Hostname: page-component-586b7cd67f-vdxz6 Total loading time: 0 Render date: 2024-11-24T15:03:53.218Z Has data issue: false hasContentIssue false

Prevalence and predictors of vitamin D inadequacy amongst Lebanese osteoporotic women

Published online by Cambridge University Press:  17 July 2008

Marie-Hélène Gannagé-Yared*
Affiliation:
Department of Endocrinology, Saint-Joseph University, Hôtel-Dieu de France Hospital, Achrafieh, Beirut, Lebanon
Ghassan Maalouf
Affiliation:
Department of Orthopedics, Balamand University, Beirut, Lebanon
Simon Khalife
Affiliation:
Department of Biostatistics, Saint-Joseph University, Beirut, Lebanon
Samir Challita
Affiliation:
Department of Endocrinology, Saint-Joseph University, Hôtel-Dieu de France Hospital, Achrafieh, Beirut, Lebanon
Yasser Yaghi
Affiliation:
Department of Orthopedics, Hammoud Hospital, Saida, Lebanon
Nelly Ziade
Affiliation:
Department of Endocrinology, Saint-Joseph University, Hôtel-Dieu de France Hospital, Achrafieh, Beirut, Lebanon
Amal Chalfoun
Affiliation:
Merck Sharp and Dohme, Lebanon Representative Office, Dbayeh Main Road, Haddad Center, PO Box 70679, Metn, Lebanon
Josephine Norquist
Affiliation:
Department of Epidemiology, Merck Research Laboratories, West Point, PA, USA
Julie Chandler
Affiliation:
Department of Epidemiology, Merck Research Laboratories, West Point, PA, USA
*
*Corresponding author: Dr Marie-Hélène Gannagé-Yared, fax +961 1615295, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

In Middle-Eastern countries, more particularly in Lebanon, the incidence of vitamin D deficiency has been found to be surprisingly high in schoolchildren and young individuals. However, the prevalence and risk factors for vitamin D inadequacy amongst Lebanese osteoporotic women seeking medical health care has never been studied. We analysed vitamin D-inadequacy risk factors among the 251 Lebanese postmenopausal osteoporotic women (from both Muslim and Christian communities) who participated in a vitamin D international epidemiological study. Vitamin D inadequacy prevalence (25-hydroxyvitamin D (25(OH)D) < 30 ng/ml) was 84·9 %. 25(OH)D was negatively correlated with BMI (r − 0·41; P < 0·001) and positively correlated with educational level (r 0·37; P < 0·001) and self-reported general health (r 0·17; P < 0·01). No significant correlation was found with age and no seasonal variation was observed. There was no significant correlation between 25(OH)D and sun exposure index or vitamin D-rich food consumption. However, 25(OH)D strongly correlated with vitamin D supplement intake (r 0·48; P < 0·0001). Muslim community participants had lower 25(OH)D levels compared with their Christian counterparts (P < 0·001). They also had higher BMI, lower educational level and vitamin D supplement consumption and followed more frequently a dress code covering the arms (P < 0·0001 for all variables). In a multivariate model, in Muslims, inadequate vitamin D supplements and a dress code covering the arms are the independent predictors of 25(OH)D inadequacy (P < 0·001 for both variables). However, in Christians, the predictors are inadequate vitamin D supplements, high BMI and low educational level (P < 0·001; P = 0·002 and P = 0·02 respectively). There is an urgent need to increase vitamin D supplement use in Middle-Eastern osteoporotic women, more particularly in those from the Muslim community.

Type
Short Communication
Copyright
Copyright © The Authors 2008

Among factors contributing to bone health, satisfactory vitamin D status is of major importance(Reference Lips1, Reference Holick2). Both inadequate vitamin D intake and low sun exposure lead to vitamin D deficiency(Reference Lips1Reference Holick4). Fish being the only natural important dietary sources of vitamin D, all other dietary sources are in need of supplementation. Milk, some milk products and cereals are supplemented to different degrees depending on the country, with a much higher degree of fortification in the USA. On the other hand, season, latitude and time of the day, clothing and sunscreen, pigmentation of the skin and ageing are the main factors contributing to the cutaneous production of vitamin D(Reference Lips1).

