As research on the unique effects of space environment, especially microgravity and cosmic radiation, on the cardiovascular system is being conducted, research on the development of cardiovascular therapeutics using the space environment is attracting attention. This review comprehensively analyzes the current status and prospects of cardiovascular therapeutics development research utilizing space environment.Microgravity environment has been shown to have a positive effect on the proliferation and differentiation of cardiac progenitor cells and induced pluripotent stem cell-derived cardio myocytes. Cardiac tissue culture and organoid technology have enabled more effective drug screening and disease modeling than on the ground, and changes in gene expression such as Aquaporin-4 have been found to play an important role in cardiac function. Cosmic radiation can cause myocardial remodeling, fibrosis, and vascular endothelial dysfunction, and the underlying mechanisms of these effects include increased oxidative stress, promotion of inflammatory responses, deoxyribo nucleic acid damage, and cell death. Currently, the development of drugs that can prevent or treat cardiovascular damage caused by the space environment is in the early stages, and future research is expected to focus on developing personalized treatments and exploring the potential applications of space medicine research results to terrestrial medicine.

OBJECTIVES: Low handgrip strength (HGS) in children and adolescents might be associated with the risk of metabolic syndrome (MetS) and insulin resistance. This study prospectively evaluated the association between HGS in childhood and MetS in adolescence. METHODS: Based on data from the Ewha Birth and Growth Study, this study analyzed HGS at ages 7 to 9 and metabolic indices at ages 13 to 15. In total, 219 participants were analyzed. The risk of MetS was evaluated using the continuous metabolic syndrome score (cMetS), and insulin resistance was assessed using fasting blood insulin and homeostasis model assessment of insulin resistance (HOMA-IR). Relative HGS in childhood was determined by dividing HGS by body weight and categorized as sex-specific quartiles. RESULTS: This study found an inverse association between relative HGS levels in childhood and MetS and insulin resistance in adolescence. For each 1-group increase in relative HGS quartiles, cMetS (standarard [Std] β=-0.64, p<0.01), HOMA-IR (Std β=-0.21, p<0.01), and fasting blood insulin (Std β=-0.21, p<0.01) all decreased on average. These associations remained significant even after adjusting for confounding factors. CONCLUSIONS Our study showed a prospective association between HGS in childhood and the risk of MetS and insulin resistance in adolescence. It provides significant epidemiological evidence, emphasizing the importance of efforts to increase muscle strength from a young age to mitigate the risk of MetS and insulin resistance in adolescence.

As research on the unique effects of space environment, especially microgravity and cosmic radiation, on the cardiovascular system is being conducted, research on the development of cardiovascular therapeutics using the space environment is attracting attention. This review comprehensively analyzes the current status and prospects of cardiovascular therapeutics development research utilizing space environment.Microgravity environment has been shown to have a positive effect on the proliferation and differentiation of cardiac progenitor cells and induced pluripotent stem cell-derived cardio myocytes. Cardiac tissue culture and organoid technology have enabled more effective drug screening and disease modeling than on the ground, and changes in gene expression such as Aquaporin-4 have been found to play an important role in cardiac function. Cosmic radiation can cause myocardial remodeling, fibrosis, and vascular endothelial dysfunction, and the underlying mechanisms of these effects include increased oxidative stress, promotion of inflammatory responses, deoxyribo nucleic acid damage, and cell death. Currently, the development of drugs that can prevent or treat cardiovascular damage caused by the space environment is in the early stages, and future research is expected to focus on developing personalized treatments and exploring the potential applications of space medicine research results to terrestrial medicine.

As research on the unique effects of space environment, especially microgravity and cosmic radiation, on the cardiovascular system is being conducted, research on the development of cardiovascular therapeutics using the space environment is attracting attention. This review comprehensively analyzes the current status and prospects of cardiovascular therapeutics development research utilizing space environment.Microgravity environment has been shown to have a positive effect on the proliferation and differentiation of cardiac progenitor cells and induced pluripotent stem cell-derived cardio myocytes. Cardiac tissue culture and organoid technology have enabled more effective drug screening and disease modeling than on the ground, and changes in gene expression such as Aquaporin-4 have been found to play an important role in cardiac function. Cosmic radiation can cause myocardial remodeling, fibrosis, and vascular endothelial dysfunction, and the underlying mechanisms of these effects include increased oxidative stress, promotion of inflammatory responses, deoxyribo nucleic acid damage, and cell death. Currently, the development of drugs that can prevent or treat cardiovascular damage caused by the space environment is in the early stages, and future research is expected to focus on developing personalized treatments and exploring the potential applications of space medicine research results to terrestrial medicine.

