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عن الكتاب : Next Section Abstract Osteoporosis is a debilitating disease that affects many older people. Fragility fractures are the hallmark of osteoporosis. Although nutrition is only 1 of many factors that influence bone mass and fragility fractures, there is an urgent need to develop and implement nutritional approaches and policies for the prevention and treatment of osteoporosis that could, with time, offer a foundation for population-based preventive strategies. However, to develop efficient and precocious strategies in the prevention of osteoporosis, it is important to determine which modifiable factors, especially nutritional factors, are able to improve bone health throughout life. There are potentially numerous nutrients and dietary components that can influence bone health, and these range from the macronutrients to micronutrients as well as bioactive food ingredients. The evidence-base to support the role of nutrients and food components in bone health ranges from very firm to scant, depending on the nutrient/component. This article initially overviews osteoporosis, including its definition, etiology, and incidence, and then provides some information on possible dietary strategies for optimizing bone health and preventing osteoporosis. The potential benefits of calcium, vitamin D, vitamin K1, phytoestrogens, and nondigestible oligosaccharides are briefly discussed, with particular emphasis on the evidence base for their benefits to bone. It also briefly considers some of the recent findings that highlight the importance of some dietary factors for bone health in childhood and adolescence. Previous Section Next Section Introduction Osteoporosis is a global health problem that will take on increasing significance as people live longer and the world's population continues to increase in number (1). Thus, prevention of osteoporosis and its complications is an essential socioeconomic priority. There is an urgent need to develop and implement nutritional approaches (including functional foods) and policies for the prevention and treatment of osteoporosis. This article first briefly defines the principal disease of bone mass (i.e., osteoporosis) and considers its epidemiology and risk factors. It then focuses on the importance of certain dietary factors (in particular those that could be potential functional food ingredients for the prevention of osteoporosis) in bone health. Osteoporosis: definition and epidemiology Osteoporosis is defined as a systemic skeletal disease characterized by low bone mass and microarchitectural deterioration of bone tissue, with a consequent increase in bone fragility and susceptibility to fracture (2). For the purposes of clinical diagnosis, a working party of the World Health Organization has redefined osteoporosis according to bone mass, at least for women. Their diagnostic criteria for osteoporosis, based on bone mineral content (BMC)3 or bone mineral density (BMD), include: normal, within 1 SD of the young adult reference mean for the population; osteopenia, between −1 and −2.5 SD of the young adult mean; osteoporosis more than −2.5 SD below the young adult mean; and established osteoporosis as the same mass definition but associated with a fragility fracture (3). Fragility fractures are the hallmark of osteoporosis and are particularly common in the spine, hip, and distal forearm, although they can occur throughout the skeleton. Osteoporotic fractures constitute a major public health problem. Currently, in the United States alone, 10 million individuals already have osteoporosis, and a further 34 million more have low bone mass, placing them at increased risk from this disorder (4). Moreover, 1 in 8 European Union (EU) citizens over the age of 50 y will fracture their spine this year (1). The estimated remaining lifetime risk of fractures in Caucasian women at age 50 y, based on incidence rates in North America, is 17.5%, 15.6%, and 16% for hip, spine, and forearm, respectively; the remaining lifetime risk for any fragility fracture approaches 40% in women and 13% in men (5). The incidence of vertebral and hip fractures increases exponentially with advancing age (6). This is of particular concern because it is projected that the number of elderly (80 y and older, in whom the incidence of osteoporotic fracture is greatest) in the EU population will grow from 8.9 million women and 4.5 million men in 1995, to 26.4 million women and 17.4 million men in 2050 (1). Similar demographic changes have been forecast for the U.S. population (7). Because of the increase in incidence rates of osteoporotic fractures with age, these demographic changes and increasing life expectancy will have a huge impact on the number of fractures that can be expected to occur. For example, the number of hip fractures occurring each year in the EU alone is estimated to rise from current figures of 414,000 to 972,000 by 2050, representing an increase of 135% (1). Hip fracture patients have an overall mortality of 15–30% (8), the majority of excess deaths occurring within the first 6 mo after the fracture. From an economic perspective, the expenses of hospital care and rehabilitation associated with osteoporotic fractures are a considerable fiscal