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×èòàòåëü Íåäóã.Ðó
Homocysteine and Fracture Prevention
Joyce B. J. van Meurs, PhD; André G. Uitterlinden, PhD
JAMA. 2005;293:1121-1122.
Osteoporotic fractures are a major health problem in Western society and are associated with increased morbidity and mortality and substantial economic costs. Because the number of fractures will increase throughout the world as the population ages, prevention of fractures is becoming increasingly important. Recently, studies have identified a new and potentially modifiable risk factor for osteoporotic fracture—a mildly elevated circulating homocysteine level. These epidemiological studies showed that a relatively high homocysteine level predicts a higher fracture risk but they did not establish a causal relationship. The question remained whether the increase in fracture risk was due to homocysteine itself, or to other covarying factors.
To establish a causal relationship between elevated homocysteine concentrations and osteoporosis, data from 2 types of studies are needed. One consists of randomized placebo-controlled trials studying the effect of lowering homocysteine levels on the incidence of fractures, the most important clinical end point of osteoporosis. In addition, cellular and molecular studies are required to elucidate the biological mechanism linking high homocysteine concentrations with factors that predispose to or cause fracture.
In this issue of JAMA, Sato and colleagues present the first evidence that an elevated homocysteine level might indeed cause more brittle bones. In this randomized double-blind study, Japanese patients following stroke who were treated with folate and vitamin B12 had a 5 times lower risk for hip fracture over a follow-up period of 2 years compared with the placebo group. This is a very large risk reduction, but care should be taken in interpreting these results. As the authors note, the generalizability of the results is limited. The control patients had an unusually high incidence of hip fracture (4.3% per year) compared with the incidence in the average Japanese population of the same age (0.3% for women and 0.6% for men).5 In addition, the high mean levels of circulating homocysteine in the studied population (19.9 µmol/L) could explain the effectiveness of the therapy. Earlier studies suggested that there is a threshold above which homocysteine predicts increased fracture risk; the greater the percentage of the population above the threshold, the greater would be the expected effectiveness of treatment with a homocysteine-lowering therapy. The results of the study by Sato et al are also limited due to a relatively low power, with only 33 hip fractures during the study period of 2 years. This suggests that the 80% risk reduction reported in this study might not be detected in a larger study or with other (high-risk) populations, and the true relative risk might be as high as 0.5, which would translate to a 2-fold risk reduction.
A wide spectrum of diseases is already associated with elevated circulating homocysteine concentrations, such as cardiovascular disease (including stroke) and cognitive impairment. Because these diseases are also associated with a high fracture risk, they could be confounding factors. However, Sato et al adjusted their risk estimates for cardiovascular events and presence of dementia without an effect on the study outcome. More important, the fall frequency was similar in both groups, which means that with the same number of falls, the placebo group fractured more easily. Because the recording of the falls was well-validated with a "fall calendar" in combination with a monthly visit to the clinic, cognitive impairment without dementia, which could affect recall of the falls, is an unlikely confounder. Nevertheless, similar intervention studies in patients other than those who have had a stroke will be necessary to show generalizability of the conclusions.
Apart from showing that homocysteine levels were effectively reduced, Sato et al showed that vitamin B12 and folate levels were increased at the end of the study. It is possible that the observed effects on fracture are caused by increasing the levels of vitamin B12 rather than by lowering homocysteine. Vitamin B12 deficiency is common in the elderly population, ranging from 10% to 40%, depending on the diagnostic criteria. Vitamin B12 has been linked to bone health by a limited but growing number of studies. Patients with vitamin B12 deficiency (pernicious anemia) have a higher risk for fracture, and recent population-based studies suggest that vitamin B12 status is important for maintenance of bone mineral density (BMD). In addition, vitamin B12 has been found to affect osteoblast activity and bone formation. Because vitamin B12 plays an important role as a cofactor in metabolizing homocysteine, the levels of each are highly associated, making it difficult to separate the effects of vitamin B12 and homocysteine. This question can only be addressed by clarifying the biological mechanism linking homocysteine, vitamin B12, or both to fractures.
