Effect of adherence to carbohydrate counting on metabolic control in children and adolescents with type 1 diabetes mellitus

Sinem Bayram; Gül Kızıltan; Onur Akın

doi:10.6065/apem.1938192.096

Ann Pediatr Endocrinol Metab > Volume 25(3); 2020 > Article

Bayram, Kızıltan, and Akın: Effect of adherence to carbohydrate counting on metabolic control in children and adolescents with type 1 diabetes mellitus

Original Article

Annals of Pediatric Endocrinology & Metabolism 2020;25(3): 156-162.

Published online: July 29, 2020

DOI: https://doi.org/10.6065/apem.1938192.096

Effect of adherence to carbohydrate counting on metabolic control in children and adolescents with type 1 diabetes mellitus

Sinem Bayram, PhD¹

, Gül Kızıltan, PhD¹, Onur Akın, MD²

¹Department of Nutrition and Dietetics, Faculty of Health Science, Baskent University, Ankara, Turkey

²Department of Nutrition and Dietetics, Gulhane Education and Research Hospital, Faculty of Health Science, Baskent University, Ankara, Turkey

Address for correspondence: Sinem Bayram, PhD Depar tment of Nutrition and Dietetics, Faculty of Health Science, Baskent University, Ankara, Turkey
Tel: +90-5335434657 Fax: +90-3122466666 E-mail: metins@baskent.edu.tr

Received December 2, 2019 Revised February 18, 2020 Accepted March 2, 2020

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Purpose

Carbohydrate counting provides better glycemic control and flexibility than other food planning methods. Consistent adherence to such a complex method is difficult, especially for youth. However, studies that determine adherence to this method and whether it alters metabolic control are limited. The aim of the current study was to determine adherence to this method and investigate its effect on metabolic control, anthropometric measurements, insulin dose, and energy intake.

Methods

In this prospective cross-sectional study, 53 children and adolescents with type 1 diabetes mellitus aged 2 to18 years and receiving intensive insulin therapy were trained and followed for 6 months. Demographics, anthropometrics, insulin requirements, hemoglobin A1c (HbA1c), fasting lipids, and food records at baseline and study conclusion were evaluated. At the end of the study patients were divided into adherer and nonadherer groups according to carbohydrate estimate deviations from standardized daily sample menus and calculations for accurate insulin doses. More than 10-g variation in daily consumed carbohydrate amount or failure to decide bolus insulin dose was defined as a nonadherer.

Results

The mean HbA1c, low-density lipoprotein cholesterol, and body mass index standard deviation score changed after the carbohydrate counting training while the mean HbA1c between groups was significant (P<0.05). Total daily insulin doses increased, and the mean high-density lipoprotein cholesterol levels decreased in both groups. There were significant correlations between HbA1c and carbohydrate deviation scores as well as HbA1c and caregiver's education level.

Conclusions

Since adherence to carbohydrate counting may affect metabolic control, health professionals should evaluate and monitor carbohydrate counting skills of caregivers and patients in order to improve efficiency.

Keywords: Type 1 diabetes mellitus, Carbohydrate counting, Adherence, Carbohydrate, Child, Adolescents

Introduction

Metabolic control is an integral component of diabetes management [1]. For the reason that carbohydrates are the principal macronutrient affecting glycemic excursions, intensive insulin therapy and carbohydrate estimation become central to optimizing metabolic control according to the Diabetes Control and Complications Trial. Carbohydrate counting has been reported to provide better glycemic control and flexibility than other meal planning methods in children and adolescents with type 1 diabetes mellitus (T1DM) [2]. Since the method requires frequent blood glucose monitoring, keeping food records, reading food nutrition labels, and food weighing, adherence associated problems have been reported [3].

Children and adolescents have different age-specific hemoglobin A1c (HbA1c) goals than adults who require special standards of care. Many children and adolescents have elevated postprandial glucose levels and HbA1c values that exceed age-specific goals [3]. Common barriers to children and adolescent adherence are peer influences, depression, disordered eating, insufficient continuous glucose monitoring, and so on. Moreover, such cognitive and emotional factors affect metabolic control and quality of the diet [4]. Previous studies indicate low adherence to dietary guidelines in type 1 diabetic children and adolescents [5-8]. To prevent obesity, dyslipidemia, hypertension and the microvascular complications associated with hyperglycemia, dietary adherence and quality should be improved. Thus, individual counseling, regular training, and more intensive education are needed for both patients and their families [3,9].