Vitamin D inadequacy is a highly prevalent condition worldwide, more particularly in Europe and elsewhere(Reference Lips1, Reference van der Wielen, Lowik, van den Berg, de Groot, Haller, Moreiras and van Staveren5, Reference Scharla6). In Middle-Eastern countries, more particularly in Lebanon, several recent studies have shown a surprisingly high incidence of vitamin D deficiency in young individuals(Reference Gannagé-Yared, Chemali, Yaacoub and Halaby7) and schoolchildren(Reference El-Hajj Fuleihan, Nabulsi, Choucair, Salamoun, Hajj Shahine, Kizrian and Tannous8). Similar results were observed in Saudi Arabia(Reference Ghana, Handmaid, Bakheet and Khan9), Kuwait(Reference el-Sonbaty and Abdul-Ghaffar10) and Jordan(Reference Mishal11). Dress codes, culinary habits and a very hot sun enabling sun exposure account for these differences(Reference Lips1, Reference Gannagé-Yared, Chemali, Yaacoub and Halaby7).

Despite the fact that adequate vitamin D intake is considered an essential component of osteoporosis management(12), the prevalence of vitamin D inadequacy in osteoporotic women is very high; more than half of North American women have vitamin D inadequacy(Reference Holick, Siris, Binkley, Beard, Khan, Katzer, Petruschke, Chen and dePapp13). Moreover, in a recently published international study, vitamin D inadequacy affects 64 % of osteoporotic women worldwide(Reference Lips, Hosking, Lippuner, Norquist, Wehren, Maalouf, Ragi-Eis and Chandler14). In this latter study, Lebanon had the lowest regional 25-hydroxyvitamin D (25(OH)D) values; the major risk factors for vitamin D inadequacy were high BMI, inadequate vitamin D supplementation and poor self-reported health(Reference Rizzoli, Eisman, Norquist, Ljunggren, Krishnarajah, Lim and Chandler15).

The purpose of the present subanalysis is to study risk factors for vitamin D inadequacy in the Lebanese subgroup of the international population and to compare those risk factors in both Muslim and Christian communities.

Materials and methods

Participants

The present study is part of a cross-sectional survey performed at fifty-five sites in eighteen countries and including 2606 postmenopausal osteoporotic women. Participating countries represented a variety of latitudes and were grouped in five regions: Europe, Middle-East (Lebanon, Turkey), Asia, Latin America and Australia. In Lebanon (latitude 34°N), 251 participants were selected from three sites typical of medical out-patient practices treating postmenopausal women. Women were recruited either because they sought medical advice for osteoporosis or via the osteodensitometry centre of the sites. Two of the three sites were in two university hospitals of the Eastern part of Beirut (sixty-six and eighty-five participants respectively), and the third site was in a hospital centre of Saida, a south Lebanese town (100 participants). In the first two sites, all women were from the Christian community while in the third site, all women were Muslims. Recruitment was done during two periods, from July to August 2004 and from February to March 2005 covering respectively the winter and summer seasons of Lebanon. Inclusion criteria were female gender, age over 50 years, postmenopausal status for at least 2 years, and prevalent osteoporosis diagnosed according to the WHO criteria (bone mineral density T-score ≤ 2·5 at any site or a history of low-trauma non-pathological fragility fracture at any site after age of 45 years).

