Eliana M. Perrin

Cardiometabolic Risks and Severity of Obesity in Children and Young Adults

BACKGROUND The prevalence of severe obesity among children and young adults has increased over the past decade. Although the prevalence of cardiometabolic risk factors is relatively low among children and young adults who are overweight or obese, those with more severe forms of obesity may be at greater risk. METHODS We performed a cross-sectional analysis of data from overweight or obese children and young adults 3 to 19 years of age who were included in the National Health and Nutrition Examination Survey from 1999 through 2012 to assess the prevalence of multiple cardiometabolic risk factors according to the severity of obesity. Weight status was classified on the basis of measured height and weight. We used standard definitions of abnormal values for total cholesterol, high-density lipoprotein (HDL) cholesterol, low-density lipoprotein cholesterol, triglycerides, blood pressure, glycated hemoglobin, and fasting glucose and report the prevalence of abnormal values in children and young adults according to weight status. RESULTS Among 8579 children and young adults with a body-mass index at the 85th percentile or higher (according to the Centers for Disease Control and Prevention growth charts), 46.9% were overweight, 36.4% had class I obesity, 11.9% had class II obesity, and 4.8% had class III obesity. Mean values for some, but not all, cardiometabolic variables were higher with greater severity of obesity in both male and female participants, and the values were higher in male participants than in female participants; for HDL cholesterol, the mean values were lower with greater severity of obesity. Multivariable models that controlled for age, race or ethnic group, and sex showed that the greater the severity of obesity, the higher the risks of a low HDL cholesterol level, high systolic and diastolic blood pressures, and high triglyceride and glycated hemoglobin levels. CONCLUSIONS Severe obesity in children and young adults was associated with an increased prevalence of cardiometabolic risk factors, particularly among boys and young men.

Multiple Markers of Inflammation and Weight Status: Cross-sectional Analyses Throughout Childhood

OBJECTIVE: Inflammatory markers such as C-reactive protein (CRP) are related to obesity in adults, but the association is less clear in children. Our objective was to examine relationships between multiple markers of inflammation and childrens weight status; we hypothesized that the prevalence of inflammatory markers would increase as weight status increased. METHODS: We conducted a cross-sectional analysis of children in the United States aged 1 to 17 years in the National Health and Nutrition Examination Survey, 1999–2006. Children were categorized using weight-for-length when age <2 years and BMI for ≥2 years, as very obese (≥99th percentile), obese (<99th and ≥95th percentile), overweight (<95th and ≥85th percentile), and healthy weight (>5th to ≤85th percentile) according to expert consensus. Our main outcome measures were high-sensitivity CRP and absolute neutrophil count, in addition to a novel third measure: ferritin controlled for iron status using a ferritin/transferrin ratio. We used Cox proportional hazards models to examine risk of abnormal values of inflammatory markers according to weight. RESULTS: Increased risk of a CRP level of >1.0 mg/L was evident among very obese children from ages 3 to 5 years (hazard ratio [HR]: 2.29; P < .01) through 15 to 17 years (HR: 4.73; P < .01). Increased risk of abnormal neutrophil count among very obese children began at 6 to 8 years (HR: 2.00; P = .049), and increased prevalence of abnormal ferritin/transferrin ratio began at 9 to 11 years (HR: 7.06; P < .001). CONCLUSIONS: Multiple inflammatory markers are strongly and positively associated with increasing weight status in children, and this relationship starts as young as age 3. Elevated inflammatory markers in very young obese children are particularly concerning, because inflammation may cause long-term, cumulative vascular damage. This deserves additional research via longitudinal design.

Prevalence of obesity and severe obesity in US children, 1999‐2014

Provide the most recent data on the prevalence of obesity and severe obesity among United States children and adolescents aged 2 to 19 years.

Interventions Aimed at Decreasing Obesity in Children Younger Than 2 Years: A Systematic Review

