America's Compounding Center says this about Niacine (B3):
"Niacin, also known as nicotinic acid, nicotinamide or vitamin B3, is a complex B vitamin. Niacin is used to treat patients with niacin deficiency, known as pellagra, which may be due to poor dietary intake, aging, malabsorption syndromes, or alcoholism. Classic symptoms associated with pellagra include inflammation and irritation of the skin, mental confusion, and diarrhea. Patients commonly develop a rash with darkening or thickening of the skin on the face. Niacin is found in lean meats, poultry, grains, eggs, fish, milk and legumes (such as beans, peas and peanuts). The recommended dose of niacin for mitochondrial disorders ranges from 50-100mg by mouth daily, according to the UMDF. Side effects associated with niacin supplementation include stomach discomfort, flushing of the upper body (particularly face and neck), headache, and liver problems. "
Tuesday, November 15, 2011
Monday, November 14, 2011
What is N-Acetylaspartic Acid (NAA)?
This is a question I've been asking over the last month. What, exactly, is this chemical, NAA, that is low in J's brain?
Simply stated, N-Acetylaspartic Acid (NAA) is a marker of neuron integrity and viability. A study in the American Journal of Neuroradiology said the following: Due to its near-exclusive localization to neurons and their processes, NAA is regarded as a marker for their health and density, and its level has been reported to decline in all neurodegenerative central nervous system disorders in adults.
N-Acetylaspartic Acid even has an entire website dedicated to it. N-Acetylaspartic Acid.com
NAA is also known as N-acetylaspartate and NAA is the second most most abundant amino acid in the brain. NAA gives off the largest signal in MRS of the human brain. This along with the fact that it is pretty much exclusive to neurons, makes it a reliable marker. The levels measured in the brain are decreased in many neuropathological conditions ranging from brain injury, stroke, Alzheimer's to Parkinson's. This also makes NAA a reliable diagnostic molecule for doctors treating patients with brain disease.
An article that I found on PubMed says:
An article I found on PubMed says this: "MRS studies of human brain disorders have invariably detected decreases in brain NAA concentrations when neuronal loss or dysfunction are involved with one major exception: Canavan Disease... virtually all other neurological disorders involving neuronal loss or dysfunction result in reduction of NAA levels."
A 2003 Medscape article titled MRI Shows Brain Injury in MS That Precedes Atrophy says the following:
"Neuronal cell death may be an important marker to measure the progression of MS, and this eventually may be a therapeutic target. "First you lose the neurons, and then the axons atrophy," Dr. Gonen told Medscape. "We don't have a treatment that interrupts this process, but physicians can use these images to encourage their patients to take medications that prevent attacks."
The marker for neuronal cell death is the amino acid derivative N-acetylaspartate (NAA). Because this protein is present almost exclusively in neuronal cells, Dr. Gonen and colleagues theorized that quantifying the level of NAA by proton MR spectroscopy would give an indication of whether the patient was experiencing a loss of these cells. Therefore, they sought to quantify the relationship among NAA levels, brain volume, and disease duration to better understand the early developments in MS."
Simply stated, N-Acetylaspartic Acid (NAA) is a marker of neuron integrity and viability. A study in the American Journal of Neuroradiology said the following: Due to its near-exclusive localization to neurons and their processes, NAA is regarded as a marker for their health and density, and its level has been reported to decline in all neurodegenerative central nervous system disorders in adults.
N-Acetylaspartic Acid even has an entire website dedicated to it. N-Acetylaspartic Acid.com
NAA is also known as N-acetylaspartate and NAA is the second most most abundant amino acid in the brain. NAA gives off the largest signal in MRS of the human brain. This along with the fact that it is pretty much exclusive to neurons, makes it a reliable marker. The levels measured in the brain are decreased in many neuropathological conditions ranging from brain injury, stroke, Alzheimer's to Parkinson's. This also makes NAA a reliable diagnostic molecule for doctors treating patients with brain disease.