After providing informed consent, data collection was performed in each of the centres in a single visit. In every woman weight and height were measured. BMI was calculated as weight (kg)/height (m2). A survey including information regarding past medical history, prior and current medications for osteoporosis, use of vitamin D supplements and Ca was filled in. A dietary recall using a twenty-item questionnaire was done to evaluate the amount of intake of vitamin D-rich food (milk, fish and chicken liver). Information on sun exposure (time spent outside with or without sunscreen, body parts exposed to sun) was also collected. Sun exposure was calculated as number of hours spent outside without sun protection multiplied by percentage of the body exposed to sunlight (9 % for face, 1 % for each hand, 9 % for each arm, and 18 % for each leg). Body part exposure to sunlight (arms, face, hands, legs) corresponds to the answer yes/no to the question: ‘During the past month, when you spent time outside, which of the following body parts were usually exposed?’. Finally, the questionnaire included information on self-reported general health (poor, fair, good, very good, excellent) and level of education obtained (less than primary school, primary school, secondary school, university degree). A score was used for self-reported general health and educational level (score from 0 to 4 and from 0 to 3 respectively).

Laboratory studies

A single non-fasting blood sample was collected for the assessment of blood chemistry, serum 25(OH)D and intact parathyroid hormone. All tests of biological samples were performed in a single central laboratory (Quest Diagnostics Clinical Trials Laboratory, Van Nuys, CA, USA). 25(OH)D and parathyroid hormone were measured using two Nichols Advantage® two-site chemiluminescence assays (Nichols Institute Diagnostics, San Clemente, CA, USA). For 25(OH)D, the normal range is 10–68 ng/ml, with intra-assay CV 4 % and lower limit of sensitivity 7 ng/ml. For parathyroid hormone, the normal range is 10–65 pg/ml, with intra-assay CV < 7·5 % and lower limit of detection 2 pg/ml.

Statistical analysis

SPSS release 13 (SPSS, Inc., Chicago, IL, USA) was used to perform the statistical analysis. Because 25(OH)D is not normally distributed, a logarithmic transformation was used for its analysis (Ln25(OH)D). The Pearson coefficient was used for linear correlations between Ln25(OH)D and other variables. A multilinear regression analysis was performed separately in the two communities in order to look at the explanatory variables for 25(OH)D. This analysis was performed without logarithmic transformation in order to facilitate the interpretation of the β coefficients and because it gives similar P values compared with the regression with logarithmic transformation. Clinical and biological characteristics between communities were compared using Student's t test and where indicated the χ2 test. For all analysis, a P value < 0·05 was considered statistically significant.

Results

Participants' age varied between 50 and 87 years with a mean of 67·5 (sd 6·69) years (Table 1). Of the participants, 33·9 % had a history of fragility fractures and 71·9 % were treated by an anti-resorptive osteoporotic treatment (biphosphonates, hormone replacement therapy, raloxifene and/or calcitonine), of which 68·5 % by biphosphonates. A total of 48·6 % of the subjects reported a daily use of at least 10μg (400 IU) of vitamin D supplements; in 18·7 % this dose was less than 400 IU and 32·7 % did not take vitamin D supplements. A Ca supplement was taken by 62·9 % of our participants.

Table 1 Comparison between Christian and Muslim communities

(Mean values and standard deviations)

* P < 0·05, *** P < 0·001.

For milk, number of cups drunk daily. For fish and chicken liver, number of servings consumed during the past month.

Baseline 25-hydroxyvitamin D levels and their relationships to other parameters

The mean 25(OH)D levels in the whole population was 19·5 (sd 9·8) ng/ml (Table 1). Ln25(OH)D levels were negatively correlated with BMI (r − 0·41; P < 0·001) and positively correlated with educational level score (r 0·37; P < 0·001) and self-reported general health score (r 0·17; P = 0·007). No seasonal variation was observed (19·5 (sd 9·4) v. 19·6 (sd 10·3) ng/ml respectively for summer and winter; P = 0·90) and no significant correlation was found with sun exposure index (P = 0·26). Despite this fact, Ln25(OH)D was lower in women who followed a dress code covering the arms compared with the others (16·8 (sd 10) v. 22·2 (sd 9·7) ng/ml respectively; P < 0·0001) while the significance was borderline for the exposure of legs (P = 0·06). Finally, no significant correlation was found between Ln25(OH)D levels and the consumption of milk and of vitamin D-rich food (fish and chicken liver). However, Ln25(OH)D values strongly correlated with vitamin D supplement use (r 0·48; P < 0·0001).