drain for the health care system, exceeding those of other highly prevalent pathologies of the elderly, such as myocardial infarction (9). Osteoporosis costs national treasuries over €3500 million annually in hospital health care alone (1). Risk factors for osteoporosis Low bone mineral mass is the main factor underlying osteoporotic fracture (10). Bone mass in later life depends on the peak bone mass achieved during growth and the rate of subsequent age-related bone loss. Development of maximal bone mass during growth and reduction of loss of bone later in life are the 2 main strategies of preventing osteoporosis (11). Consequently, any factor that influences the development of peak bone mass or the loss of bone in middle-age will affect later fracture risk. Several factors are thought to influence bone mass. These can be broadly grouped into factors that cannot be modified, such as gender, age, body (frame) size, genetics and ethnicity, and those factors that can be modified, such as hormonal status (especially sex and calciotropic hormone status), lifestyle factors including physical activity levels, smoking and alcohol consumption patterns, and diet (including functional foods). The interaction of these genetic, hormonal, environmental and nutritional factors influences both the development of bone to peak bone mass at maturity and its subsequent loss. The remainder of this article will focus on a selected number of dietary components/nutrients that may influence bone health. Diet, nutrition and bone health Many of the nutrients and food components we consume as part of a Westernized diet can potentially have a positive or negative impact on bone health (see Table 1). They may influence bone by various mechanisms, including alteration of bone structure, the rate of bone metabolism, the endocrine and/or paracrine system, and homeostasis of calcium and possibly of other bone-active mineral elements (12). These dietary factors range from inorganic minerals (e.g., calcium, magnesium, phosphorus, sodium, potassium, and various trace elements) and vitamins (vitamins A, D, E, K, C, and certain B vitamins), to macronutrients, such as protein and fatty acids. In addition, the relative proportions of these dietary factors derived from different types of diets (vegetarian vs. omnivorous) may also affect bone health and thus osteoporosis risk. Furthermore, in recent years a number of bioactive food components have been proposed as being beneficial for bone health. A review of all of these dietary factors is beyond the scope of the present article. .
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نبذة عن كتاب Diet Nutrition and Bone Health1 2

كتاب Diet Nutrition and Bone Health1 2

Next Section Abstract Osteoporosis is a debilitating disease that affects many older people. Fragility fractures are the hallmark of osteoporosis. Although nutrition is only 1 of many factors that influence bone mass and fragility fractures, there is an urgent need to develop and implement nutritional approaches and policies for the prevention and treatment of osteoporosis that could, with time, offer a foundation for population-based preventive strategies. However, to develop efficient and precocious strategies in the prevention of osteoporosis, it is important to determine which modifiable factors, especially nutritional factors, are able to improve bone health throughout life. There are potentially numerous nutrients and dietary components that can influence bone health, and these range from the macronutrients to micronutrients as well as bioactive food ingredients. The evidence-base to support the role of nutrients and food components in bone health ranges from very firm to scant, depending on the nutrient/component. This article initially overviews osteoporosis, including its definition, etiology, and incidence, and then provides some information on possible dietary strategies for optimizing bone health and preventing osteoporosis. The potential benefits of calcium, vitamin D, vitamin K1, phytoestrogens, and nondigestible oligosaccharides are briefly discussed, with particular emphasis on the evidence base for their benefits to bone. It also briefly considers some of the recent findings that highlight the importance of some dietary factors for bone health in childhood and adolescence. Previous Section Next Section Introduction Osteoporosis is a global health problem that will take on increasing significance as people live longer and the world's population continues to increase in number (1). Thus, prevention of osteoporosis and its complications is an essential socioeconomic priority. There is an urgent need to develop and implement nutritional approaches (including functional foods) and policies for the prevention and treatment of osteoporosis. This article first briefly defines the principal disease of bone mass (i.e., osteoporosis) and considers its epidemiology and risk factors. It then focuses on the importance of certain dietary factors (in particular those that could be potential functional food ingredients for the prevention of osteoporosis) in bone health. Osteoporosis: definition and epidemiology Osteoporosis is defined as a systemic skeletal disease characterized by low bone mass and microarchitectural deterioration