Do Young Kim1, Jong M Rho. 1. Barrow Neurological Institute, St. Joseph's Hospital & Medical Center, Phoenix, Arizona 85013, USA. doyoung.kim@chw.edu
Abstract
PURPOSE OF REVIEW: The ketogenic diet has long been used to treat medically refractory epilepsy. The mechanisms underlying its clinical effects, however, have remained a mystery. The evidence to date suggests that a fundamental shift from glycolysis to intermediary metabolism induced by the ketogenic diet is necessary and sufficient for clinical efficacy. This notion is supported by a growing number of studies indicating that glucose restriction, ketone bodies and polyunsaturated fatty acids may all play mechanistic roles, possibly by enhancing mitochondrial respiration and ATP production, and decreasing reactive oxygen species production. RECENT FINDINGS: Recent reports indicate that ketone bodies can reduce oxidative stress and that fatty acid-induced mitochondrial uncoupling may also yield similar protective effects. Ketone bodies may attenuate spontaneous firing of ATP-sensitive potassium channels in central neurons, and pharmacological inhibition of glycolysis has been shown to retard epileptogenesis in a rat kindling model. SUMMARY: While the mechanisms underlying the broad clinical efficacy of the ketogenic diet remain unclear, there is growing evidence that the ketogenic diet alters the fundamental biochemistry of neurons in a manner that not only inhibits neuronal hyperexcitability but also induces a protective effect. Thus, the ketogenic diet may ultimately be useful in the treatment of a variety of neurological disorders.
PURPOSE OF REVIEW: The ketogenic diet has long been used to treat medically refractory epilepsy. The mechanisms underlying its clinical effects, however, have remained a mystery. The evidence to date suggests that a fundamental shift from glycolysis to intermediary metabolism induced by the ketogenic diet is necessary and sufficient for clinical efficacy. This notion is supported by a growing number of studies indicating that glucose restriction, ketone bodies and polyunsaturated fatty acids may all play mechanistic roles, possibly by enhancing mitochondrial respiration and ATP production, and decreasing reactive oxygen species production. RECENT FINDINGS: Recent reports indicate that ketone bodies can reduce oxidative stress and that fatty acid-induced mitochondrial uncoupling may also yield similar protective effects. Ketone bodies may attenuate spontaneous firing of ATP-sensitive potassium channels in central neurons, and pharmacological inhibition of glycolysis has been shown to retard epileptogenesis in a rat kindling model. SUMMARY: While the mechanisms underlying the broad clinical efficacy of the ketogenic diet remain unclear, there is growing evidence that the ketogenic diet alters the fundamental biochemistry of neurons in a manner that not only inhibits neuronal hyperexcitability but also induces a protective effect. Thus, the ketogenic diet may ultimately be useful in the treatment of a variety of neurological disorders.
Authors: Do Young Kim; Kristina A Simeone; Timothy A Simeone; Jignesh D Pandya; Julianne C Wilke; Younghee Ahn; James W Geddes; Patrick G Sullivan; Jong M Rho Journal: Ann Neurol Date: 2015-05-06 Impact factor: 10.422
Authors: Juan M Pascual; Peiying Liu; Deng Mao; Dorothy I Kelly; Ana Hernandez; Min Sheng; Levi B Good; Qian Ma; Isaac Marin-Valencia; Xuchen Zhang; Jason Y Park; Linda S Hynan; Peter Stavinoha; Charles R Roe; Hanzhang Lu Journal: JAMA Neurol Date: 2014-10 Impact factor: 18.302
Authors: Yong Xu; Juli E Jones; Daisuke Kohno; Kevin W Williams; Charlotte E Lee; Michelle J Choi; Jason G Anderson; Lora K Heisler; Jeffrey M Zigman; Bradford B Lowell; Joel K Elmquist Journal: Neuron Date: 2008-11-26 Impact factor: 17.173