Estrategias para mitigar hipoglucemias y variabilidad glucémica / Strategies to mitigate hypoglycemia and glycemic variability

La última década se ha destacado por los importantes avances en el desarrollo de nuevas tecnologías para pacientes que viven con diabetes mellitus (DM). Las innovaciones han estado orientadas principalmente a: mejorar la calidad de vida, reducir el impacto que genera la ocurrencia de hipoglucemias y reducir la carga de la enfermedad colaborando en la toma diaria de decisiones1. El monitoreo continuo de glucosa (MCG) es una herramienta que ha experimentado un importante avance al aportar información dinámica del estado metabólico en los pacientes y permitir la toma de decisiones, demostrado por un control metabólico estable, menores excursiones glucémicas, y una reducción significativa en la aparición y gravedad de las hipoglucemias2-5. Las presentes recomendaciones tienen como objetivo brindar herramientas rápidas para la interpretación de datos metabólicos y la consiguiente toma de decisiones terapéuticas. A tal fin se realizó una exhaustiva revisión de las principales guías y recomendaciones vigentes; posteriormente, el Grupo de Trabajo adaptó esa información según una serie de preguntas con criterio clínico práctico. El avance de los MCG es innegable, no solo en el desarrollo tecnológico, sino que se han convertido en una herramienta educativa para las personas con DM, su entorno y el equipo de salud al posibilitar un ajuste dinámico del tratamiento, prevenir complicaciones agudas y mejorar la calidad de vida. En esta ecuación enfatizamos la importancia de la educación diabetológica continua de la persona con DM y su entorno, participando activamente en la toma de decisiones para, de esta manera, cumplir con los objetivos propuestos: mejorar la calidad de vida, reducir la carga de la enfermedad y disminuir las excursiones glucémicas agudas.

The last decade has been highlighted by important advances in the development of new technologies for patients living with diabetes. The innovations have been oriented above all to improve the quality of life, reduce the impact generated by the occurrence of hypoglycemia and reduce the burden of the disease by collaborating in daily decision-making1. Continuous glucose monitoring (CGM) is a tool that has undergone significant progress, providing dynamic information on the metabolic status of patients, allowing decision making, demonstrated by stable metabolic control, lower glycemic excursions and a significant reduction in the occurrence and severity of hypoglycemia2-5. The purpose of these recommendations, developed by members of the Innovation Committee of the Argentine Society of Diabetes, is to provide rapid tools for the interpretation of metabolic data and the subsequent therapeutic decisionmaking. To this end, an exhaustive review of the main current guidelines and recommendations has been carried out, later the working group adapted this information according to a series of questions with practical clinical criteria. The progress of CGMs is undeniable, not only in technological development, but it has become an educational tool for people with diabetes, their environment, and the health team, offering the possibility of a dynamic adjustment of treatment, prevention of acute complications and improving quality of life. In this equation, we emphasize the importance of continuous diabetes education for the person with diabetes and their environment, actively participating in decision-making, and in this way, meeting the proposed objectives: improving quality of life, reducing the burden of disease, and decreasing acute glycemic excursions.

Estrategias para mitigar hipoglucemias y variabilidad glucémica / Strategies to mitigate hypoglycemia and glycemic variability

