Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UMLS:C0004352 (autism)
 32,579 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Magnetic resonance imaging (MRI) has opened a new window to the brain. Measuring hippocampal volume with MRI has provided important information about several neuropsychiatric disorders. We reviewed the literature and selected all English-language, human subject, data-driven papers on hippocampal volumetry, yielding a database of 423 records. Smaller hippocampal volumes have been reported in epilepsy, Alzheimer's disease, dementia, mild cognitive impairment, the aged, traumatic brain injury, cardiac arrest, Parkinson's disease, Huntington's disease, Cushing's disease, herpes simplex encephalitis, Turner's syndrome, Down's syndrome, survivors of low birth weight, schizophrenia, major depression, posttraumatic stress disorder, chronic alcoholism, borderline personality disorder, obsessive-compulsive disorder, and antisocial personality disorder. Significantly larger hippocampal volumes have been correlated with autism and children with fragile X syndrome. Preservation of hippocampal volume has been reported in congenital hyperplasia, children with fetal alcohol syndrome, anorexia nervosa, attention-deficit and hyperactivity disorder, bipolar disorder, and panic disorder. Possible mechanisms of hippocampal volume loss in neuropsychiatric disorders are discussed.
 ...
PMID:MR-based in vivo hippocampal volumetrics: 2. Findings in neuropsychiatric disorders. 1535 39

Comorbidity is the rule, not the exception, in bipolar disorder. The most common mental disorders that co-occur with bipolar disorder in community studies include anxiety, substance use, and conduct disorders. Disorders of eating, sexual behavior, attention-deficit/hyperactivity, and impulse control, as well as autism spectrum disorders and Tourette's disorder, co-occur with bipolar disorder in clinical samples. The most common general medical comorbidities are migraine, thyroid illness, obesity, type II diabetes, and cardiovascular disease. Bipolarity is a marker for comorbidity, and comorbid disorders, especially multiple conditions occurring when a patient is young, may be a marker for bipolarity. Relatively few controlled clinical studies have examined the treatment of bipolar disorder in the context of comorbid conditions (i.e., complicated or comorbid bipolar disorder). However, the first step in treating any type of complicated bipolar disorder--stabilizing a patient's mood--may be associated with improving the comorbid disorder. Standard mood stabilizers, atypical antipsychotics, and non-antimanic antiepileptic agents are emerging as potentially useful treatments for several of the disorders that frequently co-occur with bipolar disorder, and therefore may be useful treatments for comorbid bipolar disorder.
 ...
PMID:Diagnosing and treating comorbid (complicated) bipolar disorder. 1555 95

With optimal pregnancy conditions (natural, enriched diet which includes fish) African (Digo) infants are 3-4 weeks ahead of European/American infants in sensorimotor terms at birth, and during the first year. Infants of semi-aquatic sea-gypsies swim before they walk, and have superior visual acuity compared with us. With adverse pregnancy behaviour (fear of fat, a trend to dieting), neglecting the need for brain fat to secure normal brain development and function, we run a risk of dysfunction--death. Sudden Infant Death Syndrome victims have depressed birth weight, lower levels of marine fat in brainstem than controls, and >80 suffer multiple hypoxic episodes prior to death. Depressed birth weight (more than 10% below mean) is seen in learning and behaviour disorders, and a trend towards weights of less than 3kg is increasing, which supports a rise in antenatal sub optimality. Given marine fat deficiency in pregnancy and infancy, neurons starved for fuel could delay myelination and maturation in the latest developed Frontal Lobes. The phylogenetic oldest Lateral Frontal Lobe System (feed-back mechanism etc.) derived from olfactory bulb-amygdala, which crosses in Anterior Commisure is probably spared, while the Medial Frontal Lobe System derived from Hippocampus-Cingulum and crosses in Corpus Callosum (delayed response task) is most likely affected. The rise in infantile autism (intact vision and hearing) with deficit in delayed response task only, could suggest a deficit in the Medial Frontal Lobe System. The human species is unique; 70% of total energy to the foetus goes to development of the brain, which mainly consists of marine fat. It undergoes pervasive regressive events, before birth, in infancy and at puberty. Minimal retraction of neuronal arborisation is advantageous. Attributable to adverse pregnancy childrearing practice, excessive retraction is likely prenatally and in infancy. Pubertal age affects the fundamental property of nervous tissue, excitability: excessive excitatory drive is seen in early, and a deficiency in late puberty. It is postulated that with adequate marine fat, there is probably no risk of psychopathology at the extremes, whereas a deficiency could lead to paroxysmal (subcortical) dysfunction in early puberty, and breakdown of cortical circuitry and cognitive dysfunctions in late puberty. The post-pubertal psychoses, schizophrenia and manic-depressive psychosis at the extremes of the pubertal age continuum, with contrasting excitability and biological treatment, are probably the result of continuous dietary deficiency, which has inactivated the expression of genes for myelin development and oligodendrocyte-related genes in their production of myelin. The beneficial effect of marine fat in both disorders, in other CNS disorders as well as in developmental dyslexia (DD) and ADHD among others, supports our usual diet is persistently deficient. We have neglected the similarity of our great brain to other mammals, and our marine heritage. Given the amount of marine fat needed to secure normal brain development and function is not known, nor the present dietary level, it seems unduly conjectural to postulate that a dietary deficiency in marine fat is causing brain dysfunction and death. However, all observations point in the same direction: our diet focusing on protein mainly, is deficient, the deficiency is most pronounced in maternal nutrition and in infancy.
 ...
PMID:From superior adaptation and function to brain dysfunction--the neglect of epigenetic factors. 1561 23

