The use of PDT for endometrial ablation has been the focus of much recent research. However, the mechanism of action, optimal treatment parameters, and long-term clinical effect are still poorly understood. This study was undertaken to further the understanding of the endometrial response to this drug/light- induced damage. Postpartum rat (Charles River) uterine horns were used as the animal model for fluorescence and treatment studies. Aminolevulinic acid was administered topically (intrauterine), and following a 0.5- to 3-hour drug incubation time, the endometrium was either removed and processed for fluorescence microscopy to assess drug localization or exposed to 150-200 J/cm2 of 630-nm laser light via a 1-cm cylindrical diffusing tip. The light=treated uterine horns were removed and histologically examine 7 to 10 days following treatment. The extent and character of uterine and endometrial damage (gross and histological analysis) were recorded for the varying light doses and incubation times. With topical (intrauterine) application of photosensitizer, incubation time and penetration ability of drug were found to be crucial factors. The use of a drug penetration enhancing vehicle produced greater tissue effects (endometrial ablation). These preliminary studies also showed that tissue effect is drug and light dose related and that the most profound effects may be vascular mediated. The study provided preliminary information for the use of PDT in gynecological applications such as endometrial ablation and female sterilization through Fallopian tube occlusion.
[1]
B. Mclucas.
Endometrial ablation with the roller ball electrode.
,
1990,
The Journal of reproductive medicine.
[2]
P A Cowled,et al.
Ablation of endometriotic implants in rabbits by hematoporphyrin derivative photoradiation therapy using the gold vapor laser
,
1990,
Lasers in surgery and medicine.
[3]
J. Kennedy,et al.
INTRAUTERINE 5‐AMINOLEVULINIC ACID INDUCES SELECTIVE FLUORESCENCE AND PHOTODYNAMIC ABLATION OF THE RAT ENDOMETRIUM *
,
1993,
Photochemistry and photobiology.
[4]
J C Kennedy,et al.
Endogenous protoporphyrin IX, a clinically useful photosensitizer for photodynamic therapy.
,
1992,
Journal of photochemistry and photobiology. B, Biology.
[5]
J H Phipps,et al.
Experimental and clinical studies with radiofrequency-induced thermal endometrial ablation for functional menorrhagia.
,
1990,
Obstetrics and gynecology.
[6]
Bent Ae,et al.
Endometrial ablation with the neodymium:Yag laser.
,
1990
.
[7]
A Singer,et al.
The endometrial ablator: a new instrument.
,
1994,
Obstetrics and gynecology.