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U.S. Preventive Services Task Force (USPSTF)

Screening and Treatment for Lipid Disorders in Children and Adolescents

Article—Systematic Evidence Review

Elizabeth M. Haney, MD;^1,2 Laurie Hoyt Huffman, MS;¹ Christina Bougatsos, BS;¹ Michele Freeman, MPH;¹ Robert D. Steiner, MD;³ Heidi D. Nelson, MD, MPH.^1,2,4

The authors of this article are responsible for its contents, including any clinical or treatment recommendations. No statement in this article should be construed as an official position of the Agency for Healthcare Research and Quality or the U.S. Department of Health and Human Services.

This article was first published in the Pediatrics. Select for copyright and source information.

Abstract
Introduction
Methods
Results
Conclusions
References
Notes
Appendix 1

Abstract

Objective: This was a systematic evidence review for the U.S. Preventive Services Task Force, intended to synthesize the published evidence regarding the effectiveness of selecting, testing, and managing children and adolescents with dyslipidemia in the course of routine primary care.

Methods: Literature searches were performed to identify published articles addressing 10 key questions. The review focused on screening relevant to primary care of children without previously identified dyslipidemias, but included treatment trials of children with dyslipidmia because some drugs have only been tested in that population.

Results: Normal values for lipids for children and adolescents are defined according to population levels (percentiles). Age, sex, and racial differences and temporal trends may alter these statistical cut points. Approximately 40-55% of children with elevated total cholesterol and low-density lipoprotein will continue to have elevated lipids on follow-up. Current screening recommendations based on family history will fail to detect substantial numbers (30-60%) of children with elevated lipids.

Drug treatment for dyslipidemia in children has been studied and shown to be effective only for suspected or proven familial monogenic dyslipidemias. Intensive dietary counseling and follow-up can result in improvements in lipids, but these results have not been sustained after the cessation of the intervention. The few trials of exercise are of fair-poor quality and show little or no improvements in lipids for children without monogenic dyslipidemias. Although reported adverse effects were not serious, studies were generally small and not of sufficient duration to determine long-term effects of either short or extended use.

Conclusions: Several key questions about screening and treatment of dyslipidemia in children and adolescents could not be addressed because of lack of studies, including effectiveness of screening on adult coronary heart disease (CHD) or lipid outcomes, optimal ages and intervals for screening children, or effects of treatment of childhood lipid levels on adult CHD outcomes.

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Introduction

Dyslipidemias are disorders of lipoprotein metabolism resulting in abnormal excesses of total cholesterol (TC), low-density lipoprotein cholesterol (LDL-C), or triglycerides, or deficiency of high-density lipoprotein cholesterol (HDL-C).^1,2 Dyslipidemia is an established risk factor for coronary heart disease (CHD)—the leading cause of death for adults in the US.³ Dyslipidemia rarely leads to adverse health outcomes in childhood, but its long-term effects may be considerable. While no long-term studies of the direct relationship between lipid levels measured in children and CHD later in life have been conducted, this relationship can be inferred. Large epidemiologic studies indicate that children's lipid levels correlate with those of adult family members.⁴ Children of parents with CHD have a higher prevalence of dyslipidemia in childhood,⁵ and identification of dyslipidemia in children can identify families at increased risk for CHD.⁴ Studies of children and young adults who died accidentally report correlations between lipid levels and arterial fat deposition,^6,7 and note early lesions of atherosclerosis (fatty streaks) in the abdominal aorta at age three years, coronary arteries at age 10 years, and further progression with age.^8-12 Increasing prevalence of risk factors for CHD among children, including metabolic syndrome and obesity, as well as continued emphasis on primary prevention of CHD has raised interest in screening children for dyslipidemia.^13-15

Dyslipidemia is defined by laboratory testing and statistically determined criteria. Elevated LDL-C is the most common clinically significant marker of dyslipidemia in children. The majority of children with dyslipidemia will have idiopathic dyslipidemias (polygenic, risk factor associated, or multi-factorial), while a minority will have monogenic or secondary dyslipidemias. The more common genetic dyslipidemias include familial hypercholesterolemia (FH), familial combined hyperlipidemia (FCH), familial defective apoprotein-B, and familial hypertriglyceridemia.