of bone tissue, with a consequent increase in bone fragility and susceptibility to fracture (2). For the purposes of clinical diagnosis, a working party of the World Health Organization has redefined osteoporosis according to bone mass, at least for women. Their diagnostic criteria for osteoporosis, based on bone mineral content (BMC)3 or bone mineral density (BMD), include: normal, within 1 SD of the young adult reference mean for the population; osteopenia, between −1 and −2.5 SD of the young adult mean; osteoporosis more than −2.5 SD below the young adult mean; and established osteoporosis as the same mass definition but associated with a fragility fracture (3). Fragility fractures are the hallmark of osteoporosis and are particularly common in the spine, hip, and distal forearm, although they can occur throughout the skeleton. Osteoporotic fractures constitute a major public health problem. Currently, in the United States alone, 10 million individuals already have osteoporosis, and a further 34 million more have low bone mass, placing them at increased risk from this disorder (4). Moreover, 1 in 8 European Union (EU) citizens over the age of 50 y will fracture their spine this year (1). The estimated remaining lifetime risk of fractures in Caucasian women at age 50 y, based on incidence rates in North America, is 17.5%, 15.6%, and 16% for hip, spine, and forearm, respectively; the remaining lifetime risk for any fragility fracture approaches 40% in women and 13% in men (5). The incidence of vertebral and hip fractures increases exponentially with advancing age (6). This is of particular concern because it is projected that the number of elderly (80 y and older, in whom the incidence of osteoporotic fracture is greatest) in the EU population will grow from 8.9 million women and 4.5 million men in 1995, to 26.4 million women and 17.4 million men in 2050 (1). Similar demographic changes have been forecast for the U.S. population (7). Because of the increase in incidence rates of osteoporotic fractures with age, these demographic changes and increasing life expectancy will have a huge impact on the number of fractures that can be expected to occur. For example, the number of hip fractures occurring each year in the EU alone is estimated to rise from current figures of 414,000 to 972,000 by 2050, representing an increase of 135% (1). Hip fracture patients have an overall mortality of 15–30% (8), the majority of excess deaths occurring within the first 6 mo after the fracture. From an economic perspective, the expenses of hospital care and rehabilitation associated with osteoporotic fractures are a considerable fiscal drain for the health care system, exceeding those of other highly prevalent pathologies of the elderly, such as myocardial infarction (9). Osteoporosis costs national treasuries over €3500 million annually in hospital health care alone (1). Risk factors for osteoporosis Low bone mineral mass is the main factor underlying osteoporotic fracture (10). Bone mass in later life depends on the peak bone mass achieved during growth and the rate of subsequent age-related bone loss. Development of maximal bone mass during growth and reduction of loss of bone later in life are the 2 main strategies of preventing osteoporosis (11). Consequently, any factor that influences the development of peak bone mass or the loss of bone in middle-age will affect later fracture risk. Several factors are thought to influence bone mass. These can be broadly grouped into factors that cannot be modified, such as gender, age, body (frame) size, genetics and ethnicity, and those factors that can be modified, such as hormonal status (especially sex and calciotropic hormone status), lifestyle factors including physical activity levels, smoking and alcohol consumption patterns, and diet (including functional foods). The interaction of these genetic, hormonal, environmental and nutritional factors influences both the development of bone to peak bone mass at maturity and its subsequent loss. The remainder of this article will focus on a selected number of dietary components/nutrients that may influence bone health. Diet, nutrition and bone health Many of the nutrients and food components we consume as part of a Westernized diet can potentially have a positive or negative impact on bone health (see Table 1). They may influence bone by various mechanisms, including alteration of bone structure, the rate of bone metabolism, the endocrine and/or paracrine system, and homeostasis of calcium and possibly of other bone-active mineral elements (12). These dietary factors range from inorganic minerals (e.g., calcium, magnesium, phosphorus, sodium, potassium, and various trace elements) and vitamins (vitamins A, D, E, K, C, and certain B vitamins), to macronutrients, such as protein and fatty acids. In addition, the relative proportions of these dietary factors derived from different types of diets (vegetarian vs. omnivorous) may also affect bone health and thus osteoporosis risk. Furthermore, in recent years a number of bioactive food components have been proposed as being beneficial for bone health. A review of all of these dietary factors is beyond the scope of the present article. .


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