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Those low on vitamin D get the most sunbed benefit – April 2013

Increase in serum 25-hydroxyvitamin-D3 in humans after sunbed exposures compared to previtamin D3 synthesis in vitro.

J Photochem Photobiol B. 2013 Mar 28;122C:32-36. doi: 10.1016/j.jphotobiol.2013.03.006. Orlova T, Moan J, Lagunova Z, Aksnes L, Terenetskaya I, Juzeniene A.
Department of Optical Quantum Electronics, Institute of Physics, National Academy of Sciences of Ukraine, 03680 Kiev, Ukraine. Electronic address: orlovat at iop.kiev.ua.

Ultraviolet (UV) radiation is liable to cause skin cancer but it is the main source of vitamin D. Vitamin D photosynthesis takes place in skin at sub-erythemogenic UV doses, while larger exposures destroy vitamin D and increase DNA damage. Proper UV dosimetry is needed to obtain an optimal vitamin D status when skin cancer risk is minimal. A simple approach to such dosimetry using physically measured accumulated UV dose cannot provide a satisfactory quantification of vitamin D because of the complexity of the processes involved in vitamin D synthesis. A biological dosimeter of vitamin D synthetic UV radiation ('D-dosimeter') has been introduced earlier on the basis of an in vitro model of previtamin D photosynthesis. In the present study in vivo generation of 25-hydroxyvitamin D (25(OH)D) in serum of healthy volunteers exposed to UV radiation from the sunbed was accompanied by in vitro measurements of vitamin D formation using 'D-dosimeter'. It was found that the increase in serum 25(OH)D concentration depended both on the initial 25(OH)D level and on the cumulative sunbed exposure time. The observed linear correlation between in vivo and in vitro data can be used to estimate changes in vitamin D status after UV exposure using only one pre-exposure blood sample combined with further in vitro measurements.

Copyright © 2013 Elsevier B.V. All rights reserved.

PMID: 23591142

Fig. 1.

Image
The UV irradiance spectra from top (1) and bottom (2)
sunbed parts and solar spectrum in Oslo (3)
combined to CIE action spectra of erythema (4)
and previtamin D synthesis in vivo (5)
and with action spectrum of previtamin D formation in vitro (6).


Fig. 2. Similar spectra to the sun

Image
Initial spectrum of 7-DHC in ethanol solution (C = 2.4 × 10−5 mol/L) and its spectral transformations as a result of 2-h sunlight exposure in Oslo (UVA radiant exposure is 3.9 × 105 J/m2 and UVB radiant exposure is 10.2 × 103 J/m2) and 2-h sunbed irradiation (UVA radiant exposure is 15.3 × 105 J/m2 and UVB radiant exposure is 9.4 × 103 J/m2).


Fig. 4. Those with lowest vitamin D level gained the most (a ==> b)

Image
Number of participants with insufficient (25–50 nmol/L),
marginal (50–75 nmol/L) and
sufficient (75–150 nmol/L) levels of 25(OH)D before (a) and after (b) all 20 sunbed exposures.



Fig. 5.

Image
Box plots of 25(OH)D distributions before and after all sunbed exposures for three volunteer groups: boxes represent interquartile range around median (also depicted), whiskers show 1.5 interquartile ranges above and below the boxes, stars indicate outliers outside the whiskers.


Sorry about the fuzzy figures.
That was all that was available for free.
The good figures and full text would cost >$30 and could not be shared on the internet

It is well known that it takes more Vitamin D/UV to raise the level as the level is higher

see wiki page: http://www.vitamindwiki.com/tiki-index.php?page_id=1425

See also VitaminDWiki

Attached files

ID Name Comment Uploaded Size Downloads
2376 Sunbed 1.jpg admin 18 Apr, 2013 22.09 Kb 1919
2375 Sunbed 2.jpg admin 18 Apr, 2013 13.67 Kb 1840
2374 Sunbed 4.jpg admin 18 Apr, 2013 13.07 Kb 1559
2373 Sunbed 5.jpg admin 18 Apr, 2013 23.34 Kb 1800