Most treatment recommendations advise a low-fat, low-cholesterol diet, such as the American Heart Association (AHA) Step I diet, for children with dyslipidemia beginning at age two years and older.¹⁴ Children younger than two years should not be prescribed a low-fat, low-cholesterol diet because their rapid growth and development require adequate fat and cholesterol intake.^16,17 Children and adolescents with FH or FCH are the only non-adults for whom trials of drug therapy are available and drugs are approved by the US Food and Drug Administration (FDA). Bile acid-binding resins are the only medications approved for treatment of dyslipidemia for children younger than eight years of age. HMG Co-A reductase inhibitors (statins) are approved for use in older children with heterozygous FH.^18,19 Other medications used in adults for treatment of hyperlipidemia, such as niacin, are either not recommended for children or have not been adequately evaluated for safety and efficacy in children. Additional interventions for children include dietary supplements (fiber, sterol or stanol margarines, omega-3 fatty acids), exercise, weight loss for overweight children, and identification and treatment of diabetes mellitus or other causes of secondary dyslipidemia.

The relationship between childhood and adult dyslipidemia, increasing prevalence of related CHD risk factors in children (e.g., obesity and diabetes),^13-15 and continued emphasis on a primary prevention approach for CHD has raised interest in screening children for dyslipidemia. Identifying children with dyslipidemia could lead to interventions or treatments that could prevent or delay adult dyslipidemia and CHD. This rationale lends support to consideration of screening for dyslipidemia as part of well-child care and at other opportunities. Clinic-based screening, neonatal screening, community-based screening, and other prevention strategies have been proposed, but most recommendations support selective strategies testing children who have family members with dyslipidemia or premature CHD and those with unknown family histories.^16,20

This evidence review focuses on the strengths and limitations of evidence for identifying and managing children and adolescents with dyslipidemia determined by screening in the course of routine primary care. Its objective is to determine the balance of potential benefits and adverse effects of screening for development of guidelines by the US Preventive Services Task Force (USPSTF). The target population includes children and adolescents age 0 to 21 years without previously-known conditions associated with dyslipidemia. There is potential to identify children and adolescents with dyslipidemia in this population from among three groups: those with undiagnosed monogenic dyslipidemias, such as familial hypercholesterolemia; those with undiagnosed secondary causes of dyslipidemia (diabetes, nephrotic syndrome, hypothyroidism, others); and those with idiopathic dyslipidemia (polygenetic, risk factor associated, or multi-factorial) (Figure 1). Although children and adolescents with idiopathic dyslipidemia generally have less severe lipid abnormalities than children and adolescents with monogenic disorders, such abnormal levels could still potentially improve with intervention.

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Methods

Evidence reviews for the USPSTF follow a specific methodology²¹ (Figure 2). Key questions examine a chain of evidence about the accuracy and feasibility of screening children and adolescents for dyslipidemia in primary care or community settings (Key Question 1), abnormal lipid values (Key Question 2a), appropriate tests (Key Question 2b), tracking of lipid levels through childhood to adulthood (Key Question 2c), accuracy of family history (Key Question 2d), role of risk factors in selecting children and adolescents for screening (Key Question 2e), effectiveness of interventions for children and adolescents identified with dyslipidemia (Key Questions 4-8, 10), and adverse effects of screening and interventions (Key Questions 3, 9).

Studies that addressed Key Question 1 (Figure 2) include all components in the continuum of the screening process: the screening evaluation, diagnostic evaluation for those identified by the screening results, interventions for those diagnosed with dyslipidemia, and outcome measures allowing determination of the effectiveness of the overall screening process.