Some patients think they are applying "carbohydrate counting" however they estimate preprandial insulin doses with approximate estimation rather than calculating carbohydrate content of the meal. Thus, they can over- or underestimate a meal's carbohydrate content [10]. Accurate estimation of carbohydrates to be consumed in a meal is critical to achieving target glycemic control. Although no standardized approach to assess adherence to carbohydrate counting is available, carbohydrate estimation and quantity of carbohydrate consumed in relation to insulin dose can be examined [5,6]. It is well known that carbohydrates are primary postprandial glucose modifying macronutrients [9]. Smart et al. [11] have proven that 20 g of ingested glucose causes significant postprandial hyperglycaemia when insulin is not given. Based on this result 20-g variation in actual carbohydrate content can critically affect postprandial glycaemia in children using intensive insulin therapy. Thus, researchers stated that carbohydrate estimations should be within 10 g of the actual meal carbohydrate for optimal postprandial glucose.

Few data exist on adherence to carbohydrate counting in youth with T1DM, yet it is a recommended part of diabetes management [12,13]. Bolus insulin adjustments for the meal are associated with optimal glycemic control independent of which method is used when assessing carbohydrate amount. However, the impact of carbohydrate counting on serum lipid parameters and BMI z-scores are not yet clear. Consequently, the aim of this study was to assess the effect of adherence to carbohydrate counting on glycemic control, serum lipid levels, anthropometric measurements, total daily insulin dose, and energy intake among children and adolescents with T1DM.

Materials and methods

1. Subjects

After exclusion of patients with another systemic disease except T1DM and those that were using medications that interfere with diabetes management, 53 children and adolescents followed by the Gulhane Education and Research Hospital Pediatric Endocrinology Department and ages 2 to 18 years, receiving intensive insulin therapy, and using carbohydrate counting for meal planning for at least 6 months were enrolled in the study. For analyses, 5 patients who did not attend follow-up visits or had missing records were excluded, thus 48 patients’ results were evaluated in the final analysis.

2. Study plan

Sociodemographic information, nutritional habits, and disease related data were collected via a survey. The survey was completed at the time of the routine clinic visit, and diet records were completed in a week after the visit.

Problems associated with the carbohydrate counting method were determined by the dietitian through preliminary interviews and education repeated for confused patients. All interviews (hospital visits and phone calls) were conducted by the same researcher.

3. Dietary intake and nutrient analysis

Dietary habits were examined using an open ended, dietitianadministered dietary history in a section of the survey. Families were instructed to keep detailed 24-hour dietary recall since it has been reported to capture dietary intake with less bias than food-frequency questionnaires. Recalls were performed on 3 consecutive days in a week, including 2 weekdays and 1 weekend. A photographic atlas was used to record the type and portion size of the food/fluid/meal. Dietary records were checked by the dietitian and asked to be repeated if needed.

The energy and nutrient intakes of patients were analyzed by the dietitian using the Nutrition Database for Turkey Ebispro for Windows (BEBIS), Germany, version 7.0 [14] and compared with the Recommended Dietary Allowances (RDA) [15]. BEBIS is a software program that is designed to calculate the nutritional values of Turkish foods and commercial foods.

4. Anthropometrical measurements

Height was measured to the nearest 0.1 cm, and weight to nearest 0.1 kg in light clothing and without shoes. All anthropometrical measurements were performed by the same trained staff. Body mass index (BMI) and BMI standard deviations (SDs) according to age and sex were calculated and evaluated with World Health Organization child growth references and standards. According to these, -1 to +1 SD is accepted as normal weight, <-1 SD as underweight, +1 to +2 as overweight and ≥+2 SD as obese [16].

