Background: Sunscreen products aim to help protect the skin against UV radiation and consequently reduce the risk of early skin ageing and skin cancer. However, it is well known that some sunscreen ingredients are not photostable, but this usually refers to irradiation with UV light. Moreover, it has to be mentioned that a relative cumulative erythema effectiveness compliant light source is used for the in vivo sun protection factor (SPF) testing. Here, UV simulators equipped with a xenon arc lamp use filters such as WG320 and UG11 (thickness 1 mm) to minimize infrared (IR) radiation and wavelength below 300 nm. However, under practical conditions, the sunscreen product is not only exposed to UVA/B light, but also to visible light (VIS) and IR light. In fact, the spectrum of solar radiation is composed of approximately 7% UV, 39% VIS and 54% IR. Aims: To investigate the influence of short-wave and long-wave radiation on the photostability of sunscreens. Methods: Irradiation was performed with the Suntest CPS+ that is considered to closely imitate solar radiation. The filter UG11 (thickness 1 mm), which absorbs much of the VIS and IR light, and the glass filter WG320 (thickness 2 mm), which effectively absorbs radiation of wavelengths less than 300 nm, were used in the Suntest CPS+ both individually and in combination and were inserted between the light source and the samples. The following transmission measurements were carried out with Labsphere’s UV-2000s device. Here, the effectiveness (percentage change of SPF before irradiation to SPF after irradiation) as a measure of the photostability was calculated. Results: As expected after total solar spectrum irradiation, the effectiveness in all tested sunscreens is lower compared to relative cumulative erythema effectiveness light used for in vitro testing of SPF. In the reference sunscreen formula S2 as well as in the two different sunscreen products, especially long-wave radiation (>400 nm) had an effect on photostability, whereas short-wave radiation had only a minor impact. In contrast, in the BASF sun care gel line only short-wave radiation below 300 nm had an effect on photostability, and blocking VIS and IR light had no effect at all. Conclusion: Based on these data, we can conclude that short waves and/or VIS + IR light have an influence on the photostability of sunscreens.

1.
Moyal
D
.
Prevention of ultraviolet-induced skin pigmentation
.
Photodermatol Photoimmunol Photomed
.
2004
Oct
;
20
(
5
):
243
7
.
[PubMed]
0905-4383
2.
Dahle
J
,
Kvam
E
.
Induction of delayed mutations and chromosomal instability in fibroblasts after UVA-, UVB-, and X-radiation
.
Cancer Res
.
2003
Apr
;
63
(
7
):
1464
9
.
[PubMed]
0008-5472
3.
Marrot
L
,
Jones
C
,
Perez
P
,
Meunier
JR
.
The significance of Nrf2 pathway in (photo)-oxidative stress response in melanocytes and keratinocytes of the human epidermis
.
Pigment Cell Melanoma Res
.
2008
Feb
;
21
(
1
):
79
88
.
[PubMed]
1755-1471
4.
Hughes
MC
,
Williams
GM
,
Baker
P
,
Green
AC
.
Sunscreen and prevention of skin aging: a randomized trial
.
Ann Intern Med
.
2013
Jun
;
158
(
11
):
781
90
.
[PubMed]
0003-4819
5.
Green
AC
,
McBride
P
.
Squamous cell carcinoma of the skin (non-metastatic)
.
BMJ Clin Evid
;
2010
.
6.
van der Pols
JC
,
Williams
GM
,
Pandeya
N
,
Logan
V
,
Green
AC
.
Prolonged prevention of squamous cell carcinoma of the skin by regular sunscreen use
.
Cancer Epidemiol Biomarkers Prev
.
2006
Dec
;
15
(
12
):
2546
8
.
[PubMed]
1055-9965
7.
Herzog
B
,
Wehrle
M
,
Quass
K
.
Photostability of UV absorber systems in sunscreens
.
Photochem Photobiol
.
2009
Jul-Aug
;
85
(
4
):
869
78
.
[PubMed]
0031-8655
8.
Berset
G
,
Gonzenbach
H
,
Christ
R
,
Martin
R
,
Deflandre
A
,
Mascotto
RE
, et al
Proposed protocol for determination of photostability Part I: cosmetic UV filters
.
Int J Cosmet Sci
.
1996
Aug
;
18
(
4
):
167
77
.
[PubMed]
0142-5463
9.
Armstrong
RB
,
Whitman
GB
,
Gasparro
FP
,
Leach
EE
.
Potential hazards in phototherapy with ultraviolet radiation arising from variation in dose required to produce erythema
.
J Am Acad Dermatol
.
1985
Nov
;
13
(
5 Pt 1
):
772
7
.
[PubMed]
0190-9622
10.
Tarras-Wahlberg
N
,
Stenhagen
G
,
Larkö
O
,
Rosén
A
,
Wennberg
AM
,
Wennerström
O
.
Changes in ultraviolet absorption of sunscreens after ultraviolet irradiation
.
J Invest Dermatol
.
1999
Oct
;
113
(
4
):
547
53
.
[PubMed]
0022-202X
11.
Vanquerp
V
,
Rodriguez
C
,
Coiffard
C
,
Coiffard
LJ
,
De Roeck-Holtzhauer
Y
.
High-performance liquid chromatographic method for the comparison of the photostability of five sunscreen agents
.
J Chromatogr A
.
1999
Feb
;
832
(
1-2
):
273
7
.
[PubMed]
0021-9673
12.