Studies of children with previously diagnosed conditions known to cause dyslipidemia were not included because the scope of this review is screening children without known diagnoses. Specifically, studies of children with diabetes were not included because these children would already be under surveillance for dyslipidemia as a result of their primary disease. This review includes treatment trials of children and adolescents using dietary, exercise, and drug interventions. Trials of drug therapy in children with heterozygous FH or FCH are included because drug treatment trials have been conducted exclusively in this population.

Relevant studies were identified from multiple searches of MEDLINE® (1966 through September 2005).²² We obtained additional articles from recent systematic reviews, reference lists of related studies, reviews, editorials, and Web sites, and from consulting experts. Retrieved abstracts were entered into an electronic database (EndNote®).

Investigators reviewed all identified abstracts and determined eligibility by applying inclusion and exclusion criteria specific to each key question. Full-text articles of included abstracts were reviewed for relevance. Eligible studies were English-language, applicable to US clinical practice, and provided primary data relevant to key questions. Studies of risk factors were included only if they provided multivariate adjusted analyses.

For treatment studies, full text randomized controlled trials (RCTs), non-controlled clinical trials, and non-controlled prospective studies providing data on the treatment of children and adolescents with diet, drug therapy, exercise, or combinations of these were initially reviewed. Subsequently, only RCTs and meta-analyses of RCTs that reported serum lipid outcomes were included. Crossover trials were included if they reported data prior to crossover. For Key Question 10, outcomes included either adult lipid levels or adult CHD. Information about adverse effects of treatment was obtained from RCTs and additional sources, such as non-randomized controlled treatment trials and non-comparative studies of treatment.

Data were extracted from each study, entered directly into evidence tables, and summarized. Benefits and adverse effects of therapies were considered equally important and both types of outcomes were abstracted. Trials of therapy for children and adolescents with dyslipidemia were categorized by population and intervention. Two reviewers independently rated the RCTs' quality using US Preventive Services Task Force criteria (Appendix 1).²¹

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Results

Our literature search identified 2,507 unique citations, including 144 papers about screening and testing for dyslipidemia (Key Question 2); 43 about interventions and tracking of lipid values over time (Key Questions 4-8 and 10); 6 about the adverse effects of screening (Key Question 3) and 84 about adverse effects of treatment (Key Question 9).

Key Question 1. Is screening for dyslipidemia in children/adolescents effective in delaying the onset and reducing the incidence of CHD-related events?

No studies evaluated the effect of screening children and adolescents on adult lipid or disease outcomes.

Key Question 2. What is the accuracy of screening for dyslipidemia in identifying children/adolescents at increased risk of CHD-related events and other outcomes?

Key Question 2a. What are abnormal lipid values in children/adolescents?

While several studies conducted in the US during the 1970s obtained lipid levels from large samples of normal healthy children,^23-25 current recommendations^14,16,20,26 are based on distributions of lipid and lipoprotein levels obtained from the Lipid Research Clinics (LRC) Prevalence Study.²⁷ This study included one Canadian and nine US sites and enrolled subjects primarily based on residency within census tracts, school enrollment, and employment in occupational and industrial groups. Fasting (>12 hours) lipoprotein levels were obtained in 15,626 children age 0 to 19 years between 1972 and 1976. The selected populations included a broad range of geographic, socio-economic, occupational, sex, and ethnic groups, but were not selected to be a representative sample of the North American population.

In the LRC sample, TC levels increased from birth and stabilized at approximately 2 years of age. At puberty, TC levels declined slightly for both boys and girls, and HDL-C levels declined for boys. For all children, the mean serum level for TC was approximately 160 mg/dL and for LDL-C was 100 mg/dL. The 95th percentile level was 200 mg/dL for TC and 130 mg/dL for LDL-C. While results for African American children were similar, they were based on smaller numbers and provided only TC and triglyceride data.²⁷