An article that I found on PubMed says:
An article I found on PubMed says this: "MRS studies of human brain disorders have invariably detected decreases in brain NAA concentrations when neuronal loss or dysfunction are involved with one major exception: Canavan Disease... virtually all other neurological disorders involving neuronal loss or dysfunction result in reduction of NAA levels."
A 2003 Medscape article titled MRI Shows Brain Injury in MS That Precedes Atrophy says the following:
"Neuronal cell death may be an important marker to measure the progression of MS, and this eventually may be a therapeutic target. "First you lose the neurons, and then the axons atrophy," Dr. Gonen told Medscape. "We don't have a treatment that interrupts this process, but physicians can use these images to encourage their patients to take medications that prevent attacks."
The marker for neuronal cell death is the amino acid derivative N-acetylaspartate (NAA). Because this protein is present almost exclusively in neuronal cells, Dr. Gonen and colleagues theorized that quantifying the level of NAA by proton MR spectroscopy would give an indication of whether the patient was experiencing a loss of these cells. Therefore, they sought to quantify the relationship among NAA levels, brain volume, and disease duration to better understand the early developments in MS."
Mitochondria and Brain Disease
Mitochondria and Brain Disease is a great article for anyone looking for the link between the two.
"It is not surprising that, in adult neurons, which depend primarily on ATP production to meet bioenergetic demands, any compromises in mitochondrial function place neurons at a high risk for both dysfunction and/or death. The association between mitochondrial abnormalities and disease has been known for approximately four decades, with the description of a patient with hypermetabolism and a skeletal muscle biopsy demonstrating large numbers of abnormal mitochondria, a disorder now termed “mitochondrial myopathy” (Cassarino & Bennett, 1999). There exists substantial evidence that mitochondrial dysfunction and oxidative damage may play a key role in the pathogenesis of neurodegenerative disease. Evidence implicating both mitochondrial dysfunction and oxidative damage in the pathogenesis of Alzheimer’s disease (AD), and Huntington’s disease (HD), as well as ischemia and other neurological disorders, continues to accumulate"
"It is not surprising that, in adult neurons, which depend primarily on ATP production to meet bioenergetic demands, any compromises in mitochondrial function place neurons at a high risk for both dysfunction and/or death. The association between mitochondrial abnormalities and disease has been known for approximately four decades, with the description of a patient with hypermetabolism and a skeletal muscle biopsy demonstrating large numbers of abnormal mitochondria, a disorder now termed “mitochondrial myopathy” (Cassarino & Bennett, 1999). There exists substantial evidence that mitochondrial dysfunction and oxidative damage may play a key role in the pathogenesis of neurodegenerative disease. Evidence implicating both mitochondrial dysfunction and oxidative damage in the pathogenesis of Alzheimer’s disease (AD), and Huntington’s disease (HD), as well as ischemia and other neurological disorders, continues to accumulate"
MR Spectroscopy in Mitochondrial Diseases
Proton MR Spectroscopy of Mitochondrial Diseases: Analysis of Brain Metabolic Abnormalities and Their Possible Diagnostic Relevance
http://www.ajnr.org/content/24/10/1958.fullI've been trying to find medical papers on MRS in Mito. This one seems to be quite useful. Our doctor sent us a good one, but I have not been able to find it on-line. I'd say enjoy reading, except, if you are interested in reading, it isn't likely because you enjoy the topic (at least this is the case for me...I wish I'd never heard of Spectroscopy, to be honest)!
A quote from the article: "Mitochondrial diseases with respiratory chain dysfunction are a wide group of clinical disorders that result from mutations in mitochondrial or nucleus-encoded OXPHOS subunit genes. Skeletal muscles and brain are the most commonly affected tissues mainly because their energy production strongly relies on mitochondrial oxidative phosphorylation. However, other organs and tissues such as heart, liver, kidney, and endocrine glands may also be involved. Different syndromes have been described on the basis of the type of primary or nucleus-driven mitochondrial DNA (mtDNA) mutation, but in most cases the consequent biochemical defect is not related to a single clinical manifestation. Diagnosis is often a challenge, based on a multidisciplinary approach that uses clinical, biochemical, neuroradiologic, and genetic data (1–3)."