Cosmetics
I
: Sun protection factor test methods - In vivo determination of SPF (Sun Protection Factor).
13.
Kochevar
IE
,
Pathak
MA
, A. PJ: Photophysics, photochemistry, and phobiology.
1999
.
14.
Quistorf
JC
,
Kockott
D
,
Garbe
B
,
Heinrich
U
,
Tronnier
H
,
Braun
N
.
Development of an in vitro Test Procedure to Determine the Direct Infrared A Protection of Sunscreens and Non-Cosmetic Samples
.
Skin Pharmacol Physiol
.
2017
;
30
(
4
):
171
9
.
[PubMed]
1660-5527
15.
Wabnik
M
,
Kockott
D
,
Garbe
B
,
Theek
C
,
Heinrich
U
,
Tronnier
H
, et al
Application of an Easy-to-Perform High-Energy and Low-End Visible Light Transmittance Method and the Influence of Tinted Sunscreens on High-Energy/Low-End Visible Light Transmittance and Infrared Protection
.
Skin Pharmacol Physiol
.
2019
;
32
(
5
):
244
53
.
[PubMed]
1660-5527
16.
Meinke
MC
,
Syring
F
,
Schanzer
S
,
Haag
SF
,
Graf
R
,
Loch
M
, et al
Radical protection by differently composed creams in the UV/VIS and IR spectral ranges
.
Photochem Photobiol
.
2013
Sep-Oct
;
89
(
5
):
1079
84
.
[PubMed]
0031-8655
17.
Souza
C
,
Maia Campos
P
,
Schanzer
S
,
Albrecht
S
,
Lohan
SB
,
Lademann
J
, et al
Radical-Scavenging Activity of a Sunscreen Enriched by Antioxidants Providing Protection in the Whole Solar Spectral Range
.
Skin Pharmacol Physiol
.
2017
;
30
(
2
):
81
9
.
[PubMed]
1660-5527
18.
Fitzpatrick
TB
.
The validity and practicality of sun-reactive skin types I through VI
.
Arch Dermatol
.
1988
Jun
;
124
(
6
):
869
71
.
[PubMed]
0003-987X
19.
Miura
Y
,
Takiguchi
Y
,
Shirao
M
,
Takata
S
,
Yanagida
T
,
Fukui
H
, et al
Algorithm for in vitro Sun Protection Factor based on transmission spectrum measurement with concomitant evaluation of photostability
.
Photochem Photobiol
.
2008
Nov-Dec
;
84
(
6
):
1569
75
.
[PubMed]
0031-8655
20.
Tronnier
H
,
Hölzner
U
,
Heinrich
U
,
Kockott
D
,
Reubke-Gother
B
.
Bewertung von Sonnenschutzmitteln Kosmetische Medizin
.
1998
;
18
:
344
50
.
21.
Stanfield
J
.
Optimizing in vitro measurements of sunscreen protection
.
SÖFW J
.
2006
;
132
:
19
23
.
22.
Stanfield
J
.
Spectroscopic measurements of sunscreen protection
.
Expert Rev Dermatol
.
2011
;
6
(
5
):
475
8
. 1746-9872
23.
Couteau
C
,
Faure
A
,
Fortin
J
,
Paparis
E
,
Coiffard
LJ
.
Study of the photostability of 18 sunscreens in creams by measuring the SPF in vitro
.
J Pharm Biomed Anal
.
2007
May
;
44
(
1
):
270
3
.
[PubMed]
0731-7085
24.
Lhiaubet-Vallet
V
,
Marin
M
,
Jimenez
O
,
Gorchs
O
,
Trullas
C
,
Miranda
MA
.
Filter-filter interactions. Photostabilization, triplet quenching and reactivity with singlet oxygen
.
Photochem Photobiol Sci
.
2010
Apr
;
9
(
4
):
552
8
.
[PubMed]
1474-905X
25.
Gaspar
LR
,
Maia Campos
PM
.
Evaluation of the photostability of different UV filter combinations in a sunscreen
.
Int J Pharm
.
2006
Jan
;
307
(
2
):
123
8
.
[PubMed]
0378-5173
26.
Huong
SP
,
Rocher
E
,
Fourneron
JD
,
Charles
L
,
Monnier
V
,
Bun
H
, et al
Photoreactivity of the sunscreen butylmethoxydibenzoylmethane (DBM) under various experimental conditions
.
J Photochem Photobiol Chem
.
2008
;
196
(
1
):
106
12
. 1010-6030
27.
Miura
Y
,
Suzuki
S
,
Hirao
T
,
Hatao
M
.
Light source spectrum strongly influences the in vitro estimation of sun protection factor
.
Photochem Photobiol
.
2012
Jul-Aug
;
88
(
4
):
1005
11
.
[PubMed]
0031-8655
28.
Perugini
P
,
Vettor
M
,
Tursilli
R
,
Scalia
S
,
Genta
I
,
Modena
T
, et al
Technological strategies to improve photostability of a sunscreen agent
.
Int J Cosmet Sci
.
2006
;
28
(
2
):
148
9
. 0142-5463
29.
Rohr
M
,
Ernst
N
,
Schrader
A
.
Hybrid Diffuse Reflectance Spectroscopy: Non-Erythemal in vivo Testing of Sun Protection Factor
.
Skin Pharmacol Physiol
.
2018
;
31
(
4
):
220
8
.
[PubMed]
1660-5527
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