Retinoid receptors (RARs and RXRs) regulate brain morphogenesis and function. Defects in these receptors may contribute to schizophrenia or other psychiatric diseases. To test the hypothesis that genetic variants of the retinoid receptor genes may predispose to schizophrenia and other psychiatric diseases, the six RAR and RXR genes and a heterodimer partner, the NURR1 gene, were scanned in 100 schizophrenia patients, along with pilot studies in 20-24 patients with bipolar disorder (BPD), attention-deficit hyperactivity disorder (ADHD), autism, or alcoholism. A total of 5.4 megabases of genomic sequence was scanned. No variants affecting protein structure or expression (VAPSEs) were found in four of the genes. One uncommon missense variant was found in each of the RARbeta, RARgamma, and RXRgamma genes. We conclude that structural variants in the RAR/RXR and NURR1 genes do not play a major role in the etiology of schizophrenia.
 ...
PMID:Structural variants in the retinoid receptor genes in patients with schizophrenia and other psychiatric diseases. 1563 45

The brain is one of the organs with the highest level of lipids (fats). Brain lipids, formed of fatty acids, participate in the structure of membranes, for instance 50 % fatty acids are polyunsaturated in the gray matter, 1/3 are of the omega-3 family, and are thus of dietary origin. The omega-3 fatty acids (mainly alpha-linolenic acid, ALA) participated in one of the first experimental demonstration of the effect of dietary substances (nutrients) on the structure and function of the brain. Experiments were first of all carried out on ex vivo cultured brain cells, then on in vivo brain cells (neurons, astrocytes and oligodendrocytes) from animals fed ALA deficient diet, finally on physicochemical (membrane fluidity), biochemical, physiological, neurosensory (vision an auditory responses), and behavioural or learning parameters. These findings indicated that the nature of polyunsaturated fatty acids (in particular omega-3) present in formula milks for human infants determines to a certain extend the visual, neurological, and intellectual abilities. Thus, in view of these results and of the high polyunsaturated fatty acid content of the brain, it is normal to consider that they could be involved in psychiatric diseases and in the cognitive decline of ageing. Omega-3 fatty acids appear effective in the prevention of stress, however their role as regulator of mood is a matter for discussion. Indeed, they play a role in the prevention of some disorders including depression (especially post partum), as well as in dementia, particularly Alzheimer's disease. Their role in major depression and bipolar disorder (manic-depressive disease), only poorly documented, is not clearly demonstrated. The intervention of omega-3 in dyslexia, autism, and schizophrenia has been suggested, but it does not necessarily infer a nutritional problems. The respective importance of the vascular system (where the omega-3 are actually active) and the cerebral parenchyma itself, remain to be resolved. However, the insufficient supply of omega-3 fatty acids in today diet in occidental (less than 50 % of the recommended dietary intakes values for ALA) raises the problem of how to correct inadequate dietary habits, by prescribing mainly rapeseed (canola) and walnut oils on the one hand, fatty fish (wild, or farmed, but the nature of fatty acids present in fish flesh is the direct consequence of the nature of fats with which they have been fed), and eggs from laying hens fed omega-3 fatty acids.
 ...
PMID:[Omega-3 fatty acids in psychiatry]. 1569 97