OBJECTIVE To assess the evidence for interventions designed to prevent or reduce overweight and obesity in children younger than 2 years. DATA SOURCES MEDLINE, the Cochrane Central Register of Controlled Trials, CINAHL, Web of Science, and references from relevant articles. STUDY SELECTION Included were published studies that evaluated an intervention designed to prevent or reduce overweight or obesity in children younger than 2 years. DATA EXTRACTION Extracted from eligible studies were measured outcomes, including changes in child weight status, dietary intake, and physical activity and parental attitudes and knowledge about nutrition. Studies were assessed for scientific quality using standard criteria, with an assigned quality score ranging from 0.00 to 2.00 (0.00-0.99 is poor, 1.00-1.49 is fair, and 1.50-2.00 is good). DATA SYNTHESIS We retrieved 1557 citations; 38 articles were reviewed, and 12 articles representing 10 studies met study inclusion criteria. Eight studies used educational interventions to promote dietary behaviors, and 2 studies used a combination of nutrition education and physical activity. Study settings included home (n = 2), clinic (n = 3), classroom (n = 4), or a combination (n = 1). Intervention durations were generally less than 6 months and had modest success in affecting measures, such as dietary intake and parental attitudes and knowledge about nutrition. No intervention improved child weight status. Studies were of poor or fair quality (median quality score, 0.86; range, 0.28-1.43). CONCLUSIONS Few published studies attempted to intervene among children younger than 2 years to prevent or reduce obesity. Limited evidence suggests that interventions may improve dietary intake and parental attitudes and knowledge about nutrition for children in this age group. For clinically important and sustainable effect, future research should focus on designing rigorous interventions that target young children and their families.

Fasting Might Not Be Necessary Before Lipid Screening: A Nationally Representative Cross-sectional Study

BACKGROUND: There are barriers to fasting lipid screening for at-risk children. Results of studies in adults have suggested that lipid testing might be reliably performed without fasting. OBJECTIVE: To examine population-level differences in pediatric lipid values based on length of fast before testing. METHODS: We used the National Health and Nutrition Examination Survey (1999–2008) to examine total cholesterol (TC), HDL (high-density lipoprotein), LDL (low-density lipoprotein), and triglyceride cholesterol components on the basis of the period of fasting. Young children fasted for varying times before being tested, and children older than 12 years were asked to fast; however, adherence was variable. We used ordinary least-squares regression to test for differences in lipid values that were based on fasting times, controlling for weight status, age, race, ethnicity, and gender. RESULTS: TC, HDL, LDL, or triglyceride values were available for 12 744 children. Forty-eight percent of the TC and HDL samples and 80% of the LDL and triglyceride samples were collected from children who had fasted ≥8 hours. Fasting had a small positive effect for TC, HDL, and LDL, resulting in a mean value for the sample that was 2 to 5 mg/dL higher with a 12-hour fast compared with a no-fast sample. Fasting time had a negative effect on triglycerides (β = −0.859; P = .02), which resulted in values in the fasting group that were 7 mg/dL lower. DISCUSSION: Comparison of cholesterol screening results for a nonfasting group of children compared with results for a similar fasting group resulted in small differences that are likely not clinically important. Physicians might be able to decrease the burden of childhood cholesterol screening by not requiring prescreening fasting for these components.

Use of a Pediatrician Toolkit to Address Parental Perception of Children's Weight Status, Nutrition, and Activity Behaviors

BACKGROUND Communication of childrens weight status and targeted counseling by pediatricians may change parental perceptions or child dietary and physical activity behaviors. The aim of this study was to determine whether accuracy of parental perception of childrens weight status and reports of related behaviors changed following a brief pediatrics resident intervention. METHODS Parents (N = 115) of children aged 4 to 12 years enrolled in Medicaid completed baseline questionnaires with providers about prior communication of weight status and/or body mass index (BMI), perceptions of their childrens weight, and childrens dietary and physical activity behaviors, and children were weighed and measured. Trained residents used a toolkit to communicate weight status to parents (via color-coded BMI charts) and counseled about mutually chosen healthy behaviors. Questionnaires were repeated at 1 and 3 months, and measurements were repeated for children with BMI > or =85%. RESULTS At baseline, 42% of parents of overweight children believed their children were at healthy weight. Most (n = 96; 83%) parents completed 1-month questionnaires, and 56% completed 3-month follow-up questionnaires. Improvements in fruit and vegetable consumption, sweet drinks, unhealthy snacks, frequency of restaurant food, lower-fat milk, and screen time occurred among both overweight and healthy weight children. There were also increases in discussions with providers about weight/BMI and parental accuracy of overweight assessment. CONCLUSIONS Parent accuracy of weight status and short-term childhood dietary and physical activity behavior changes improved following resident pediatrician use of a toolkit to support communication of weight status and counseling. Further research needs to determine whether accurate parental perception motivates improved behavior change or healthier BMI trajectories.

Physical Activity and BMI in a Nationally Representative Sample of Children and Adolescents

Objective. To examine objectively measured physical activity levels by age, sex, and BMI for children and adolescents in a nationally representative sample. Methods. Data were from the 2003-2004 and 2005-2006 National Health and Nutrition Examination Surveys, which included physical activity assessment by accelerometer and measured height and weight. The authors calculated minutes of moderate and vigorous activity. Results. Boys were more active than girls, and activity levels were lower at older ages. Younger children met daily recommendations for physical activity, whereas older children, especially girls, did not. Typically, weight status was inversely related to activity, though differences were less apparent among boys. Underweight children were not always more active than heavier peers.