The reduced fracture risk observed by Sato et al could not be explained by BMD, which suggests that bone quality rather than bone quantity explains the difference in fracture risk. Previous studies did not find a relationship between homocysteine levels and femoral neck BMD,2 supporting the present findings. A mechanism underlying the deleterious effect of homocysteine on bone quality might involve inhibition of collagen cross-linking by high homocysteine concentrations. This hypothesis is based on observations in patients with homocystinuria, a rare autosomal recessive disease characterized by very high homocysteine levels and early generalized osteoporosis. In vivo evidence for this hypothesis is limited, and it remains to be determined whether disturbed collagen cross-linking is also involved when homocysteine levels are only mildly elevated.
Another way to prove a causal relationship between increased homocysteine and fracture risk is by studying mendelian randomization (ie, performing genetic association studies with polymorphisms known to increase homocysteine levels). This approach was recently successfully applied to examine the relationship between homocysteine and stroke. The most frequently studied related polymorphism is Ala222Val, a common functional polymorphism in the gene encoding for methylenetetrahydrofolate reductase, which has been found to cause higher homocysteine levels. A number of studies have found a relationship between this polymorphism and BMD and fracture. However, definitive answers about the relationship with fracture will require larger studies and possibly meta-analysis.
Despite the potential limitations of the study by Sato et al, the results show that—at least in patients following stroke—folate and vitamin B12 supplementation is effective in preventing hip fracture. Whether a similar effect can also be obtained in other (high fracture risk) patients can only be answered by other intervention studies. After the initial observation of association between circulating homocysteine levels and fracture risk less than 1 year ago, these results now support a causal link. However, final proof of causality will have to come from elucidation of the biological mechanism underlying this relationship.
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×èòàòåëü Íåäóã.Ðó
Effect of Folate and Mecobalamin on Hip Fractures in Patients With Stroke
A Randomized Controlled Trial
Yoshihiro Sato, MD; Yoshiaki Honda, MD; Jun Iwamoto, MD; Tomohiro Kanoko, PhD; Kei Satoh, MD
JAMA. 2005;293:1082-1088.
Context
Stroke increases the risk of subsequent hip fracture by 2 to 4 times. Hyperhomocysteinemia is a risk factor for both ischemic stroke and osteoporotic fractures in elderly men and women. Treatment with folate and mecobalamin (vitamin B12) may improve hyperhomocysteinemia.
Objective
To investigate whether treatment with folate and vitamin B12 reduces the incidence of hip fractures in patients with hemiplegia following stroke.
Design, Setting, and Patients
A double-blind, randomized controlled study of 628 consecutive patients aged 65 years or older with residual hemiplegia at least 1 year following first ischemic stroke, who were recruited from a single Japanese hospital from April 1, 2000, to May 31, 2001. Patients were assigned to daily oral treatment with 5 mg of folate and 1500 µg of mecobalamin, or double placebo; 559 completed the 2-year follow-up.
Main Outcome Measure
Incidence of hip fractures in the 2 patient groups during the 2-year follow-up.
Results
At baseline, patients in both groups had high levels of plasma homocysteine and low levels of serum cobalamin and serum folate. After 2 years, plasma homocysteine levels decreased by 38% in the treatment group and increased by 31% in the placebo group (P<.001). The number of hip fractures per 1000 patient-years was 10 and 43 for the treatment and placebo groups, respectively (P<.001). The adjusted relative risk, absolute risk reduction, and the number needed to treat for hip fractures in the treatment vs placebo groups were 0.20 (95% confidence interval [CI], 0.08-0.50), 7.1% (95% CI, 3.6%-10.8%), and 14 (95% CI, 9-28), respectively. No significant adverse effects were reported.
Conclusion
In this Japanese population with a high baseline fracture risk, combined treatment with folate and vitamin B12 is safe and effective in reducing the risk of a hip fracture in elderly patients following stroke.
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×èòàòåëü Íåäóã.Ðó
Î÷åíü èíòåðåñíîå ñîîáùåíèå, íî, äóìàþ, âðÿä ëè îíî íàéä¸ò ïðàêòè÷åñêîå ïðèìåíåíèå, ò.ê. áîëüíûì ïîñëå èíñóëüòà èòàê åñòü îò ÷åãî óìèðàòü
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×èòàòåëü Íåäóã.Ðó
È ïî÷òè óíèâåðñàëüíîé ïðè÷èíîé âñåõ ñòðàäàíèé âèäåòü àíåìèþ òîæå ïåðåáîð...