Resumen La última década se ha destacado por los importantes avances en el desarrollo de nuevas tecnologías para pacientes que viven con diabetes mellitus (DM). Las innovaciones han estado orientadas principalmente a: mejorar la calidad de vida, reducir el impacto que genera la ocurrencia de hipoglucemias y reducir la carga de la enfermedad colaborando en la toma diaria de decisiones1. El monitoreo continuo de glucosa (MCG) es una herramienta que ha experimentado un importante avance al aportar información dinámica del estado metabólico en los pacientes y permitir la toma de decisiones, demostrado por un control metabólico estable, menores excursiones glucémicas, y una reducción significativa en la aparición y gravedad de las hipoglucemias2-5. Las presentes recomendaciones tienen como objetivo brindar herramientas rápidas para la interpretación de datos metabólicos y la consiguiente toma de decisiones terapéuticas. A tal fin se realizó una exhaustiva revisión de las principales guías y recomendaciones vigentes; posteriormente, el Grupo de Trabajo adaptó esa información según una serie de preguntas con criterio clínico práctico. El avance de los MCG es innegable, no solo en el desarrollo tecnológico, sino que se han convertido en una herramienta educativa para las personas con DM, su entorno y el equipo de salud al posibilitar un ajuste dinámico del tratamiento, prevenir complicaciones agudas y mejorar la calidad de vida. En esta ecuación enfatizamos la importancia de la educación diabetológica continua de la persona con DM y su entorno, participando activamente en la toma de decisiones para, de esta manera, cumplir con los objetivos propuestos: mejorar la calidad de vida, reducir la carga de la enfermedad y disminuir las excursiones glucémicas agudas.

Abstract The last decade has been highlighted by important advances in the development of new technologies for patients living with diabetes. The innovations have been oriented above all to improve the quality of life, reduce the impact generated by the occurrence of hypoglycemia and reduce the burden of the disease by collaborating in daily decision-making1. Continuous glucose monitoring (CGM) is a tool that has undergone significant progress, providing dynamic information on the metabolic status of patients, allowing decision making, demonstrated by stable metabolic control, lower glycemic excursions and a significant reduction in the occurrence and severity of hypoglycemia2-5. The purpose of these recommendations, developed by members of the Innovation Committee of the Argentine Society of Diabetes, is to provide rapid tools for the interpretation of metabolic data and the subsequent therapeutic decisionmaking. To this end, an exhaustive review of the main current guidelines and recommendations has been carried out, later the working group adapted this information according to a series of questions with practical clinical criteria. The progress of CGMs is undeniable, not only in technological development, but it has become an educational tool for people with diabetes, their environment, and the health team, offering the possibility of a dynamic adjustment of treatment, prevention of acute complications and improving quality of life. In this equation, we emphasize the importance of continuous diabetes education for the person with diabetes and their environment, actively participating in decision-making, and in this way, meeting the proposed objectives: improving quality of life, reducing the burden of disease, and decreasing acute glycemic excursions.

Effects of Pubertal Status and Inflammation on the Use of Ferritin to Define Iron Deficiency in Children With Overweight or Obesity.

BACKGROUND AND AIMS: A worldwide increase in childhood overweight (OW) and obesity (OB) has been reported. OB is an inflammatory state which affects iron metabolism and the sensibility of the tests to detect iron deficiency (ID). Our aim was to evaluate the adequacy of current ferritin cut-offs to define ID in children with OW/OB. METHODS: This cross-sectional study included 152 children (54% girls) aged (median [Q1-Q3]) 11 (8-13) years with OW/OB. Complete blood count and iron metabolism were evaluated. Low ferritin, transferrin saturation (TSat), and anemia were defined by age- and sex-specific cut-offs recommended by National Guidelines. Iron intake was assessed in a subgroup (n = 80) by a 24-hour dietary recall. Analyses were made according to pubertal development and ferritin tertiles. RESULTS: The overall prevalence of low ferritin, TSat, and anemia was 2.6%, 23.8%, and 5.2%, respectively. Among pre-pubertal children (n = 87), the frequency of low TSat rose across ferritin tertiles (P < .05), whereas it decreased among pubertal children (n = 65; P < .005). Cases of anemia among pre-pubertal children were found in the highest ferritin tertile, whereas 4/6 anemia cases in pubertal children were found in the lowest ferritin tertile (<39 µg/L). Pubertal children within the lowest ferritin tertile + low TSat (n = 11) showed lower hemoglobin (-9%; P < .005) and hematocrit (-8%, P < .01) than those in the same tertile + normal TSat (n = 16). The overall prevalence of children with ferritin < 39 µg/L + low TSat was 9.2%. CONCLUSIONS: Higher ferritin cut-off values are required to define ID in children with OW/OB. Such cut-off remains to be validated in larger, multi-ethnic cohorts of children with OW/OB.