In view of the high omega-3 poly unsaturated fatty acid content of the brain, it is evident that these fats are involved in brain biochemistry, physiology and functioning; and thus in some neuropsychiatric diseases and in the cognitive decline of ageing. Though omega-3 fatty acids (from fatty fish in the human diet) appear effective in the prevention of stress, their role as regulator of mood and of libido is a matter for discussion pending experimental proof in animal and human models. Dietary omega-3 fatty acids play a role in the prevention of some disorders including depression, as well as in dementia, particularly Alzheimer's disease. Their direct role in major depression, bipolar disorder (manic-depressive disease) and schizophrenia is not yet established. Their deficiency can prevent the renewal of membranes, and thus accelerate cerebral ageing; none the less, the respective roles of the vascular component on one hand (where the omega-3's are active) and the cerebral parenchyma itself on the other, have not yet been clearly resolved. The role of omega-3 in certain diseases such as dyslexia and autism is suggested. In fact, omega-3 fatty acids participated in the first coherent experimental demonstration of the effect of dietary substances (nutrients) on the structure and function of the brain. Experiments were first of all carried out one x-vivo cultured brain cells (1), then on in vivo brain cells(2), finally on physiochemical, biochemical, physiological, neurosensory, and behavioural parameters (3). These findings indicated that the nature of poly unsaturated fatty acids(in particular omega-3) present in formula milks for infants (both premature and term) determines the visual, cerebral,and intellectual abilities, as described in a recent review (4). Indeed,the insufficient dietary supply of omega-3 fatty acids in today's French and occidental diet raises the problem of how to correct dietary habits so that the consumer will select foods that are genuinely rich in omega-3/ the omega-3 family ; mainly rapeseed, (canola) and walnut oils on one hand and fatty fish on the other.
 ...
PMID:Dietary omega-3 Fatty acids and psychiatry: mood, behaviour, stress, depression, dementia and aging. 1575 Jun 63

Genome investigations of autism, attention deficit hyperactivity disorder (ADHD), and dyslexia suggest possible genetic overlap. Atypical cerebral asymmetry (ACA), the absence of the left hemisphere dominance for language, may be a shared phenotype due to genes located in regions of overlap. A binomal test is used to evaluate whether linked regions overlap more than expected by chance for 15 genome-wide scans in autism, ADHD, and dyslexia. Significant evidence of linkage overlap (P = 10(-7)) is seen for autism, ADHD, and dyslexia for seven chromosomal regions (2p11-12, 5p13, 7q22-33, 9q33-34, 13q22, 16p13, and 17p11-q11). Linkage analysis of ACA and molecular markers for 270 sibling pairs with ADHD is conducted using the Haseman-Elston statistic. Linkage analysis supports ACA as a shared phenotype with risk genes located on 9q33-34 or 16p13 (P < 0.004). Further support stems from the overlap of these regions in schizophrenia, bipolar illness, specific language impairment (SLI), and handedness, all traits associated with ACA. Autism, ADHD, and dyslexia share regions of linkage overlap and ACA may be a shared phenotype for such genes similar to HLA in autoimmune disease. Because ACA is associated with certain aspects of creativity, such risk genes may also be enhancer genes for creativity.
 ...
PMID:Toward localizing genes underlying cerebral asymmetry and mental health. 1580 84