More recent data from the National Health and Nutrition Examination Survey (NHANES) III (1988 to 1994) were derived from 7,499 children and adolescents ages 4 to 19 years. These provided 95th percentile levels of 216 mg/dL for serum TC, and 152 mg/dL for LDL-C.²⁸ Mean age-specific TC levels peaked at 171 mg/dL at 9 to 11 years and declined at older ages. Girls had significantly higher mean TC and LDL-C levels than boys (p<0.005). Non-Hispanic Black children and adolescents had significantly higher mean TC, LDL-C, and HDL-C levels compared to non-Hispanic White and Mexican-American children and adolescents. In linear regression models of these data, age, sex, and race have significant effects on lipid levels questioning the utility of fixed screening cut points.²⁹

Key Question 2b. What are the appropriate tests? How well do screening tests (non-fasting total cholesterol, fasting total cholesterol, fasting lipoprotein analysis) identify children and adolescents with dyslipidemia?

In the American Academy of Pediatrics (AAP) and the National Cholesterol Education Program (NCEP) guidelines, TC is used as an initial laboratory measurement for children tested because of a family history of high cholesterol or vascular disease, and a lipoprotein profile is obtained if the patient has a TC over a certain defined target.^16,20 In children LDL-C is the basis for initiating treatment and determining goals of therapy.

How well TC levels detect elevated LDL-C levels has been examined with LRC data (ages 6 to19, n=1325),³⁰ and data from the biracial Bogalusa cohort (ages 5 to 17, n=2,857).³¹ Elevated levels were defined as >95th percentile. With LRC data, an elevated fasting TC detected children with elevated LDL-C and elevated triglycerides with 69% sensitivity and 98% specificity.³⁰

In the Bogalusa cohort, elevated TC detected elevated LDL-C with 44% (white females) to 50% (white males, African American males and females) sensitivity and 90% specificity (African American and white males and females).³¹

In adults, both TC and HDL-C are recommended for screening. While this has not been recommended in guidelines for children and adolescents, it is common in practice.³² HDL-C may help distinguish false negatives from true negatives when used with TC.³⁰ In 260 African American adolescents ages 12 to 20 years, fasting TC minus HDL-C above the 95th percentile was 88-96% sensitive and 98% specific for predicting LDL-C >130 mg/dL.³³ Using a lower threshold of fasting TC > the 75th percentile to detect LDL-C > the 95th percentile is a sample of Hispanic children ages 4-5, sensitivities were 86% (using an LRC defined 75th percentile) and 96% (using the sample-defined 75th percentile), and specificities were 93% (LRC defined) and 87% (sample defined).³⁴ A TC > 215 mg/dL is required, however, to accurately identify a child with elevated LDL-C with 95% confidence. No single TC value places a child in the borderline category (170-200 mg/dL) with 95% confidence.³⁵ Direct measurement of LDL-C can be done using non-fasting serum samples and may be as precise as calculated LDL-C, but this remains controversial.^36,37

Key Question 2c. How well do lipid levels track from childhood to adulthood?

Twenty-three prospective cohort studies contributed information on tracking lipid levels during childhood.^38-60 These studies drew from seven US cohorts and eight non-US cohorts. Approximately 40% to 55% of children with elevated lipids, defined by percentile within a population distribution, will continue to have elevated lipids on follow-up (4-15 years later).²² None of these studies, however, evaluated the proportion of children and adolescents with lipid levels above the 95th percentile who remained in the top 5% at follow-up.

Key Question 2d. What is the accuracy of family history in determining risk?

Several good-quality studies of diagnostic accuracy evaluated the sensitivity and specificity of family history information in determining risk for dyslipidemia in children and adolescents (Table 1).^33,34,61-74 Studies used different definitions of family history such as any parental history of heart attack, other parental risk factors, and varying age definitions of early CHD, and selected different levels of LDL-C or TC as the lipid detection threshold. For example, parental history of early CHD alone was 5% to 17% sensitive for TC >170 mg/dL or LDL-C >130 mg/dL,^34,63 whereas parent or grandparent history of early CHD was 46% sensitive for LDL >the 95th percentile.⁶⁵

Regardless of the precise definition, using positive family history information to trigger lipid testing misses substantial numbers of children with elevated lipids, ranging from 17-90% overall and 30-60% in most studies.^{33,64,65,68,70,72,75-77} The proportion of children and adolescents qualifying for screening based on family history is generally between 25% to 55%, depending on the sensitivity of the specific family history question.^{33,34,61-65,67,70,71,73,78}

Key Question 2e. What are other important risk factors?

