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UC Irvine Previously Published Works

Title
Combined benzoporphyrin derivative monoacid ring photodynamic therapy and pulsed dye 
laser for port wine stain birthmarks.

Permalink
https://escholarship.org/uc/item/1p49t236

Journal
Photodiagnosis and photodynamic therapy, 6(3-4)

ISSN
1572-1000

Authors
Tournas, Joshua A
Lai, Jennifer
Truitt, Anne
et al.

Publication Date
2009-09-01

DOI
10.1016/j.pdpdt.2009.10.002

License
https://creativecommons.org/licenses/by/4.0/ 4.0
 
Peer reviewed

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Combined Benzoporphyrin Derivative Monoacid Ring A
Photodynamic Therapy and Pulsed Dye Laser for Port Wine Stain
Birthmarks

Joshua A. Tournas, M.D.1,2, Jennifer Lai, M.D.1,3, Anne Truitt, M.D.1,2, Y.C. Huang, Ph.D.1,
Kathryn E. Osann, Ph.D.6, Bernard Choi, Ph.D.1,4,5, and Kristen M. Kelly, M.D.1,2,4
1Beckman Laser Institute, University of California, Irvine, CA
2Department of Dermatology, University of California, Irvine, CA
3Keck School of Medicine, University of Southern California, Los Angeles, CA
4Department of Surgery, University of California, Irvine, CA
5Department of Biomedical Engineering, University of California, Irvine, CA
6Department of Medicine, University of California, Irvine, CA

Abstract
Background—Pulsed dye laser (PDL) is a commonly utilized treatment for port wine stain
birthmarks (PWS) in the United States; however, results are variable and few patients achieve
complete removal. Photodynamic therapy (PDT) is commonly used in China, but treatment
associated photosensitivity lasts several weeks and scarring may occur. We propose an alternative
treatment option, combined PDT+PDL and performed a proof-of-concept preliminary clinical trial.

Methods—Subjects with non-facial PWS were studied. Each subject had four test sites: control,
PDL alone, PDT alone (benzoporphyrin derivative monoacid ring A photosensitizer with 576 nm
light), and PDT+PDL. Radiant exposure time for PDT was increased in increments of 15 J/cm2.
Authors evaluated photographs and chromametric measurements before and 12 weeks post-
treatment.

Results—No serious adverse events were reported; epidermal changes were mild and self-limited.
No clinical blanching was noted in control or PDT-alone sites. At PDT radiant exposures of 15 and
30 J/cm2, equivalent purpura and blanching was observed at PDL and PDT+PDL sites. At PDT
radiant exposures over 30 J/cm2, greater purpura was noted at PDT+PDL sites as compared to PDL
alone. Starting at 75 J/cm2, improved blanching was noted at PDT+PDL sites.

Conclusions—Preliminary results indicate that PDT+PDL is safe and may offer improved PWS
treatment efficacy. Additional studies are warranted.

© 2009 Elsevier B.V. All rights reserved.
Corresponding Author: Kristen M. Kelly, M.D., 1002 Health Sciences Road East, Irvine, CA 92612, Telephone: (949) 824-7997, Fax:
(949) 824-2726, KMKelly@uci.edu.
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NIH Public Access
Author Manuscript
Photodiagnosis Photodyn Ther. Author manuscript; available in PMC 2010 November 12.

Published in final edited form as:
Photodiagnosis Photodyn Ther. 2009 ; 6(3-4): 195–199. doi:10.1016/j.pdpdt.2009.10.002.

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Keywords
Port wine stain birthmarks; pulsed dye laser; photodynamic therapy; vascular birthmarks

INTRODUCTION
Port wine stain birthmarks (PWS) are congenital, progressive vascular malformations of the
skin which are present at birth in 0.3% of infants, are commonly found on the face and in many
cases disfigure the bearer. The pulsed dye laser (PDL) is the current standard of care for
treatment of such cutaneous vascular lesions. The PDL enables lesion lightening by causing
selective photothermal injury to tissue vasculature. Yellow light (λ = 577–600 nm wavelength)
emitted by the pulsed dye laser is preferentially absorbed by hemoglobin (the major blood
chromophore) in the ectatic capillaries of the upper dermis. Radiant energy is converted to
heat, causing thermal damage and thrombosis in targeted vessels(1).