5. Carbohydrate counting training

Individual training was conducted for study participants. On the first day, general information such as healthy meal planning, the effect of nutrients (carbohydrate, protein, fat) on glycemia, the amount of carbohydrate in foods, foods containing 15 g of carbohydrate defined as a carbohydrate change, and portion sizes were taught by solving sample menus. For this training, a 4-hour interview was conducted with each patient. At the end of this phase, patients were asked to record their fasting and postprandial blood glucose measurements, insulin doses, nutrient consumption, and carbohydrate content of their meals for the next day. On the second and third days these records were checked, and subjects such as meal planning and frequency; interaction between consumed foods, physical activity, and insulin doses; and correct label reading according to the type of insulin used by the patient were discussed. Target blood glucose levels were determined followed by discussions about how to achieve them.

It was thought that advanced carbohydrate counting training could be initiated in patients whose blood glucose control was achieved and whose basal insulin dose was adjusted correctly. After endocrinologists reported that participating patients met this condition, the patients were recalled a week later with their 5-day food records, at least 4 fasting and postprandial blood glucose measurement records, and the form on which they recorded insulin doses. Meal-specific carbohydrate/insulin ratios were calculated according to the amount of carbohydrates consumed in patients' meals and changes in blood glucose levels. The patients were taught how to use the insulin sensitivity factor (IDF). Although the duration of the training varied according to the patients’ level of understanding, a 4-hour interview was conducted and this stage of the training was repeated in those who could not answer the questions correctly. After the 3 stages of carbohydrate counting were taught, the training was completed by dissolving samples with groups of 3 to 4 patients and their parents so that patients could share their knowledge and experiences. Participation in group trainings varied depending on the patient's/family's desire and level of understanding.

6. Adherence evaluation

All 3-day food records and standardized daily sample menus were evaluated to determine their accuracy in carbohydrate estimation. The mean difference between patients' and dietitians’ carbohydrate estimation was computed. To set adherence classification, ≥10-g variation from actual carbohydrate content (dietitian assessment) of meals was used. The carbohydrate content of snacks and its accuracy was not included for the adherence evaluation because patients did not cover snacks with bolus insulin.

All patients and parents were asked to calculate the carbohydrate content of standardized daily sample menus and their own food records to define how they would intervene for low, normal, and high blood glucose levels in the carbohydrate count adherence form in order to determine the compliance and skills of carbohydrate counts at the end of the sixth month. Questions asked on the carbohydrate count adherence form included, "Did the patient administer the correct insulin dose according to the menu consumed," "Did the patient calculate the carbohydrate content appropriately," and "Did the patient use the IDF correctly?"

7. Biochemical parameters

HbA1c and lipid parameters were used to evaluate metabolic control. HbA1c values were evaluated according to goals of The Society of Turkish Endocrinology and Metabolism of Turkey (<7.5%–8.5% for ages <6 years old, <8.0% for ages 6 to 13 years old, and 6.5%–7.0% for ages 13–19 years old) [17]. Reference values of the American Academy of Pediatrics Clinical Report on Lipid Screening in Children were used for lipid parameter classifications [18]. According to this report, levels of low-density lipoprotein (LDL)-cholesterol <110 mg/dL, high-density lipoprotein (HDL)-cholesterol≥35 mg/dL, total cholesterol <170 mg/dL, and triglycerides <160 mg/dL were accepted as reference values.

8. Statistical analysis

Data analysis was conducted using the statistical software package IBM SPSS Statistics software ver. 22.0 (IBM, Armonk, New York, USA). Continuous variables are presented as the mean and SD, and categorical variables as the frequency and percentage. Fisher exact test was used for independent group comparisons in categorical variables. Variables were examined for normality distribution by the Shapiro-Wilk test. If the distribution was normal, comparisons between baseline and final values were performed with the paired sample t-test; otherwise, the Wilcoxon signed-rank test was used. The independent samples t-test or Mann-Whitney test was used to compare the mean difference between groups. Pearson correlation coefficients were utilized to determine correlation values between variables. Significant values of P<0.05 were considered to be statistically significant.

Results

The mean age of study group participants (n=53) was 10.8±4.0 years and the interquartile range of diabetes duration was 0.79–4.62 years. Demographic, clinical, laboratory, and general dietary characteristics of the adherer and nonadherer patients at baseline are given in Table 1. There was no significant difference between the 2 groups at the beginning of the study (P>0.05).