Forty-three cohort and cross-sectional studies of mixed quality with adjusted statistical analyses contributed information on additional risk factors for identifying children at increased risk for elevated lipids and/or CHD-related events.^66,79-120 Thirty studies examined overweight or body fat composition measures as a risk factor for dyslipidemia.^{79-82,84-86,89-95,99,101-104,106-112,114,115,117,119} These measures were the most consistently effective in predicting risk of dyslipidemia, compared to other factors assessed.²² Childhood overweight, as measured by BMI, was the best independent predictor of adult dyslipidemia after LDL-C, specifically when considering BMI increases from childhood to adulthood.¹²¹ Five of six studies evaluating overweight as a risk found that overweight was associated with abnormal lipid levels.^{85,86,94,110,115,117}

Key Question 2f. What are effective screening strategies for children/adolescents (including frequency of testing, optimal age for testing)?

Thirty-two studies evaluated screening strategies among children in various settings.^{33,34,61,63-66,68,70,72,76,77,122-141} The only RCT compared two regimens for screening college students.¹³¹ All others were non-comparative prospective studies tht described screening interventions and differed considerably in venue (school, pediatric clinic, hospital, or population-based cohort), methods (fasting or non-fasting samples, method for detecting of positive family history), and outcomes. Most reported low parental compliance with follow-up testing,^76,136-139 even when follow-up was provided free of charge, as in pre-paid health plans.

Studies demonstrate low compliance among primary care physicians in following current guidelines for screening.¹⁴⁰ In an ancillary study of the Child Adolescent Trial for Cardiovascular Health (CATCH), parents were given recommendations to consult their child's physician if TC exceeded 200 mg/dL on one or more occasions.¹⁴¹ After physicians examined the children, only 59% were further evaluated for possible elevated cholesterol. Of these, half of the physicians repeated cholesterol tests, 42% asked about family history, 38% made recommendations for dietary management, and only 12% referred children to dietitians.¹⁴¹

Neonatal screening for dyslipidemia has been examined in multiple studies of either cord blood testing,^54,142-155 dried filter paper blood spots from cord blood,¹⁵⁶ or heel sticks of three to seven day old infants. ^157-162 No studies screened a general population of infants and followed abnormal results with mutation analysis or LDL-C receptor activity assays making it difficult to determine the value of such screening.

Key Question 3. What are the adverse effects of screening (including false positives, false negatives, labeling)?

Potential adverse effects of screening for dyslipidemia among children were examined in one randomized controlled trial¹⁶³ and five non-comparative studies.^76,136-139 Although one small study showed increased parental reporting of behavior difficulties among children with dyslipidemia, these reports were not objectively confirmed.¹³⁹ No studies reported increased anxiety or depression among screened children or their parents.^137,138 ¹³⁹

Key Question 4. In children/adolescents, what is the effectiveness of drug, diet, exercise, and combination therapy in reducing the incidence of adult dyslipidemia, and delaying the onset and reducing the incidence of CHD-related events (including optimal age for initiation of treatment)?

No studies evaluated the effect of a childhood intervention on the incidence of adult dyslipidemia or CHD-related events and outcomes.

Key Questions 5-8. What is the effectiveness of drug, diet, exercise, and combination therapy for treating dyslipidemia in children/adolescents?