However, with PDL alone, few patients (< 10%) achieve complete blanching of their lesion,
and multiple treatments (5–30 or more) are generally required. In a five-year study of 640 PWS
patients at Bridgend General Hospital, Lanigan et al. concluded that the degree of fading
achieved following PDL therapy is “variable and often unpredictable”(2). Huikeshoven et al.
(3) published a 10-year follow-up study of 51 patients who had undergone PDL treatment for
PWS birthmarks. They reported significant re-darkening of PWS since an initial course of PDL
therapy (although PWS remained significantly lighter as compared to pre-treatment).

Because of the limitations of PDL PWS therapy, the search continues for other safe and more
effective treatment modalities. Photodynamic therapy (PDT) may offer such an alternative.
PDT utilizes a photosensitizer and light to generate reactive oxygen species and creates an
opportunity for targeted lesion destruction. PDT has been used to treat a wide range of benign,
pre-malignant and malignant conditions, including age-related macular degeneration(4),
actinic keratoses(5) and cancers of the skin, lung and gastrointestinal tract(6).

PDT may offer several advantages for treatment of cutaneous vascular lesions. However,
careful protocol design is required because the potential exists for complete vascular network
destruction, which can result in necrosis, ulceration, and subsequent scarring. A small number
of studies have been conducted using PDT as a stand-alone treatment of PWS, with varied
success and safety outcomes. Collectively, the use of PDT to treat PWS has been associated
with promising blanching, but also with prolonged photosensitivity and a significant risk of
complications(7),(8)

Careful photosensitizer and light source selection is required to achieve desired efficacy during
PDT treatment of PWS, while limiting injury to vessels at the desired depth. In this study, we
propose the use of benzoporphyrin derivative monoacid ring A (BPD) and yellow light for
PDT. BPD is an excellent photosensitizer for PWS treatment based on the following
characteristics: 1) vascular predominance(9),(10),(11); 2) proven safety and efficacy in humans
(4),(12) and 3) photosensitivity of relatively short duration (1–5 days depending on dose
administered)(12).

We have proposed combining the photochemical and photothermal aspects of PDT and PDL
therapy(9),(13). Combining these approaches allows the use of lower radiant exposures for
each portion of the procedure, avoiding adverse effects such as scarring, while providing
enhanced vascular shutdown. Our preliminary animal experiments(9;13) demonstrated that
PDT+PDL combination therapy can achieve enhanced vascular effect without epidermal injury
and may address limitations associated with the current standard of care treatment, PDL alone.

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We report observations from a proof-of-concept, tolerance and safety dose ranging study
designed to evaluate and compare PDL alone, PDT alone and PDT+PDL for PWS treatment.
This is the first published report evaluating clinical use of the PDT+PDL approach.

MATERIALS AND METHODS
The Institutional Review Board at the University of California, Irvine approved the research
protocol. Patients 18 or older with non-facial PWS were recruited. Exclusion criteria included
history of allergy to study medication, history of photosensitizing conditions such as the
porphyrias, use of photosensitizing or blood-thinning medications, active infections, and recent
laser treatment of PWS.

Eight patients were enrolled. Three patients underwent two separate sets of treatment, for a
total of 11 sets of treatment sites. Subject’s ages ranged from 19 to 53 and 7 of 8 patients were
female. Fitzpatrick skin types were II or III. Lesions were located on the trunk and extremities.

For each subject, four circular test sites with a 2-cm diameter were delineated on the day of
treatment. Sites were documented with digital photography and chromameter (Minolta Inc.)
measurements were taken. Site #1 served as a control and received no treatment. Site #2 was
treated with PDL alone (585 nm, 7 mm spot, 8 J/cm2 radiant exposure, 30 ms cryogen spurt
with a 20 ms delay). Sites #3 and #4 were treated with PDT alone and PDT+PDL, respectively.