No changes in hypoglycemic episodes were observed. At the beginning of the study the mean hypoglycemia prevalence in a month was 6.91±7.43 times, at the end of the study it was 6.75±6.31 (P>0.05). Although the mean values of HbA1c did not differ during the study period for both adherer and nonadherer groups, it differed between adherer and nonadherer groups within the study time (P<0.05). Daily total insulin doses increased and total energy consumption decreased after 6 months in both groups (P<0.05). Metabolic and anthropometric changes in the adherer and nonadherer groups during the study are given in Table 2.

Correlations between carbohydrate deviation score and some parameters are given in Table 3. According to Table 3, there was a positive correlation between HbA1c and insulin doses (P<0.05). On the other hand, BMI-standard deviation score positively correlated with insulin doses and LDL. Caregiver's eduction level (CEL) correlated negatively with HbA1c and insulin doses (P<0.05). There was a significant positive correlation between carbohydrate deviation score (CDS) and HbA1c.

Carbohydrate counting affects significant change in insulin dose and energy regardless of adherence. Adherence affects the significant decrease in HbA1c. HbA1c was positively correlated with CDS and negatively correlated with CEL.

Discussion

T1DM is a disease with high morbidity and mortality due to acute and chronic complications that cause growth retardation in children because of varying benefits from nutrients. β cell damage is very rapid in T1DM, especially at young ages. Carbohydrate counting is a meal planning method that allows better glycemic control due to the advantages of enabling individual freedom and continuation of social life [12]. It is very difficult to plan and adapt nutritional therapy in children and adolescents with special needs. In this study, the researchers aimed to increase adherence by increasing the frequency and awareness of nutritional education.

Little is known about the ability of children to count carbohydrates and whether a particular method for assessing carbohydrate quantity is better than others. This study investigated how accurately children and their caregivers estimated the carbohydrate content of a sample menu, and based on results, researchers divided the children into adherer or nonadherer groups. Demographic and metabolic profiles of adherer and nonadherer children were similar at the beginning of the study. Adherence to carbohydrate counting in children with T1DM revealed that approximately 51% adhered to this method. In a similar study conducted in Brazil, adherence to the prescribed diet was reported as 54.2% [19]. In a study that reviewed current findings on dietary adherence in youth with T1DM, rates of adherence to eating behaviors ranged from 21%–95% [5].

The metabolic control parameter (HbA1c) of nonadherer children increased by the end of the study when compared to baseline (P<0.05), however, no such difference was determined in other selected metabolic control parameters. The HbA1c levels were not significantly different after the intervention, although the adherer group had lower HbA1c levels within the study time. It is well known that even a modest reduction in HbA1c level decreases the risk of microvascular complications [2]. One study reported that although metabolic control (HbA1c) was good in patients with T1DM, only one-third of patients were able to maintain postprandial normoglycemia and 40% experienced frequent hyperglycemia. This drawback leads researchers to search for different methods. Conventional carbohydrate counting (focusing on carbohydrate content) is the most often used insulin carbohydrate matching method because of the proven effectiveness and safety of carbohydrate counting, and therefore there is limited literature on other methods (protein-fat counting, etc.) [20].

In the present study, the highest HbA1c levels were found in children whose caregiver was less educated and who failed to estimate the carbohydrate content of the sample menus. The caregiver's level of education is important since the caregiver carries out the calculations of the carbohydrate counting, especially in young children. Consistent with these results, the International Society for Pediatric and Adolescent Diabetes Clinical Practice Guidelines stated that family, especially the primary caregiver's education level, has an significant role in accomplishing carbohydrate counting [21].

A careful counting of carbohydrates will lead to the correct calculation of the required insulin dose, which in turn will lead to normalizing postprandial glycemia. This should only be achieved by accurate carbohydrate counting techniques. The results of studies conducted with adolescents are controversial in that carbohydrate counting affects the total daily insulin dose [22-25]. In this study insulin doses increased after training in both groups. One of the reasons for this increment could be the rapid growth of children and adolescents during the study time. Another reason may be incorrect calculation of the required insulin doses. Most adolescents consume more saturated fat and animal protein and less fiber regardless of T1DM. It is well known that it is carbohydrates that primarily affect glycemia. However, it should be remembered that high consumption of protein and fat is critical for deciding the correct insulin dose.

