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Query: UMLS:C0026850 (
muscular dystrophy
)
5,870
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Cardiac disease is commonly associated with virtually every form of
muscular dystrophy
and myopathy. A double-blind and open crossover trial on the oral administration of
coenzyme Q10
(
CoQ10
) to 12 patients with progressive muscular dystrophies and neurogenic atrophies was conducted. These diseases included the Duchenne, Becker, and limb-girdle dystrophies, myotonic dystrophy, Charcot-Marie-Tooth disease, and Welander disease. The impaired cardiac function was noninvasively and extensively monitored by impedance cardiography. Solely by significant change or no change in stroke volume and cardiac output, all 8 patients on blind
CoQ10
and all 4 on blind placebo were correctly assigned (P less than 0.003). After the limited 3-month trial, improved physical well-being was observed for 4/8 treated patients and for 0/4 placebo patients; of the latter, 3/4 improved on
CoQ10
; 2/8 patients resigned before crossover; 5/6 on
CoQ10
in crossover maintained improved cardiac function; 1/6 crossed over from
CoQ10
to placebo relapsed. The rationale of this trial was based on known mitochondrial myopathies, which involve respiratory enzymes, the known presence of
CoQ10
in respiration, and prior clinical data on
CoQ10
and dystrophy. These results indicate that the impaired myocardial function of such patients with muscular disease may have some association with impaired function of skeletal muscle, both of which may be improved by
CoQ10
therapy. The cardiac improvement was definitely positive. The improvement in well-being was subjective, but probably real. Likely,
CoQ10
does not alter genetic defects but can benefit the sequelae of mitochondrial impairment from such defects.
CoQ10
is the only known substance that offers a safe and improved quality of life for such patients having muscle disease, and it is based on intrinsic bioenergetics.
...
PMID:Biochemical rationale and the cardiac response of patients with muscle disease to therapy with coenzyme Q10. 385 73
The aim of this study is to determine whether coenzyme Q (CoQ) muscle concentrations and redox state are associated with pathologic changes in muscle biopsy specimens. Skeletal muscle biopsies were collected (January 2002-February 2004) and underwent pathologic evaluation. Quadriceps specimens (n = 47) were stratified accordingly: Group 1, controls without evidence of pathologic abnormalities; Group 2, type I myofiber predominance; Group 3, type II myofiber atrophy; Group 4, lower motor unit disease; and Group 5,
muscular dystrophy
. Ubiquinol-10, ubiquinone-10, total
coenzyme Q10
(
CoQ10
), coenzyme Q9 (CoQ9), total CoQ (CoQ9+CoQ10) concentrations were analyzed in biopsy muscle by high-performance liquid chromatography.
Ubiquinone-10
, total
CoQ10
, and total CoQ concentrations were significantly decreased in Group 5. Significant positive correlations (r congruent with 0.40) were found between muscle ubiquinone-10, total
CoQ10
, and total CoQ concentrations vs the percentage of myofibers having subsarcolemmal mitochondrial aggregates. CoQ redox ratio and the fraction CoQ9/total CoQ were negatively correlated with subsarcolemmal mitochondrial aggregates. A significant correlation (r = 0.328) also occurred between ubiquinol-10 concentration and citrate synthase activity. This study suggests that total CoQ concentration provides a new method for estimating mitochondrial activity in biopsy muscle; and that the muscle CoQ test is feasible and potentially useful for diagnosing CoQ deficiency states.
...
PMID:Muscle coenzyme Q: a potential test for mitochondrial activity and redox status. 1586 32
A six-month-old male entire Norfolk terrier was presented with a 3-month history of poor development, reluctance to exercise and progressive and diffuse muscle atrophy. Serum creatine kinase concentration was markedly elevated. Magnetic resonance imaging of the epaxial muscles revealed asymmetrical streaky signal changes aligned within the muscle fibres (hyperintense on T2-weighted images and short-tau inversion recovery with moderate contrast enhancement on T1-weighted images). Electromyography revealed pseudomyotonic discharges and fibrillation potentials localised at the level of the supraspinatus, epaxial muscles and tibial cranialis muscles. Muscle biopsy results were consistent with dystrophin-deficient
muscular dystrophy
. The dog remained stable 7 months after diagnosis with
coenzyme Q10
and l-carnitine; however after that time, there was a marked deterioration and the owners elected euthanasia. This case report describes the clinical presentation, magnetic resonance imaging, electrodiagnostic and histopathological findings with immunohistochemical analysis in a Norfolk terrier with confirmed dystrophin-deficient
muscular dystrophy
, which has not been previously described in this breed.
...
PMID:Dystrophin-deficient muscular dystrophy in a Norfolk terrier. 2535 37
"Healthy" diets and supplements are widely used for prevention and disease modification in vascular, inflammatory and degenerative neurological diseases. Apart from a large number of cross-sectional and prospective cohort studies, there are only few interventional studies on individual dietary measures. A recent study confirmed the stroke preventive effect of a Mediterranean diet rich in olive oil and nuts; a ketogenic diet reduces seizure frequency in epilepsy. Supplementation of riboflavin, magnesium and
coenzyme Q10
are probably effective in migraine prophylaxis. Creatine can improve muscle strength in
muscular dystrophy
and myositis. There is insufficient evidence to recommend any of the many dietary supplements, such as vitamins, omega-3 fatty acids and other substances for the prevention or improvement of all other neurological diseases. This review critically evaluates the present data on the role of nutrition and dietary supplements in neurological diseases.
...
PMID:[Nutrition and dietary supplements in neurological diseases]. 2540 88
Coenzyme Q10
(
CoQ
) or ubiquinone is found in the biological system which is synthesized by the conjugation of benzoquinone ring with isoprenoid chain of variable length.
Coenzyme Q10
supplementation energizes the body and increases body energy production in the form of ATP and helps to treat various human diseases such as cardiomyopathy,
muscular dystrophy
, periodontal disease, etc. Reports of these potential therapeutic advantages of
CoQ10
have resulted in its high market demand, which focus the researchers to work on this molecule and develop better bioprocess methods for commercial level production. At the moment, chemical synthesis, semi-synthetic method as well as bio-production utilizing microbes as biofactory are in use for the synthesis of
CoQ10
. Chemical synthesis involves use of cheap and easily available precursor molecules such as isoprenol, chloromethylquinone, vinylalane, and solanesol. Chemical synthesis methods due to the use of various solvents and chemicals are less feasible, which limits its application. The microbial production of
CoQ10
has added advantages of being produced in optically pure form with high yield using inexpensive medium composition. Several bacteria, e.g.,
Agrobacterium, Paracoccus, Rhodobacterium
, and yeast such as
Candida, Rhodotorula
are the potent ubiquinone producer. Some alternative biosynthetic pathway for designing of
CoQ10
production coupled with metabolic engineering might help to increase
CoQ10
production. The most common practiced strategy for strain development for commercial
CoQ10
production is through natural isolation and chemical mutagenesis. Here, we have reviewed the chemical, semi-synthetic as well as microbial
CoQ10
production in detail.
...
PMID:CoQ10 a super-vitamin: review on application and biosynthesis. 2975 18
