Obesity, Health Issues, and Cardiovascular Disease

 

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This issue is dedicated to obesity, health issues, and cardiovascular disease.

Chapter 1, on epidemiology of obesity, provides proper information on classification of obesity and associated compromised health consequences. The prevalence of adult and childhood obesity in the world is highest in countries with a Western food pattern and lifestyle, and the lowest in poor, developing countries. In Western countries, obesity seems to be more common in groups of the population with relatively low socioeconomic status and lifestyle.

In chapter 2, Considine reviews human leptin as an adipocyte hormone with weight regulatory and endocrine (metabolic) functions. Mutations in the leptin or leptin receptor genes results in no leptin, which is associated with hyperphagia, morbid obesity, and cold intolerance. Leptin promotes weight loss, lowers insulin and glucose, and inhibits food intake (satiety control). Hexosamine biosynthesis is the link between glucose metabolism and leptin production. Leptin levels are higher in women than in men, mainly because estradiol stimulates and testosterone inhibits leptin production in human abdominal adipose tissue. Obesity is associated with increased leptin levels, increased leptin gene expression in adipocytes, and resistance to weight-reducing activity of leptin (leptin resistance). Weight loss (by relative starvation) results in decreased adipose mass and decreased leptin levels. Leptin has several other metabolic effects: it enhances platelet activation/aggregation, increases nitro-oxide (NO) synthesis by endothelial cells, increases endothelin, stimulates angiogenesis and hematopoiesis, and influences insulin action in target tissues.

In chapter 3, Douketis and Sharma shed some light on the relation between obesity and cardiovascular disease (CVD). A body mass index (BMI) above 30 has emerged as an important independent but modifiable risk factor for CVD. People with an abdominal (or central) pattern of obesity are at higher risk of developing the metabolic syndrome. Above the age of 65 years, there is no significant association between BMI and CVD, but an increased waist-to-hip ratio (WHR), indicative of abdominal obesity, has a threefold relative risk for CVD. Mechanisms for the association of obesity and CVD are the metabolic syndrome-related hypertension, hyperlipidemia, insulin resistance, diabetes, and components produced or expressed by adipocytes including leptin, adiponectin, TNFα, and components of the renin-angiotensin system.

The relation between obesity and stroke is weak, but between central obesity (increased WHR) and stroke the correlation is much stronger. In the NHANES I study, the population attributable risk of developing heart failure as a result of obesity was 8%, diabetes 3%, hypertension 10%, and coronary artery disease 62%. An association between peripheral artery disease and BMI is unclear. Increased BMI is associated with an increased risk on venous thrombo-embolic complications, in particular in those who had a waist circumference above 95 cm.

Clinically important weight loss of 5-10% of baseline weight or 5-10 kg is associated with an improvement of lipid levels, glycemic control, hypertension control, and reduced risk of diabetes and CVD. Prospective studies in obese patients demonstrate that pharmacological weight-reduction therapy combined with dietary and lifestyle interventions is associated with a 5-10-kg weight loss over a few years. A large prospective study on the effect of surgical weight-loss intervention versus usual care on long-term morbidity and mortality is ongoing.

In Chapter 4, the role of dietary fat in obesity is elucidated by Astrup. A 6% point reduction in dietary fat in conjunction with increased intake of fish, fruit, vegetables, and nuts is associated with weight loss of ∼4 kg over 1 year and a reduction of cardiovascular events and mortality of 40%. Dietary intervention should focus on a combination of fat reduction and an increase of whole-grain and fiber-rich food and the replacement of sugar-sweetened soft drinks and fruit juices by mineral water. Monounsaturated fats (MUFAs) and adiposity are positively related, though polyunsaturated fat is weakly related, to obesity. Body weight and insulin resistance are increased in a high-MUFA diet compared with in fat-reduced diets. A diet rich in safflower oil (PUFA) accumulates less body fat than a diet rich in beef tallow (unsaturated fat), probably because of a higher diet-induced thermogenesis, elevated fat oxidation, and higher sympathic activity. A Mediterranean, fat-reduced diet reduces mortality by 45-60% in patients with CVD.

Mertens and colleagues review in chapter 5 the role of plasminogen activator inhibitor (PAI-1) on obesity and visceral fat. PAI-1 is increased in obese subjects, correlating with BMI and with measures of body fat distribution such as waist circumference and WHR (metabolic syndrome). There is a significant relationship between visceral fat and PAI-1, which seems to be independent from insulin, insulin sensitivity, triglycerides, total fat mass, and age. As adipose issue produces PAI-1 and is able to secrete PAI-1 it has been argued that PAI-1 secreted by visceral adipose tissue contributes significantly to higher plasma PAI-1 levels in obesity, in particular when associated with the metabolic syndrome. Recent data show that plasma PAI-1 levels are more closely related to fat accumulation and PAI-1 expression in liver than in adipose tissue, indicating that a fatty liver is an important site of PAI-1 production in insulin resistance.

In chapter 6, Shankar and Steinberg review studies demonstrating that in vivo measurements of endothelial function (flow-mediated dilatation: FMD, NO production) is impaired in obese subjects, but its mechanism is very complex and remains elusive. The cause of impaired NO production in obesity is not understood. Endothelial activation markers ICAM-1, VCAM-1, P-selectin, and cytokines TNFα and IL-6 are elevated in obesity-and in particular abdominal obesity-or when associated with the metabolic syndrome or insulin resistance. Reduction in body weight is associated with improvement of endothelial function and reduction of endothelial activation markers, as well as improvement of many metabolic markers of glucose and lipid metabolism discussed in previous chapters on obesity, health issues, and cardiovascular disease.

In chapter 7, Markel reports on the origin, natural history, and recanalization of deep vein thrombosis (DVT) of the legs. The main complications of DVT are pulmonary embolism (PE) and the postthrombotic syndrome (PTS). Untreated DVT is associated with PE in 20-67% of cases and has a mortality rate of 11-23%. When treated PE decreases to 5%, mortality to far less than 1%, and two-thirds of the cases develop signs and symptoms secondary to valvular incompetence after follow-up of a few to several years. Recanalization of occlusive DVT is a slow process and occurs in 67% after 6 months, 83% after 1 year, and 100% after 3 years. Normalization of flow is a slower process-50% of post-DVT leg veins still have partial obstruction after 3 years. PTS is caused by incompetent valves of the deep and superficial leg veins. The incidence of venous reflux is about 70% after 1 year. The incidence of PTS increases up to 30-50% after a few to several years follow-up. Both reflux and partial obstruction of both superficial and deep veins contribute to the severity of PTS.

 Prof. Dr.
Luc F Van Gaal

Department of Diabetology, Metabolism and Clinical Nutrition, Faculty of Medicine

Antwerp University Hospital, Wilrijkstraat 10

B-2650 Edegem, Antwerp, Belgium