Ketones: Metabolism's Ugly Duckling

VanItallie, Theodore B.; Nufert, Thomas H.

doi:10.1301/nr.2003.oct.327-341

Cited by 171 publications

(143 citation statements)

References 81 publications

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“…Moreover, trials of ketogenic diets in the treatment of final stage cancer patients and in experimental systems (Tisdale et al 1987;Breitkreutz et al 2005;Zuccoli et al 2010;Ho et al 2011;Klement and Kaemmerer 2011;Schmidt et al 2011;Chang et al 2013) have occurred, with some interesting results of reduction in tumour size, reduction of cachexia, or delay of initiation of cancer. Ketogenic diets continue to be used to treat some classes of epilepsy (Freeman et al 1998;Kossoff et al 2006;Neal et al 2008), and have been suggested for other mental disorders or dementias including Alzheimer's disease and Parkinson's disease (VanItallie and Nufert 2003;Kim et al 2007;Kossoff and Hartman 2012). A random controlled trial of an additive to the normal diet, AC-1202, consisting of short-and medium-chain TAG derived from coconut oil and that are metabolised to ketone bodies, has shown some improvement in Alzheimer's disease sufferers from ketone body production (Henderson et al 2009).…”

Section: Health Effects Of Fat As a Macronutrient And Energy Sourcementioning

confidence: 99%

Should animal fats be back on the table? A critical review of the human health effects of animal fat

Barendse

2014

Anim. Prod. Sci.

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Abstract.Humans hunt or raise a wide variety of animals for meat, which vary from free-range to intensively reared. These animals form a valuable part of human nutrition. Their tissues, including the fat, contain vitamin and other essential nutrients necessary for health. However, animal fat from ruminants and other land mammals is usually regarded as saturated. The purpose of this review is partly to examine the basis for the saturated fat hypothesis of cardiovascular disease given more recent research, to examine the human health effects of animal fats, and partly to draw into one place the diverse knowledge about animal fat and the effects of fat on metabolism. Mechanistic understanding of the initiation of the fatty streak and atherosclerosis calls into question the avoidance of ruminant or porcine fat. Due to high levels of oleic acid, a low n-6 : n-3 fatty acid ratio in some groups, and the presence of specific micronutrients including vitamins and essential fatty acids, animal fats are of benefit in human nutrition. Animal fats can be obtained in minimally processed form making them a convenient source of energy and micronutrients.

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Section: Health Effects Of Fat As a Macronutrient And Energy Sourcementioning

confidence: 99%

Should animal fats be back on the table? A critical review of the human health effects of animal fat

Barendse

2014

Anim. Prod. Sci.

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“…Ketone bodies are utilised by brain proportional to their arterial concentrations (Hawkins et al 1971;Robinson and Williamson 1980;Blomqvist et al 2002) and in humans, can provide as much as 60% of brain substrate requirements during prolonged starvation (Cahill 1983). This partial substitution of glucose by ketones not only helps to maintain fuel supply to the brain, but also reduces the need for protein catabolism to provide gluconeogenic precursors (Cahill 1983;VanItallie and Nufert 2003) and thus greatly prolongs survival time, as mammals tend to have a greater capacity for catabolism of body fat than body protein. However, brain tissue cannot run on ketone bodies as an exclusive substrate and continues to use glucose at all times (Sokoloff et al 1977;Hertz and Dienel 2002).…”

Section: Ketone Bodies: Glucose Substitutesmentioning

confidence: 99%

Hypercarnivory and the brain: protein requirements of cats reconsidered

Eisert

2010

J Comp Physiol B

103

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The domestic hypercarnivores cat and mink have a higher protein requirement than other domestic mammals. This has been attributed to adaptation to a hypercarnivorous diet and subsequent loss of the ability to downregulate amino acid catabolism. A quantitative analysis of brain glucose requirements reveals that in cats on their natural diet, a significant proportion of protein must be diverted into gluconeogenesis to supply the brain. According to the model presented here, the high protein requirement of the domestic cat is the result of routing of amino acids into gluconeogenesis to supply the needs of the brain and other glucose-requiring tissues, resulting in oxidation of amino acid in excess of the rate predicted for a non-hypercarnivorous mammal of the same size. Thus, cats and other small hypercarnivores do not have a high protein requirement per se, but a high endogenous glucose demand that is met by obligatory amino acid-based gluconeogenesis. It is predicted that for hypercarnivorous mammals with the same degree of encephalisation, endogenous nitrogen losses increase with decreasing metabolic mass as a result of the allometric relationships of brain mass and brain metabolic rate with body mass, possibly imposing a lower limit for body mass in hypercarnivorous mammals.