After use of the PDL on site #2, patients received liposomal BPD-MA (verteporfin; Visudyne;
QLT, Inc. Vancouver, Canada) by intravenous infusion. Drug administration procedures in the
verteporfin package insert were followed. Each 15 mg vial of medication was reconstituted
with 7 ml sterile water, providing 7.5 ml of a 2 mg/ml solution of verteporfin. The reconstituted
verteporfin was protected from light and used within four hours of preparation. The volume of
reconstituted verteporfin required to achieve a dose of 6 mg/m2 body surface area (calculation
based on weight and height as provided in drug package information) was withdrawn and
diluted with 5% dextrose for a total infusion volume of 30 ml. The full infusion volume was
administered mechanically over a 10-min period at a rate of 3 ml/min using a syringe pump
and in-line filter.

Irradiation of the PDT test site was initiated 15 min after the start of the 10-min BPD infusion
with an argon pumped dye laser (Lumenis Inc., Santa Clara, CA) tuned to 576 nm with an
output irradiance of 100 mW/cm2. To study effectiveness and safety of PDT at different light
doses, total CW radiant exposure administered was steadily increased over the course of the
study by increasing total time of laser exposure. Two subjects each received a CW radiant
exposure of 15, 30, 45, 60, and 75 J/cm2, and one subject received a radiant exposure of 90 J/
cm2.

For the combined PDT+PDL test site, PDT was performed as described in the preceding
paragraph. This was followed immediately by PDL irradiation at the same parameters as the
PDL alone test site.

Subjects returned for follow-up visits at 1 and 3 days; and 1, 2, 4, 8 and 12 weeks post
intervention. At each visit, documentation of PWS appearance was obtained by visual
inspection, digital photography and chromometer measurements. Patients were questioned
regarding adverse effects. Pre- and 12-week post treatment measurements of erythema( a*),
were compared for the various treatment groups using repeated measures analysis of variance.

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RESULTS
Safety and Tolerability

Treatments were well tolerated with most subjects reporting no discomfort during PDT (only
subject 1 reported mild temporary discomfort) and mild discomfort during PDL therapy. No
subjects reported increased discomfort during PDT+PDL as compared to PDL alone.

No serious adverse events were reported. One patient experienced extravasation at the i.v. site
(antecubital fossa of arm) and required photoprotection of this area for several weeks. This
patient received a repeat treatment without incident, six weeks later. Epidermal changes were
limited to fine scabbing and temporary mild hyperpigmentation at PDL-treated sites, which
resolved without treatment. Other adverse effects were reported, but were not thought to be
related to treatment. One subject experienced viral symptoms three days post-treatment
including fever, chills and nasal congestion. Other family members were similarly affected. A
second subject developed a crust at the PDT+PDL site four weeks post-intervention. The
subject reported that similar crusting had happened before, sometimes related to trauma. This
complication resolved without treatment or sequelae. A third subject reported an asthma flare
two weeks post-treatment. This subject has a long history of significant asthma.

Visual Assessment of Blanching Response
No changes were observed at control sites. We also did not observe any PWS blanching at
PDT alone sites.

Clinical assessments of PDL alone versus PDT+PDL test sites are summarized in Table 1. At
PDT radiant exposures of 15 and 30 J/cm2, blanching was similar at the PDL and PDT+PDL
sites. Starting at a PDT radiant exposure of 30 J/cm2, a greater amount of purpura was noted
at the PDT+PDL site as compared to the PDL alone site (Figure 1). Starting at a PDT radiant
exposure of 75 J/cm2, improved efficacy was noted at the PDT+PDL site (Figure 2). Near
complete blanching was achieved in one of the subjects who received a light dose of 75 J/
cm2.

Chromametric Measurements
Chromometer measurement of a* values pre-treatment were compared to those measured at
12 weeks post-treatment. The a* value is a measurement of color on the red-green scale, with
higher a* values indicating increasing redness. The average change in a* over the 12 week
study period for each of the test sites was as follows: Control 0.48; PDT alone −0.14; PDL
alone −2.67; PDT+PDL −3.22. Repeated measures analysis of variance of a* values for control
as compared to other test sites revealed statistical significance for the PDL alone group (p = 0.
03) and the PDT+PDL group (p = 0.05). Comparisons between the different intervention sites
were not statistically significant.