Comparison between Muslim and Christian communities

No statistical difference in 25(OH)D levels was observed between the two Christian sites, so we compared both Christian sites with the Muslim site. 25(OH)D levels were significantly lower in Muslim women compared with Christians (P < 0·0001). Of the Muslim participants, 20 % had 25(OH)D levels below the detection limit of the kit compared with only 1·3 % of the Christians. Muslims had significantly higher BMI and lower educational level compared with their Christians counterparts. They also followed more commonly a dress code covering the arms (P < 0·0001 for all variables). No significant difference between the groups was found regarding self-reported general health. No seasonal variation in 25(OH)D levels was observed when the analysis was performed separately in Muslims and Christians. There was a significantly higher consumption of fish and chicken livers in Christian women compared with Muslim ones (P = 0·015). In a multivariate model, in Muslims, inadequate vitamin D supplementation and a dress code covering the arms were independent predictors of 25(OH)D inadequacy (P < 0·001 for both variables), while, in Christians, the predictors were inadequate vitamin D supplementation, high BMI and low educational level (P < 0·001, P = 0·002 and P = 0·02 respectively) (Table 2). We finally performed interaction tests comparing the results for Christian and Muslim women. The P value of the interaction factor was significant for BMI (P = 0·045) and for the exposure of arms to sunlight (P = 0·012) while there were no significant differences for educational level, self-reported general health and vitamin D supplements, suggesting that there was a statistically different effect of BMI and exposure of the arms to sunlight between the communities.

Table 2 Separate multilinear regression analyses with 25-hydroxyvitamin D as a dependent variable in Muslims and Christians

* Self-reported general health was evaluated by a score from 0 to 4 for the following: poor; fair; good; very good; excellent.

Educational level was evaluated by a score from 0 to 3 for the following: did not complete primary school; primary school; secondary school and university degree.

For no exposure of arms to sunlight, 0; for exposure of arms to sunlight, 1.

Discussion

The results of the present study show that in Lebanon, despite the sunny weather, there is a high degree of vitamin D inadequacy. Of the postmenopausal osteoporotic women studied, 85 % had serum 25(OH)D < 30 ng/ml v. 64 % worldwide(Reference Lips, Hosking, Lippuner, Norquist, Wehren, Maalouf, Ragi-Eis and Chandler14) and 54 % in the US population(Reference Holick, Siris, Binkley, Beard, Khan, Katzer, Petruschke, Chen and dePapp13), confirming results of previous studies in our young population(Reference Gannagé-Yared, Chemali, Yaacoub and Halaby7). These results were observed despite the fact that the study target individuals were seeking health care for osteoporosis, 71·9 % were taking anti-resorptive drugs and 67·3 % some vitamin D supplements.

Consistent with findings from the larger international study, inadequate vitamin D supplementation, high BMI and low educational levels were found to be the main risk factors for vitamin D inadequacy while season, sun exposure index and vitamin D-rich food consumption were not. Newly identified factors were a dress code covering the arms and belonging to a Muslim community.

Comparing the present results with those of the international study, we found in our population a lower educational level (66 % had a level of primary school or less v. 38·2 % in the international population) and higher BMI (mean 28·8 v. 25·1 kg/m2 in the international study). These two findings were observed in both our communities and can partly explain the higher prevalence of vitamin D inadequacy in Lebanon compared with other countries worldwide.

Interestingly, we found a huge prevalence of vitamin D deficiency in our Muslim community compared with the Christian one while 25(OH)D values in Christians were closer but still significantly lower than those of the international study (respectively 22 v. 26 ng/ml; P < 0·0001). The community difference we observed is probably multifactorial; in Muslims a much lesser vitamin D supplement use, a dress code covering the arms, higher BMI and lower educational level.