Forty RCTs meeting the inclusion criteria addressed the effectiveness of interventions for treatment of dyslipidemia in children and adolescents.^{18,19,164-201} Statins, bile-acid binding resins, and fibrates have been tested and reported only in children with FH and FCH. Applicability of results from these trials to children without these conditions may be limited. In addition, 18 studies used populations recruited from single lipid clinics.^{18,165-169,176,178,179,181,182,185,186,189,191,193,196,202} Major limitations of trials include fewer than 20 subjects in each study arm,^{168,175,178,181,182,185,193,195} high loss to follow-up,^177,187,191 failure of blinding,^{174,191,192,196-198} lack of results presented for the period prior to crossover,^{166-168,176,178,180-182,185,189,190,192,195,198,199,201} lack of intention to treat analyses,^{164,166,177-180,182,184,187,189,191-194,196-198} and lack of data reported for the placebo group.¹⁷⁹

Studies in children with probable or definite familial hypercholesterolemia

Drug treatment. Eleven trials evaluated drug therapies for treatment of children with probable or definite heterozygous familial hypercholesterolemia (Table 2).^{18,19,163,167,170,171,177,182,184,185,186} Most of these included children who were already compliant with a recommended low-saturated fat, low-cholesterol diet, and both treatment and control groups were maintained on the diet during the trials.

All the trials of statin drugs,^{18,19,165,169,172,173,179,184,188} demonstrated improvement in TC and LDL-C among children and adolescents with FH. The decrease in TC compared to baseline ranged from 17-32% for treatment groups vs. changes of +3.6% to –2.3% for placebo groups. The decreases in LDL-C ranged from 19-41% for treatment groups, vs. changes of +0.67% to –3% for placebo groups. Changes in HDL-C and triglycerides were mixed.^{165,169,172,173,179,184,188}

Trials of cholestyramine¹⁸⁷ and colestipol¹⁸⁶ demonstrated decreased total cholesterol and LDL-C, but no change in HDL-C or triglycerides. Trials evaluating bezafibrate,¹⁹³ vitamins C and E,¹⁸² DHA,^199,201 p-aminosalicylic acid,¹⁸⁵ combined colestipol and pravastatin vs. colestipol alone¹⁶⁶ and powder vs. pill form of cholestyramine¹⁷⁴ failed to report pre-crossover data.

Diet treatment. Five trials evaluating diet treatments in children with FH or FCH met inclusion criteria. ^{167,168,178,180,200} Although trials of sterol margarines and psyllium were crossover trials without pre-crossover results presented, the wash-out periods between treatment phases were four to six weeks, suggesting that results may be valid.^167,178,180 TC and LDL-C reductions were significant in these trials (reduction of 7.4-11% and 10-14% respectively). There was no significant improvement in lipid levels with eight weeks of garlic extract treatment.²⁰⁰

Exercise treatment. No studies evaluated exercise treatment for lipid lowering in children with FH.

Studies in children with elevated lipids but not meeting criteria for familial hypercholesterolemia

Drug treatment. No studies evaluated drug interventions in children without monogenic dyslipidemia.

Diet treatment. Dietary interventions in general populations of children and adolescents were addressed in seven studies (Table 3).^{170,171,174,190,191,194,196} A trial conducted by the DISC Collaborative Research Group showed that intensive dietary counseling over three years was effective (8% improvement in LDL-C compared to control),¹⁷¹ but not sustained at five and seven year follow-ups once the intervention ceased.¹⁷⁰ A study of the Parent-Child AutoTutorial (PCAT) program¹⁷⁴ reported 8% improvement in LDL-C compared to the at-risk control group (p<0.05). One trial of psyllium did not present pre-crossover data.⁸¹

Exercise treatment. Six studies ^{183,197,198,189,192,195} evaluated exercise in normal or obese children with elevated lipids (Table 3). Three studies were limited by differential or low completion rates, small numbers of participants, or other deficiencies (lack of blinding, lack of intention to treat analysis).^{189, 192, 195} Four trials comparing supervised, scheduled sessions of aerobic and fitness training to control groups showed minimal or no change in lipids compared to control groups.^{189,192,197,198} Two trials showed improvements in HDL-C for the exercise intervention group compared to controls.^183,195

Combination diet and exercise treatment. Three trials ^175,177,164 evaluated combined regimens of diet and exercise (Table 3). While all interventions showed some improvement in lipid levels, a group undertaking exercise, diet, and behavior change had a 23% increase in HDL-C, compared to both the diet plus behavior change group and the control group.¹⁷⁵

Key Question 9. What are the adverse effects of drug, diet, exercise, and combination therapy in children/adolescents?