DISCUSSION
Several important observations were made during this dose ranging study. First, PDT alone
and PDT+PDL therapy, using BPD and the selected light parameters, did not demonstrate any
major adverse effects. Epidermal changes were limited to fine scabbing in areas treated with
the PDL and temporary mild hyperpigmentation in the same areas, all of which resolved
without treatment. Similar hyperpigmentation is frequently seen with PDL alone treatment and
is generally well tolerated by patients. Prior studies utilizing blue light and red light PDT for
PWS treatment have resulted in skin necrosis and ulceration, possibly due to utilization of high
light intensities or selection of longer wavelengths. PWS lightening was achieved with PDT

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+PDL without adverse effects using a vascular specific photosensitizer (BPD), lower irradiance
(100 mW/cm2) and PDT light doses up to 90 J/cm2.

Photosensitizers previously utilized for PDT vascular lesion treatment have resulted in severe
photosensitivity of two weeks or more. BPD administration results in a photosensitivity period
in humans of 5 days or less. We did carefully counsel subjects regarding photosensitivity
precautions and subjects left our center wearing protective clothing. However, several subjects
drove after treatment from our center in Southern California to their homes (an hour or more
away) without sequelae. Further, no photosensitive reactions were reported, except for the one
subject in whom extravasation occurred. As noted above, she reported mild stinging in the area
of extravasation, but covering of the area prevented any further cutaneous effects.

Second, improved efficacy of PDT+PDL over PDL alone was observed and was dose-
dependent. Increased purpura was noted by the investigators in the PDT+PDL sites of subjects
who received PDT radiant exposures equal to or greater than 30 J/cm2. We also noted increased
blanching of the PDT+PDL sites over PDL sites in subjects that received PDT light doses of
75 or 90 J/cm2.

Interestingly, our studies did not find significant improvement of PDT alone as compared to
control sites. We expect that higher light or drug doses will be required in order to achieve
desired effects with PDT alone. This is undesirable because of time considerations (with the
current protocol, dose of 90 J/cm2 requires 15 min of irradiation) and financial considerations
(cost of photosensitizer). Further studies will be required to better elucidate dosing
requirements for PDT alone (using BPD and yellow light) for treatment of PWS.

This study builds on findings from our earlier in vivo animal studies demonstrating the potential
of the PDT+PDL combination intervention to achieve significant vascular effect. Our current
pilot human study provides evidence that PDT+PDL may offer enhanced blanching effect for
removal of PWS. We did note that dosing effects noted in animal models were not directly
transferable to clinical studies. As such, dose ranging studies such as the current one will be
required as protocol adjustments are made.

With additional study of the PDT+PDL treatment protocol, we envision that parameters could
be ultimately adjusted based on individual lesion characteristics. Longer wavelengths may be
useful for treatment of thicker lesions such as blebbed port wine stain, hemangiomas and other
vascular malformations.

In conclusion, in this preliminary report, PDT+PDL was shown to be a potentially efficacious
option for treatment of PWS and no long term adverse effects were noted. PDT alone did not
result in PWS blanching. Further prospective, comparative, and controlled multi-center clinical
studies are required to further develop the PDT+PDL protocol which may offer enhanced
efficacy as compared to current standard of care treatment with PDL alone. We are continuing
evaluations with the rodent dorsal skin fold window chamber to evaluate the use of alternative
light sources and determine methods to safely and effectively irradiate larger treatment areas
in a single session. Once our protocol is optimized further, we intend to expand our pilot study
into a phase II randomized, clinical trial study testing the effectiveness of PDT+PDL. It is our
belief that this protocol may offer an alternative treatment option for PWS birthmarks and may
offer a safe and more consistent blanching effect. This protocol may also be adapted for
treatment of other cutaneous vascular lesions including malignancies and hemangiomas.

Acknowledgments
This work was supported in part by grants obtained from the National Institutes of Health (AR51443 to KMK), Sturge
Weber Foundation (KMK), Arnold and Mabel Beckman Foundation and the A. Ward Ford foundation (BC).

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Institutional support was provided by the National Institutes of Health Laser Microbeam and Medical Program
(LAMMP). This investigation was also supported by the US Public Health Service research grant M01 RR00827 from
the National Center for Research Resources, University of California, Irvine. BPD and administration kits were
generously provided by QLT (Vancouver, BC, Canada). We thank Drs. Wim Verkruysse, Sol Kimel and Lars Svaasand
for their advice and assistance.