OBJECTIVES: Low handgrip strength (HGS) in children and adolescents might be associated with the risk of metabolic syndrome (MetS) and insulin resistance. This study prospectively evaluated the association between HGS in childhood and MetS in adolescence. METHODS: Based on data from the Ewha Birth and Growth Study, this study analyzed HGS at ages 7 to 9 and metabolic indices at ages 13 to 15. In total, 219 participants were analyzed. The risk of MetS was evaluated using the continuous metabolic syndrome score (cMetS), and insulin resistance was assessed using fasting blood insulin and homeostasis model assessment of insulin resistance (HOMA-IR). Relative HGS in childhood was determined by dividing HGS by body weight and categorized as sex-specific quartiles. RESULTS: This study found an inverse association between relative HGS levels in childhood and MetS and insulin resistance in adolescence. For each 1-group increase in relative HGS quartiles, cMetS (standarard [Std] β=-0.64, p<0.01), HOMA-IR (Std β=-0.21, p<0.01), and fasting blood insulin (Std β=-0.21, p<0.01) all decreased on average. These associations remained significant even after adjusting for confounding factors. CONCLUSIONS Our study showed a prospective association between HGS in childhood and the risk of MetS and insulin resistance in adolescence. It provides significant epidemiological evidence, emphasizing the importance of efforts to increase muscle strength from a young age to mitigate the risk of MetS and insulin resistance in adolescence.

OBJECTIVES: Low handgrip strength (HGS) in children and adolescents might be associated with the risk of metabolic syndrome (MetS) and insulin resistance. This study prospectively evaluated the association between HGS in childhood and MetS in adolescence. METHODS: Based on data from the Ewha Birth and Growth Study, this study analyzed HGS at ages 7 to 9 and metabolic indices at ages 13 to 15. In total, 219 participants were analyzed. The risk of MetS was evaluated using the continuous metabolic syndrome score (cMetS), and insulin resistance was assessed using fasting blood insulin and homeostasis model assessment of insulin resistance (HOMA-IR). Relative HGS in childhood was determined by dividing HGS by body weight and categorized as sex-specific quartiles. RESULTS: This study found an inverse association between relative HGS levels in childhood and MetS and insulin resistance in adolescence. For each 1-group increase in relative HGS quartiles, cMetS (standarard [Std] β=-0.64, p<0.01), HOMA-IR (Std β=-0.21, p<0.01), and fasting blood insulin (Std β=-0.21, p<0.01) all decreased on average. These associations remained significant even after adjusting for confounding factors. CONCLUSIONS Our study showed a prospective association between HGS in childhood and the risk of MetS and insulin resistance in adolescence. It provides significant epidemiological evidence, emphasizing the importance of efforts to increase muscle strength from a young age to mitigate the risk of MetS and insulin resistance in adolescence.

As research on the unique effects of space environment, especially microgravity and cosmic radiation, on the cardiovascular system is being conducted, research on the development of cardiovascular therapeutics using the space environment is attracting attention. This review comprehensively analyzes the current status and prospects of cardiovascular therapeutics development research utilizing space environment.Microgravity environment has been shown to have a positive effect on the proliferation and differentiation of cardiac progenitor cells and induced pluripotent stem cell-derived cardio myocytes. Cardiac tissue culture and organoid technology have enabled more effective drug screening and disease modeling than on the ground, and changes in gene expression such as Aquaporin-4 have been found to play an important role in cardiac function. Cosmic radiation can cause myocardial remodeling, fibrosis, and vascular endothelial dysfunction, and the underlying mechanisms of these effects include increased oxidative stress, promotion of inflammatory responses, deoxyribo nucleic acid damage, and cell death. Currently, the development of drugs that can prevent or treat cardiovascular damage caused by the space environment is in the early stages, and future research is expected to focus on developing personalized treatments and exploring the potential applications of space medicine research results to terrestrial medicine.