Intriguing parallels have been noted previously between the biology of Vitamin D and the epidemiology of schizophrenia. We have scanned the Vitamin D receptor (VDR) gene by DOVAM-S (Detection of Virtually All Mutations-SSCP), a robotically enhanced multiplexed scanning method. In total, 100 patients with schizophrenia (86 Caucasians and 14 African-Americans) were scanned. In addition, pilot experiments were performed in patients with bipolar disorder (BPD) (24), autism (24), attention deficit hyperactivity disorder (ADHD) (24), and alcoholism (20). A total of 762 kb of the VDR genomic sequence was scanned. R208N and V339I were each found in one African-American patient, while absent in 35 African-American controls without schizophrenia (2/14 versus 0/35, P=0.08). Within the power of the study (> or =1.6-fold relative risk), the common M1T variant is not associated with schizophrenia. In the 92 scanned patients with other psychiatric diseases, R173S was found in a single patient with bipolar disorder. In conclusion, we describe three novel structural variants of the Vitamin D receptor. Further study is required to clarify their role, if any, in psychiatric disease.
 ...
PMID:Vitamin D receptor variants in 192 patients with schizophrenia and other psychiatric diseases. 1585 47

Imprinted genes are epigenetically modified genes whose expression is determined according to their parent of origin. They are involved in embryonic development, and imprinting dysregulation is linked to cancer, obesity, diabetes, and behavioral disorders such as autism and bipolar disease. Herein, we train a statistical model based on DNA sequence characteristics that not only identifies potentially imprinted genes, but also predicts the parental allele from which they are expressed. Of 23,788 annotated autosomal mouse genes, our model identifies 600 (2.5%) to be potentially imprinted, 64% of which are predicted to exhibit maternal expression. These predictions allowed for the identification of putative candidate genes for complex conditions where parent-of-origin effects are involved, including Alzheimer disease, autism, bipolar disorder, diabetes, male sexual orientation, obesity, and schizophrenia. We observe that the number, type, and relative orientation of repeated elements flanking a gene are particularly important in predicting whether a gene is imprinted.
 ...
PMID:Genome-wide prediction of imprinted murine genes. 1593 Apr 97

After a previous paper discussing the possible association between beta-thalassemias and bipolar disorder, this article considers a possible association between alpha-thalassemia and the bipolar disorder. We report the case of a 36 year old woman with bipolar disorder and alpha-thalassemia. The patient, native of Reunion Island, has a family history of bipolar disorder (both parents, one brother, and a paternal uncle). The severity of the bipolar disorder type I in her family, is illustrated by the suicides of both parents, one brother and the paternal uncle, in intervals of only a few years. After a Medline review (1980-2004) we found only two studies suggesting a possible relationship between bipolar disorders and alpha-thalassemias, but without clinical case report information. Some genetic studies described the existence of possible genetic susceptibility for bipolar disorder on the short arm of chromosome 16, close to the gene involved in certain alpha-thalassemias, on the region 16p13.3. An interesting finding is that the sequencing of 258 kb of the chromosome region 16p13.3 not only allowed the identification of genes involved in the alpha-thalassemia and in the vulnerability to bipolar disorders, but also the identification of genes implicated in tuberous sclerosis, in polycystic kidney disease, in cataract with microophtalmia, and in vulnerability genetic factors for ATR-16 syndrome, asthma, epilepsy, certain forms of autism and mental retardation. Numerous clinical descriptions and some familial studies on linkage suggested a possible relationship between tuberous sclerosis, polycystic kidney disease, cataract with microophtalmia, ATR-16 syndrome, asthma, epilepsy, certain forms of autism, mental retardation and bipolar disorder, given the closeness of these vulnerability genes on the short arm of the chromosome 16. A vulnerability gene of alcohol dependence was also identified on this same chromosome region (16p13.3), by a study concerning 105 families. Taking into account the methodological difficulties due to the clinical and genetic heterogeneity of bipolar disorder, we suggest that linkage techniques should be used to confirm the presence of susceptibility genetic factor for bipolar disorders on chromosome 16. Thus a known genetic disease (alpha-thalassemia) could contribute to confirming the presence on the short arm of chromosome 16 of a susceptibility genetic factor for bipolar disorders. Linkage studies should be performed in families with a strong association for both diseases. Thanks to linkage techniques, one could hope for an improvement in understanding the physiopathology of bipolar disorder, with possible implications at a therapeutic level.
 ...
PMID:[Alpha-thalassemias and bipolar disorders: a genetic link?]. 1597 42


<< Previous 1 2 3 4 5 6 7 8 9 10 Next >>