. This difference is likely because those who weigh daily also report greater adoption of diet and exercise behaviors associated with weight control. The utility of daily weighing is becoming more widely adopted in the obesity research field and our findings provide further data to encourage prescribing daily weighing as the optimal self-weighing frequency.

Acknowledgements

The authors have no acknowledgements.

Funding Disclosure:

The authors thank the Lineberger Comprehensive Cancer Center, Cancer Control Education Program Fellowship (#R25 CA057726) for providing funding for the WEIGH study.

Footnotes

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