OBJECTIVES: Low handgrip strength (HGS) in children and adolescents might be associated with the risk of metabolic syndrome (MetS) and insulin resistance. This study prospectively evaluated the association between HGS in childhood and MetS in adolescence. METHODS: Based on data from the Ewha Birth and Growth Study, this study analyzed HGS at ages 7 to 9 and metabolic indices at ages 13 to 15. In total, 219 participants were analyzed. The risk of MetS was evaluated using the continuous metabolic syndrome score (cMetS), and insulin resistance was assessed using fasting blood insulin and homeostasis model assessment of insulin resistance (HOMA-IR). Relative HGS in childhood was determined by dividing HGS by body weight and categorized as sex-specific quartiles. RESULTS: This study found an inverse association between relative HGS levels in childhood and MetS and insulin resistance in adolescence. For each 1-group increase in relative HGS quartiles, cMetS (standarard [Std] β=-0.64, p<0.01), HOMA-IR (Std β=-0.21, p<0.01), and fasting blood insulin (Std β=-0.21, p<0.01) all decreased on average. These associations remained significant even after adjusting for confounding factors. CONCLUSIONS Our study showed a prospective association between HGS in childhood and the risk of MetS and insulin resistance in adolescence. It provides significant epidemiological evidence, emphasizing the importance of efforts to increase muscle strength from a young age to mitigate the risk of MetS and insulin resistance in adolescence.

As research on the unique effects of space environment, especially microgravity and cosmic radiation, on the cardiovascular system is being conducted, research on the development of cardiovascular therapeutics using the space environment is attracting attention. This review comprehensively analyzes the current status and prospects of cardiovascular therapeutics development research utilizing space environment.Microgravity environment has been shown to have a positive effect on the proliferation and differentiation of cardiac progenitor cells and induced pluripotent stem cell-derived cardio myocytes. Cardiac tissue culture and organoid technology have enabled more effective drug screening and disease modeling than on the ground, and changes in gene expression such as Aquaporin-4 have been found to play an important role in cardiac function. Cosmic radiation can cause myocardial remodeling, fibrosis, and vascular endothelial dysfunction, and the underlying mechanisms of these effects include increased oxidative stress, promotion of inflammatory responses, deoxyribo nucleic acid damage, and cell death. Currently, the development of drugs that can prevent or treat cardiovascular damage caused by the space environment is in the early stages, and future research is expected to focus on developing personalized treatments and exploring the potential applications of space medicine research results to terrestrial medicine.

The global prevalence of childhood and adolescent obesity, exacerbated by the coronavirus disease 2019 pandemic, affects school-aged children and preschoolers. Early-onset obesity, which carries a high risk of metabolic complications, may contribute to a lower age at the onset of cardiovascular disease. As metabolic diseases such as diabetes, dyslipidemia, and nonalcoholic fatty liver disease observed in adulthood are increasingly recognized in the pediatric population, there is an emphasis on moving disease susceptibility assessments from adulthood to childhood to enable early detection. However, consensus is lacking regarding the definition of metabolic diseases in children. In response, various indicators such as the pediatric simple metabolic syndrome score, continuous metabolic syndrome score, single-point insulin sensitivity estimator, and fatty liver index have been proposed in several studies. These indicators may aid the early detection of metabolic complications associated with pediatric obesity, although further validation studies are needed. Obesity assessments are shifting in perspective from visual obesity to metabolic health and body composition considerations to fill the gap in health impact assessments. Sarcopenic obesity, defined as the muscle- to-fat ratio, has been proposed in pediatric populations and is associated with metabolic health in children and adolescents. The National Health Screening Program for Children in Korea has expanded but still faces limitations in laboratory testing. These tests facilitate timely intervention by identifying groups at a high risk of metabolic complications. Early detection and intervention through comprehensive health screening are critical for mitigating long-term complications of childhood obesity.