We then looked separately in each community at the main contributors to 25(OH)D deficiency. We found, in both communities, similarly to the international study, that the most significant contributor is inadequate vitamin D supplementation, while season and vitamin D provided by food have no impact. However, in Muslims, opposite to Christians, BMI had a minor impact, while exposure of the arms to sunlight is of major importance, suggesting that dress code in Muslims is crucial. The reason for the limited effect of BMI in Muslims is unclear and could be related to our overweight Muslim sample.

The lack of seasonal variation in 25(OH)D values is not surprising in Muslims where the area of skin exposed to the sun is limited, but is surprising in Christians who followed a Western style of dress code. A seasonal variation was observed in some countries of the international study such as the UK and Switzerland. It was also previously reported in Lebanese schoolchildren(Reference El-Hajj Fuleihan, Nabulsi, Choucair, Salamoun, Hajj Shahine, Kizrian and Tannous8), suggesting that, in our population, age may limit the effect of sun exposure on the cutaneous production of vitamin D.

In contrast to our previous study(Reference Gannagé-Yared, Chemali, Yaacoub and Halaby7) performed in young adults, vitamin D intake provided from food was not a risk factor in both communities. This could be explained by the fact that vitamin D supplements may mask the vitamin D contribution by food to vitamin D status. In Lebanon, the only vitamin D-rich foods are fish and supplemented milk, and, in the present study, the mean milk intake is of only half a cup daily, mainly due to the high prevalence of lactose intolerance in the Lebanese population(Reference Buller and Grand16).

The present results emphasise the importance of educational level in our overall population, more particularly in our Christian community, in contrast to the international population. This risk factor was also previously reported in Lebanese schoolchildren(Reference El-Hajj Fuleihan, Nabulsi, Choucair, Salamoun, Hajj Shahine, Kizrian and Tannous8). Other studies from the USA(Reference Harris, Soteriades, Coolidge, Mudgal and Dawson-Hughes17) and Italy(Reference Isaia, Giorgino, Rini, Bevilacqua, Maugeri and Adami18) found a high prevalence of 25(OH)D inadequacy in low-income elderly populations(Reference Harris, Soteriades, Coolidge, Mudgal and Dawson-Hughes17) and in osteoporotic women with lower educational level(Reference Isaia, Giorgino, Rini, Bevilacqua, Maugeri and Adami18). All these results suggest that educational level is not a common factor worldwide.

In conclusion, the high prevalence of vitamin D inadequacy found in the Lebanese subgroup of the international study was mainly observed in Muslim women. In this community, very low vitamin D supplementation and a dress code covering the arms are the main risk factors while BMI has a lesser impact, suggesting an urgent need to largely increase vitamin D supplement use in these women. It is not clear if similar differences between communities will be found in the younger generations of our population where educational level, and probably BMI, are quite equivalent. Further research is needed to elucidate this finding.

Acknowledgements

The present study was supported by Merck Research Laboratories and by the ‘Conseil de Recherche de l'Université Saint-Joseph’.

M.-H. G.-Y. was one of the primary investigators of the Lebanese subpopulation and wrote the manuscript. G. M. and Y. Y. were the two other primary investigators in Lebanon. S. K. contributed to the statistical analysis. S. C. performed the data collection. N. Z. was the co-investigator in one of the three sites. A. C. was the Lebanese Merck Sharp and Dohme representative for the study. J. C. and J. N. conducted the international study and contributed to the writing of the article. The paper was reviewed by all the co-authors. The authors declare no conflicts of interest.