Drug treatment. Information about adverse events was reported in 15 studies of statins,^{18,19,165,169,172,173,179,184,188,203-208} in 22 studies of bile-acid binding resins ^{166,176,186,187,209-227} and in eight studies of various other drugs or drug combinations (Table 4).^{26,185,193,228-232} Studies used RCT, open-label trial, and observational designs.

Statins were associated with increased ALT and/or AST levels in some,^{169,188,204,207} but not all, studies.^{18,165,203,205} Reports of elevated CK levels were similarly conflicting.^{172,173,184,188,204,205,207,18,165,172,203}

Bile-acid binding resins were associated with gastrointestinal complaints (8-26%), such as flatulence and constipation, ^{166,176,185-187,211,214,216,218,223,224,229,230} and unpalatability (up to 50%).^{212,216-219,222,224} One study of cholestyramine reported transient increases in LDH and abnormalities in AST that persisted for six months,²¹¹ but others showed normal liver function tests.^224,226,227 Growth was reported normal in nine studies.^{26,186,187,193,215,220,221,225,227} One study reported a child whose height for age dropped below –2 S.D. while on colestipol (1 S.D. = 2.4 cm),²¹³ while growth was normal in all other children in the study. Sexual maturation was followed over 4.3 years of treatment and found to be normal.²²⁵

Two studies of niacin reported increased liver enzymes (6 of 21 children in one study), and multiple other symptoms such as flushing, abdominal pain, nausea, and headache.^229,231 There are also case reports of hepatitis²²⁹ and hepatotoxicity²³¹ with niacin.

Low-fat diet. Nineteen studies of dietary fat restriction reported effects on growth, nutrient intake, laboratory safety parameters, or other adverse effects.^{170,171,190,233-248}

Twelve studies reported normal height growth,^{170,190,234-236,239,240,242,243,245-247} although weight loss occurred among three children in two of these studies.^235,242 Growth failure in one study occurred among 8 of 40 (20%) children with dyslipidemia, three (7.5%) of whom had nutritional dwarfing and no progression of puberty.²⁴¹ In this study, families were unsupervised in the implementation of low-fat, low-cholesterol diets for a period up to 4.5 years; those with nutritional dwarfing had longer periods of time between diagnosis and formal dietary assessment and counseling.²⁴¹ Failure to thrive has been demonstrated in children under age two years eating fat-restricted diets.²⁴⁹ although these diets are not recommended for this age group.¹⁶

Dietary supplements. Fourteen studies provided information about adverse effects of various dietary supplements.^{168,178,181,200,250-259} Two children (4% of the treatment group) reported abdominal discomfort using fiber tablets (containing 50% wheat bran and 50% pectin) administered at 100-150 mg/kg/day.^181,253,256 There were no adverse effects with psyllium fiber in two other studies.^181,253 Other adverse effects of dietary supplements were mild or transient.²²

Exercise. A school-based program examined the effect of supervised exercise training on the lipid profiles of normal prepubertal children and reported 100% adherence and no adverse effects.²⁶⁰ In another study, treadmill tests elicited an exaggerated blood pressure response in boys with dyslipidemia.²⁶¹

Key Question 10. Does improving dyslipidemia in childhood reduce the risk of dyslipidemia in adulthood?

No studies were identified that directly evaluated whether treatment of idiopathic dyslipidemia in childhood reduces risk of dyslipidemia in adulthood.

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