In both groups LDL and HDL cholesterol levels were among the normal values recommended by the American Academy of Pediatrics clinical report on lipid screening in children [18]. This may be because both groups received carbohydrate count training and therefore increased healthy nutrition mindfulness. Studies determining macronutrient intakes revealed higher than recommended intake of fat and saturated fat and lower intake of fruits, vegetables, and whole grains in youth with T1DM [5]. As dieticians increase their knowledge and skills about carbohydrate counting, the situation can be reversed.

The results of studies conducted with children and adolescents applying carbohydrate counting regarding changes in body weight are contradictory; while some studies have reported an increase [26-28], others have reported a decrease [10,29] and yet others have reported no change [1,24]. In the current study, similar BMI z-scores in adherer and nonadherer groups were found both before and after training.

Young children with T1DM may be at increased risk for dietary adherence due to aspects of food preferences, food refusal, emotional lability, and behavioral resistance [30]. Adolescence is also marked by feelings of ambivalence, impulsiveness, and mood swings; the struggle to separate from parents; and the need to be accepted by peers; therefore, dietary adherence is reduced in this period [9].

The dietician's responsibilities in T1DM education should be to explain the importance of a nutrition plan, the types of carbohydrates and their effects on glycemia, why refined carbohydrates should be avoided, the role of proteins and fats in glycemia, and the importance of fiber consumption for patients and their parents. Patients should understand the relationship between insulin, nutrition, and exercise after carbohydrate counting training. In addition, the dietician should emphasize what should be considered in meal planning, out-of-home nutrition, shopping, and food preparation and cooking, and provide information about sweeteners and dietary products. Nutritional education and lifestyle changes should be individualized in a patient-centered manner. Maintaining healthy eating behaviors, providing optimum glycemic control, reducing cardiovascular risk factors, preserving psychosocial health, and maintaining family dynamics should be the basic strategies of nutrition therapy [9,31]. Most importantly, these trainings should be repeated periodically, and quizzes should be administered to patients about their carbohydrate counting skills.

The follow-up duration for the current study was 6 months, which can be considered as a limitation of the study. The study found that adherence does not currently affect metabolic parameters outside of HbA1c, but is considered to be effective over a long period of time. The effect of dietary adherence on blood lipid parameters can be determined if longer follow-up is planned. Another limitation of the study was the number of patients. The researchers conducted a single-center study to standardize the biochemical parameters and recruited all study patients with T1DM who agreed to participate. An experimental study can be conducted in which all meal consumption and insulin usage of patients are observed because in this study food records were taken based on patients' statements.

In conclusion, nutritional therapy for diabetes is complicated, and numerous studies have shown problems with dietary adherence in patients with T1DM [5,6]. However, no study has specifically examined the dietary adherence of young children and adolescents with T1DM and attempted to relate this prospectively to children's metabolic control (glycemic control as well as serum lipid profiles and anthropometrics). Additional studies have determined the effects of diet adherence or carbohydrate counting on metabolic control, however, this study has important and valuable clinical significance for determining the effect of adherence to carbohydrate counting on metabolic control. Adherence training should be regularly provided by a diabetes dietitian in order to achieve good metabolic control in this young group.

Notes

Ethical statement

This study was approved by the Baskent University Institutional Review Board and Ethics Committee (Project number: KA13/218). Informed consent was obtained from the caregivers of all patients as well as themselves if the age (≥7) was appropriate.

Conflicts of interest

No potential conflict of interest relevant to this article was reported.

ACKNOWLEDGMENTS

This study was supported by the Baskent University Research Fund.

Table 1.

Demographic, clinical and laboratory characteristics of adherer and nonadherer groups at baseline

Variable	Adherer	Nonadherer	P-value
No. of patients	27 (50.9)	26 (49.1)
Sex
Female	14 (51.9)	16 (61.5)	0.353
Male	13 (48.1)	10 (38.5)
Age (yr)	10.64±4.40	10.53±3.71	0.927
Diabetes duration (mo)	24.59±5.71	28.81±3.52	0.102
BMI SDS	0.49±0.93	0.52±0.72	0.879
HbA1c (%)	7.85±1.53	8.23±1.53	0.404
Total insulin dose (U/kg/day)	0.75±0.25	0.83±0.25	0.352
TG (mg/dL)	85.88±37.83	104.17±73.75	0.280
TC (mg/dL)	175.48±31.99	168.69±27.75	0.438
HDL-C (mg/dL)	55.72±13.74	56.17±6.31	0.885
LDL-C (mg/dL)	102.68±25.33	93.47±23.02	0.196

Values are presented as number (%) or mean±standard deviation.