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“…However, before analyzing how benefits from therapeutic ketosis could be exploited, let us mention some pivotal concepts about metabolism. Under normal conditions and mostly in western societies, a healthy brain utilizes glucose as primary energy source, which unbalance can lead to a number of neurodegenerative disorders often associated with mitochondrial impairment and glucose transport-related dysfunctions, such as in epilepsy, Traumatic Brain Injury (TBI), Parkinson's and Alzheimer's diseases [6,7]. Ketone bodies and Krebs cycle intermediates represent the best fuels for brain and other organs.…”

Section: Editorialmentioning

confidence: 99%

“…Thus, ketone esters may represent the future "ketogenic diet in a pill" [42] paving the road to further testing. Through the past decades, confusion on physiological state of nutritional ketosis has generated some misunderstanding within the medical community [7], such as the wrong association of "therapeutic ketosis" (blood ketones comprised between 0.5 and 8 mM) with "diabetic ketoacidosis" (>10 mM). In addition, another frequent observation is that initial stages of ketosis induce a transient blood pH drop [43] due to ketone bodies accumulation in the bloodstream.…”

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confidence: 99%

The Ketogenic Diet Approach as Metabolic Treatment for a Variety of Diseases

Pilla¹

2016

J Epilepsy

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EditorialHuman brain derives over 60% of its energy from ketones when glucose availability is limited. After prolonged periods of fasting or Ketogenic Diet (KD), the whole body utilizes energy obtained from Free Fatty Acids (FFAs) released from adipose tissue. However, the brain is not capable to obtain significant energy from FFAs, thus hepatic ketogenesis converts them into ketone bodies: β-Hydroxybutyrate (BHB) and acetoacetate (AcAc), while a percentage of AcAc spontaneously decarboxylates to acetone [1]. To date, it has been broadly demonstrated how the metabolic state of mild ketosis, which can be induced through KD administration, calorie restriction or fasting, represents a valid tool for the metabolic management of epilepsy and a number neurodegenerative diseases [2], Amyotrophic Lateral Sclerosis (ALS) [3], and some types of cancer [4,5]. In addition, nutritional treatments represent an effective alternative where pharmaceutical approaches fail or produce unbearable side effects and costs for public health worldwide. However, before analyzing how benefits from therapeutic ketosis could be exploited, let us mention some pivotal concepts about metabolism. Under normal conditions and mostly in western societies, a healthy brain utilizes glucose as primary energy source, which unbalance can lead to a number of neurodegenerative disorders often associated with mitochondrial impairment and glucose transport-related dysfunctions, such as in epilepsy, Traumatic Brain Injury (TBI), Parkinson's and Alzheimer's diseases [6,7]. Ketone bodies and Krebs cycle intermediates represent the best fuels for brain and other organs. In fact, through their utilization, impaired glucose metabolism may be bypassed and their neuroprotective properties may be exploited [8]. However, neuroprotective mechanisms of ketosis are currently object of studies as mechanisms of action are still not sufficiently understood. It has been shown that ketone bodies are neuroprotective as they induce a consistent increase in mitochondrial biogenesis regulating the synaptic function, and also generate ATP increases, thus reducing the reactive oxygen species production in neurological tissues [9,10], and notably inhibit superoxide synthesis in primary rat neuronal cultures exposed to hyperoxia [11]. Moreover, the main reason why the KD has been proven so effective as an anticonvulsant aFpproach is because it significantly reduces the metabolism of glucose [12]. In addition, Ma and colleagues [13] demonstrated that, at physiological concentrations, BHB and AcAc reduce spontaneous discharges of GABAergic neurons in the rat substantia nigra, through ATP-sensitive potassium channels.Also, a reduction of total CNS aspartate levels in association with an increase of glutamate concentrations was found during ketosis, observing a significant increase of decarboxylated glutamate to GABA, the main inhibitory neurotransmitter [14,15]. Moreover, a remarkable increase in mitochondrial transcription enzymes and proteins was observed in rat hippocampus after the...

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Ketones: Metabolism's Ugly Duckling

Cited by 171 publications

References 81 publications

Should animal fats be back on the table? A critical review of the human health effects of animal fat

Should animal fats be back on the table? A critical review of the human health effects of animal fat

Hypercarnivory and the brain: protein requirements of cats reconsidered

The Ketogenic Diet Approach as Metabolic Treatment for a Variety of Diseases

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