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×èòàòåëü Íåäóã.Ðó
Óâàæàåìûé Âàäèì Âàëåðüåâè÷, ñïàñèáî çà ñîîáùåíèå, íî äàâàéòå áëèæå ê ïðàêòèêå. ×òî æå ïðåäëàãàåòñÿ? Ïðèåì 5 ìã ôîëàòà è 1500 ìêã âèòàìèíà Â12 åæåäíåâíî â òå÷åíèå 2 ëåò? À êàêîé ïåíñèîíåð ñîãëàñèòñÿ â òå÷åíèå òàêîãî ïåðèîäà åæåäíåâíî ïðèíèìàòü óêàçàííûå ïðåïàðàòû? Èëè ìîæíî îãðàíè÷èòüñÿ, íàïðèìåð ìåñÿöåì òåðàïèè. È íå âåëèêà ëè äîçà â 1500 ìêã Â-12 åæåäíåâíî â òå÷åíèå äëèòåëüíîãî âðåìåíè?
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×èòàòåëü Íåäóã.Ðó
È ïî÷òè óíèâåðñàëüíîé ïðè÷èíîé âñåõ ñòðàäàíèé âèäåòü àíåìèþ òîæå ïåðåáîð...
Óâàæàåìûé êîëëåãà Ãàëëåí!
Åñëè Âû ïîñìîòðèòå áîëåå âíèìàòåëüíåå íà ðåä. êîììåíòàðèé, òî óâèäèòå, ÷òî êîáàëàìèí âëèÿåò íà îñòåîáëàñòè÷åñêóþ àêòèâíîñòü è êîñòåîáðàçîâàíèå íåïîñðåäñòâåííî, à íå ÷åðåç ïîääåðæàíèå ãåìîãëîáèíà íà ôèçèîëîãè÷åñêîì óðîâíå:
"vitamin B12 has been found to affect osteoblast activity and bone formation"
È ê ñîæàëåíèþ, ïîêà äîïîäëèííî íå óñòàíîâëåíî, ïî÷åìó ó îòäåëüíûõ ïàöèåíòîâ äåôèöèò êîáàëàìèíà ïðèâîäèò k ðàçâèòèþ ìåãàëîáëàñòíîé àíåìèè, à ó äðóãèõ äåôèöèò ïðîÿâëÿåòñÿ ïðåèìóùåñòâåííî â ÏÍÑ (âïëîòü äî ïàðàëè÷åé) èëè â ÖÍÑ (âïëîòü äî ñòàð÷åñêîãî ñëàáîóìèÿ), òîãäà êàê íàðóøåíèÿ ñî ñòîðîíû êðîâè ìèíèìàëüíû.
Åñëè æå ãîâîðèòü îá àíåìèÿõ ó ïîæèëûõ, òî ïðîñòàÿ àìåðèêàíñêàÿ ñòàòèñòèêà îöåíèâàåò åå êàê 10% ñðåäè ñòàðøå 65 ëåò è 20% - ïîñëå 85 ëåò è ÿâëÿåòñÿ íåáëàãîïðèÿòíûì ïðîãíîñòè÷åñêèì ôàêòîðîì äëÿ çàáîëåâàåìîñòè è âûæèâàåìîñòè:
Curr Opin Hematol. 2005 Mar;12(2):123-128.
Anemia in older adults.
Woodman R, Ferrucci L, Guralnik J.
In persons 65 years and older, anemia was present in 11.0% of men and 10.2% of women, with the prevalence rising to over 20% in people 85 years and older. One third of the cases were due to nutritional deficiencies, and one third was due to chronic illness, including but not limited to chronic kidney disease. About one third of the cases of anemia remain unexplained. Anemia is also prognostic for diminished physical performance and loss of mobility in people 65 years and older. A recent report suggests that the prevalence of anemia is even higher in elderly persons living in nursing homes. The data suggest that the risk of mortality and loss of mobility even extends to levels of hemoglobin normally considered low normal by WHO criteria, raising the question about optimal hemoglobin levels in the elderly.
Äåôèöèò êîáàëàìèíà ó ïîæèëûõ òîæå íå ðåäêîñòü:
Vitamin B12 deficiency affects about 5% of people aged 65–74 years and over 10% of people aged 75 years or older.
Age Ageing. 2004 Jan;33(1):34-41. Vitamin B12 and folate deficiency in later life. Clarke R è ñîàâò.