BMI, body mass index; SDS, standard deviation (z) score; LDL-C, low-density lipoprotein cholesterol; HDL-C, high-density lipoprotein cholesterol; TG, triglycerides; TC, total cholesterol.

Table 2.

Metabolic and anthropometric changes in the adherer and nonadherer groups during the study

Variable	Carbohydrate counters (n=53)
	Adherer (n=27)			Nonadherer (n=26)			Change from baseline
	Baseline	6th month	P-value^‡	Baseline	6th month	P-value^‡	Adherer	Nonadherer	P-value^†
HbA1c (%)	7.85±1.53	7.63±0.95	0.364	8.23±1.22	8.73±1.47	0.060	-0.22±1.05	0.50±1.36	0.043^*
LDL-C (mg/dL)	102.68±25.33	99.00±22.33	0.469	93.47±23.02	91.34±20.02	0.628	-3.00±24.50	-2.13±21.04	0.816
HDL-C (mg/dL)	55.72±13.74	53.64±11.25	0.340	56.17±6.31	54.78±11.17	0.487	-2.08±12.05	-1.39±8.72	0.319
Insulin dose (U/kg/d)	0.81±0.53	0.87±0.61	0.009^*	0.95±0.52	1.15±0.67	0.041^*	0.06±0.58	0.20±062	0.285
BMI-SDS	0.49±0.93	0.40±1.01	0.210	0.52±0.72	0.51±0.71	0.827	-0.49±0.95	-0.01±0.71	0.476
Height-SDS	0.31±0.89	0.32±0.61	0.845	0.38±0.67	0.39±0.51	0.735	0.01±0.78	0.01±0.63	0.375
Weight-SDS	0.21±0.90	0.18±0.75	0.310	0.43±0.87	0.42±0.85	0.875	-0.03±0.83	-0.01±0.87	0.957
Energy (kcal/kg)	54.63±26.38	45.33±21.02	0.004^*	52.80±19.38	45.62±14.55	0.001^*	-9.30±25.05	-7.18±16.09	0.555

Values are mean±SD.

HbA1c, Hemoglobin A1c; LDL-C, low-density lipoprotein cholesterol; HDL-C, high-density lipoprotein cholesterol; BMI, body mass index; SDS, standard deviation (z) score.

^* P<0.05.

^† Comparison of mean differences between adherer and nonadherer group within study time.

^‡ Comparison of baseline and 6th month values within in each group.

Table 3.

Correlations between carbohydrate deviation score and education level of caregiver, energy intake, BMI-SDS, some metabolic control parameters

Variable	LDL	HDL	Insulin doses	BMI-SDS	Energy	CEL	CDS
HbA1c	-0.118 (0.416)	0.094 (0.517)	0.084 (0.045)^*	-0.007 (0.962)	0.087 (0.557)	-0.370 (0.010)^*	0.427 (0.002)^*
LDL		0.295 (0.134)	0.027 (0.706)	0.294 (0.041)^*	0.064 (0.667)	0.061 (0.693)	-0.145 (0.327)
HDL			0.059 (0.602)	0.045 (0.757)	-0.122 (0.410)	0.097 (0.525)	0.092 (0.534)
Insulin doses				0.560 (0.004)^*	0.240 (0.480)	-0.450 (0.023)^*	0.068 (0.340)
BMI-SDS					0.037 (0.803)	0.001 (0.997)	0.020 (0.895)
Energy						0.041 (0.790)	0.086 (0.562)
CEL							0.267 (0.080)

Values are Pearson correlation coefficient (P-value).

BMI, body mass index; SDS, standard deviation (z) score; LDL, low-density lipoprotein; HDL, high-density lipoprotein; HbA1c, hemoglobin A1c; CEL, caregiver's education level; CDS, carbohydrate deviation score.

Difference between patient’s and dietitian’s carbohydrate estimation.

^* P<0.05.

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