References
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of port-wine stains 10 years after pulsed-dye-laser treatment. N Engl J Med 2007;356(12):1235–1240.
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4. Sickenberg M. Verteporfin therapy for choroidal neovascularization: from concept to proof of efficacy.
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therapy of actinic keratoses with topical 5-aminolevulinic acid (ALA): a pilot dose-ranging study.
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6. Marcus, SL. Lasers in photodynamic therapy. In: Waynant, RW., editor. Lasers in Medicine. Boca
Raton: CRC Press; 2002. p. 287-324.

7. Gu Y, Huang NY, Liang J, Pan YM, Liu FG. Clinical study of 1949 cases of port wine stains treated
with vascular photodynamic therapy (Gu's PDT). Ann Dermatol Venereol 2007;134(3 Pt 1):241–244.
[PubMed: 17389848]

8. Qin ZP, Li KL, Ren L, Liu XJ. Photodynamic therapy of port wine stains – a report of 238 cases.
Photodiag Photodyn Ther 2007;4:53–59.

9. Smith T, Choi B, Ramirez-San-Juan J, Nelson JS, Osann K, Kelly KM. Microvascular blood flow
dynamics associated with photodynamic therapy, pulsed dye laser irradiation and combined regimens.
Lasers Surg Med 2006;38:532–539. [PubMed: 16615132]

10. Fingar VH, Kik PK, Haydon PS, Cerrito PB, Tseng M, Abang E, et al. Analysis of acute vascular
damage after photodynamic therapy using benzoporphyrin derivative (BPD). Br J Cancer
1999;79:1702–1708. [PubMed: 10206280]

11. Tsoukas MM, Gonzales S, Flotte TJ, Anderson RR, Sherwood ME, Kollias N. Wavelength and fluence
effect on vascular damage with photodynamic therapy on skin. J Invest Dermatol 2000;114:303–
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12. Houle JM, Strong A. Duration of skin photosensitivity and incidence of photosensitivity reactions
after administration of verteporfin. Retina 2002;22:691–697. [PubMed: 12476093]

13. Kelly KM, Kimel S, Smith T, Stacy A, Hammer-Wilson M, Svassand LO, et al. Combined
photodynamic and photothermal induced injury enhances damage to in vivo model. Lasers Surg Med
2004;34:407–413. [PubMed: 15216534]

14. Huang YC, Ringold TL, Nelson JS, Choi B. Noninvasive blood flow imaging for real-time feedback
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Figure 1.
Increased post-treatment purpura noted one week post PDT+PDL treatment as compared to
PDL alone therapy (PDT radiant exposure = 45 J/cm2).

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Figure 2.
PDL site (test site 2) (top left) prior to and (top right) 12 weeks post-intervention. PDT+PDL
(test site 4) (bottom left) prior to and (bottom right) 12 weeks post-intervention. The PDL
therapy site remained unchanged in color and size. In contrast, the PDT+PDL treatment site
decreased in area by ~50% and some areas of the PWS resolved completely. No changes were
noted in control and PDT alone sites.

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Tournas et al. Page 9

Table 1

Summary of Treatment Observations by Investigator
PDT Radiant Exposure (J/cm2) Subject # Investigator Observations – PDL alone versus PDT

+PDL

15 1 0/2 : Difference in purpura
2 0/2 : Difference in blanching

30 3 2/2 : Increased purupura PDT+PDL
4 0/2 : Difference in blanching

45 5 2/2 : Increased purpura PDT+PDL
6 1/2 : Equal blanching

1/2 : Improved blanching PDT+PDL

60 7 2/2 : Increased purpura PDT+PDL
8 0/2 : Difference in blanching

75 9 2/2 : Increased purpura PDT+PDL
10 2/2 : Improved blanching PDT+PDL

90 11 1/1 : Increased purpura PDT+PDL
1/1 : Improved blanching PDT+PDL

Photodiagnosis Photodyn Ther. Author manuscript; available in PMC 2010 November 12.