Åäèíñòâåííî, ïðàâ êîëëåãà ïîä íèêîì Algor ãîâîðÿ, ÷òî "âðÿä ëè [âñå ýòî] íàéä¸ò ïðàêòè÷åñêîå ïðèìåíåíèå" îñîáåííî íà íàøåé òåððèòîðèè, âåäü ïîæèëûõ ñòàðøå 65 âñå ìåíüøå è ìåíüøå â Ðîññèè:
Circulatory diseases exacerbated by stress are a major killer. Life expectancy for a Russian man has sunk to 58.4 years, the lowest of the 53 countries in the WHO European Region.
Russia's population crisis
Tom Parfitt
The Lancet
Volume 365, Issue 9461 , 26 February 2005, Pages 743-744
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×èòàòåëü Íåäóã.Ðó
Óâàæàåìûé Âàäèì Âàëåðüåâè÷.
Íè â êîåé ìåðå íå õîòåë óìàëèòü ïðÿìîå ïîëîæèòåëüíîå âîçäåéñòâèå êîáàëàìèíà íà îñòåîáëàñòè÷åñêóþ àêòèâíîñòü è êîñòåîáðàçîâàíèå. Ïðîñòî íå ñäåðæàëñÿ óâèäåâ çíàêîìûå "àíòèàíåìè÷íûå" ñëîâà â î÷åðåäíîé òåìå, âåñüìà äàë¸êîé îò àíåìèè, íà ìîé âçãëÿä ïðîñòîãî õèðóðãà...
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×èòàòåëü Íåäóã.Ðó
Óâàæàåìûé êîëëåãà È.Í. Åôèìîâ!
 îòíîøåíèè äîçû êîáàëàìèíà - âûáèðàåòñÿ ñëåäóþùàÿ èç-çà òîãî, ÷òî ó íîðìàëüíûõ ñóáüåêòîâ äëèòåëüíûé ïðèåì íå âûçûâàåò òîêñè÷åñêîãî äåéñòâèÿ âñëåäñòâèå êóìóëÿöèè, à ó ïàöèåíòîâ ñ îòñóòñòâèåì âíóòðåííåãî ôàêòîðà Êàñëà (íàèáîëåå ÷àñòîé ïðè÷èíîé ìåãàëîáëàñòíîé àíåìèè â ïîæèëîì âîçðàñòå) äàííàÿ äîçèðîâêà ñïîñîáíà ëèêâèäèðîâàòü êîáàëàìèíî-äåôèöèò (ïîñëå òîãî êàê áûëî îáíàðóæåíî, ÷òî 0,5-1% ïîñòóïàþùåãî êîáàëàìèíà ìîæåò óñâàèâàòüñÿ ôàêòîð-íåçàâèñèìûì ïóòåì).
Äëÿ ñðàâíåíèÿ äîç - ôðàãìåíò èäóùåãî Â-âèòàìèííîãî òðàéëà ïî ïðîôèëàêòèêå èíñóëüòà:
The VITATOPS study is a multicenter, randomized, double-blind, placebo-controlled secondary stroke prevention trial to determine whether the addition of vitamin supplements (B12, 500 µg; B6, 25 mg; and folate, 2 mg) will reduce the combined incidence of recurrent vascular events (stroke, myocardial infarction) and vascular death in patients with recent stroke or transient ischemic attack (TIA)...target is to recruit a total of 8000 patients over the next 2 years, with a median follow-up of 2.5 years.
Íå ïîìíþ íàçâàíèé, íî àíàëîãè÷íûå èäóò è ïî ÑÑÇ ñ ïðèìåðíî òàêèìè æå äîçàìè âèòàìèíîâ: êîáàëàìèí 500-1500 ìêã, ôîëèåâàÿ - 2-4 ìã.
 îòíîøåíèè áóäåò èëè íå áóäåò ïðèíèìàòü ïàöèåíò ýòè âèòàìèíû äëèòåëüíî - ýòî âîïðîñ êîìïëàéåíñà - áóäåò ëè ïðèíèìàòü àñïèðèí, ñòàòèí, ÈÀÏÔ, ÁÁ ïîñëå èíñóëüòà ïîæèçíåííî èëè îãðàíè÷èòñÿ 3-ìÿ ìåñÿöàìè?
Îòâåòèòü