References

1Lips, P (2001) Vitamin D deficiency and secondary hyperparathyroidism in the elderly: consequences for bone loss and fractures and therapeutic implications. Endocr Rev 22, 477501.CrossRefGoogle ScholarPubMed
2Holick, MF (2006) The role of vitamin D for bone health and fracture prevention. Curr Osteoporos Rep 4, 96102.CrossRefGoogle ScholarPubMed
3Holick, MF (2006) High prevalence of vitamin D inadequacy and implications for health. Mayo Clin Proc 81, 353373.CrossRefGoogle ScholarPubMed
4Holick, MF (2006) Resurrection of vitamin D deficiency and rickets. J Clin Invest 116, 20622072.CrossRefGoogle Scholar
5van der Wielen, RP, Lowik, MR, van den Berg, H, de Groot, LC, Haller, J, Moreiras, O & van Staveren, WA (1995) Serum vitamin D concentrations among elderly people in Europe. Lancet 346, 207210.CrossRefGoogle ScholarPubMed
6Scharla, SH (1998) Prevalence of subclinical vitamin D deficiency in different European countries. Osteoporos Int 8, Suppl. 2, S7S12.CrossRefGoogle ScholarPubMed
7Gannagé-Yared, MH, Chemali, R, Yaacoub, N & Halaby, G (2000) Hypovitaminosis D in a sunny country: relation to lifestyle and bone markers. J Bone Mine Res 15, 18561862.CrossRefGoogle Scholar
8El-Hajj Fuleihan, G, Nabulsi, M, Choucair, M, Salamoun, M, Hajj Shahine, C, Kizrian, A & Tannous, R (2001) Hypovitaminosis D in healthy schoolchildren. Pediatrics 107, E53.CrossRefGoogle ScholarPubMed
9Ghana, NN, Handmaid, MM, Bakheet, SM & Khan, BA (1999) Bone mineral density of the spine and femur in healthy Saudi females: relation to vitamin D status, pregnancy and lactation. Calcif Tissue Int 65, 2328.CrossRefGoogle Scholar
10el-Sonbaty, MR & Abdul-Ghaffar, NU (1996) Vitamin D deficiency in veiled Kuwaiti women. Eur J Clin Nutr 50, 315318.Google ScholarPubMed
11Mishal, AA (2001) Effects of different dress styles on vitamin D levels in healthy young Jordanian women. Osteoporos Int 12, 931935.CrossRefGoogle ScholarPubMed
12Anonymous 2008, National Osteoporossis Foundation. http//www.nof.org//physguide/risk_assessment.htm.Google Scholar
13Holick, MF, Siris, ES, Binkley, N, Beard, MK, Khan, A, Katzer, JT, Petruschke, RA, Chen, E & dePapp, AE (2005) Prevalence of vitamin D inadequacy among postmenopausal North American women receiving osteoporosis therapy. J Clin Endocrinol Metab 90, 32153224.CrossRefGoogle ScholarPubMed
14Lips, P, Hosking, D, Lippuner, K, Norquist, JM, Wehren, L, Maalouf, G, Ragi-Eis, S & Chandler, J (2006) The prevalence of vitamin D inadequacy amongst women with osteoporosis: an international epidemiological investigation. J Intern Med 260, 245254.CrossRefGoogle ScholarPubMed
15Rizzoli, R, Eisman, JA, Norquist, J, Ljunggren, O, Krishnarajah, G, Lim, SK & Chandler, J (2006) Risk factors for vitamin D inadequacy among women with osteoporosis: an international epidemiological study. Int J Clin Prac 60, 10131019.CrossRefGoogle ScholarPubMed
16Buller, HA & Grand, RJ (1990) Lactose intolerance. Ann Rev Med 41, 141148.CrossRefGoogle ScholarPubMed
17Harris, SS, Soteriades, E, Coolidge, JA, Mudgal, S & Dawson-Hughes, B (2000) Vitamin D insufficiency and hyperparathyroidism in a low income, multiracial, elderly population. J Clin Endocrinol Metab 85, 41254130.Google Scholar
18Isaia, G, Giorgino, R, Rini, GB, Bevilacqua, M, Maugeri, D & Adami, S (2003) Prevalence of hypovitaminosis D in elderly women in Italy: clinical consequences and risk factors. Osteoporos Int 14, 577582.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Comparison between Christian and Muslim communities(Mean values and standard deviations)

Figure 1

Table 2 Separate multilinear regression analyses with 25-hydroxyvitamin D as a dependent variable in Muslims and Christians