Parental Understanding of Infant Health Information: Health Literacy, Numeracy, and the Parental Health Literacy Activities Test (PHLAT)

OBJECTIVE To assess parental health literacy and numeracy skills in understanding instructions for caring for young children, and to develop and validate a new parental health literacy scale, the Parental Health Literacy Activities Test (PHLAT). METHODS Caregivers of infants (age <13 months) were recruited in a cross-sectional study at pediatric clinics at 3 academic medical centers. Literacy and numeracy skills were assessed with previously validated instruments. Parental health literacy was assessed with the new 20-item PHLAT. Psychometric analyses were performed to assess item characteristics and to generate a shortened, 10-item version (PHLAT-10). RESULTS A total of 182 caregivers were recruited. Although 99% had adequate literacy skills, only 17% had better than ninth-grade numeracy skills. Mean score on the PHLAT was 68% (standard deviation 18); for example, only 47% of caregivers could correctly describe how to mix infant formula from concentrate, and only 69% could interpret a digital thermometer to determine whether an infant had a fever. Higher performance on the PHLAT was significantly correlated (P < .001) with education, literacy skill, and numeracy level (r = 0.29, 0.38, and 0.55 respectively). Caregivers with higher PHLAT scores were also more likely to interpret age recommendations for cold medications correctly (odds ratio 1.6, 95% confidence interval 1.02, 2.6). Internal reliability on the PHLAT was good (Kuder-Richardson coefficient of reliability = 0.76). The PHLAT-10 also demonstrated good validity and reliability. CONCLUSIONS Many parents do not understand common health information required to care for their infants. The PHLAT and PHLAT-10 have good reliability and validity and may be useful tools for identifying parents who need better communication of health-related instructions.

Using BMI to Determine Cardiovascular Risk in Childhood: How Do the BMI Cutoffs Fare?

OBJECTIVE: Although adverse health outcomes are increased among children with BMI above the 85th (overweight) and 95th (obese) percentiles, previous studies have not clearly defined the BMI percentile at which adverse health outcomes begin to increase. We examined whether the existing BMI percentile cutoffs are optimal for defining increased risk for dyslipidemia, dysglycemia, and hypertension. METHODS: This was a cross-sectional analysis of the National Health and Nutrition Examination Survey from 2001 to 2006. Studied were 8216 children aged 6 to 17 years, representative of the US population. BMI was calculated by using measured height and weight and converted to percentiles for age in months and gender. Outcome measures (dyslipidemia, dysglycemia, and hypertension) were based on laboratory and physical examination results; these were analyzed as both continuous and categorical outcomes. RESULTS: Significant increases for total cholesterol values and prevalence of abnormal cholesterol begin at the 80th percentile. Significant increases in glycohemoglobin values and prevalence of abnormal values begin at the 99th percentile. Consistent significant increases in the prevalence of high or borderline systolic blood pressure begin at the 90th percentile. CONCLUSIONS: Intervening for overweight children and their health requires clinical interventions that target the right children. On the basis of our data, a judicious approach to screening could include consideration of lipid screening for children beginning at the 80th percentile but for dysglycemia at the 99th percentile. Current definitions of overweight and obese may be more useful for general recognition of potential health problems and discussions with parents and children about the need to address childhood obesity.

Prevalence of Obesity and Severe Obesity in US Children, 1999–2016

This is a secondary data analysis of a nationally representative sample of US youth in which we report on current obesity prevalence trends through 2016. OBJECTIVES: To provide updated prevalence data on obesity trends among US children and adolescents aged 2 to 19 years from a nationally representative sample. METHODS: We used the NHANES for years 1999 to 2016. Weight status was determined by using measured height and weight from the physical examination component of the NHANES to calculate age- and sex-specific BMI. We report the prevalence estimates of overweight and obesity (class I, class II, and class III) by 2-year NHANES cycles and compared cycles by using adjusted Wald tests and linear trends by using ordinary least squares regression. RESULTS: White and Asian American children have significantly lower rates of obesity than African American children, Hispanic children, or children of other races. We report a positive linear trend for all definitions of overweight and obesity among children 2–19 years old, most prominently among adolescents. Children aged 2 to 5 years showed a sharp increase in obesity prevalence from 2015 to 2016 compared with the previous cycle. CONCLUSIONS: Despite previous reports that obesity in children and adolescents has remained stable or decreased in recent years, we found no evidence of a decline in obesity prevalence at any age. In contrast, we report a significant increase in severe obesity among children aged 2 to 5 years since the 2013–2014 cycle, a trend that continued upward for many subgroups.