Ex vivo Application of δ‐Aminolevulinic Acid Induces High and Specific Porphyrin Levels in Human Skin Tumors: Possible Basis for Selective Photodynamic Therapy

Fritsch, Clemens; Batz, Janine; Bolsen, K.; Schulte, K.-W.; Zumdick, Matthias; Ruzicka, Thomas; Goerz, G

doi:10.1111/j.1751-1097.1997.tb03146.x

Cited by 29 publications

(25 citation statements)

References 34 publications

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“…The increase of tissue pO 2 in tumour and surrounding tissue during the irradiation break can be explained by a reduced cellular respiration break by functioning oxygen supply. This assumption is supported by the fact that ALA is primarily metabolised to porphyrins in the tumour parenchyma (Fritsch et al, 1997). Therefore, direct tumour cell toxicity by PDT with ALA is expected.…”

Section: Ala -Pdt Following Different Dosimetric Protocols P Babilas mentioning

confidence: 95%

“…The only experimental difference is the use of an argon-pumped dye laser tuned to 635 nm for irradiation, while in the present investigation an incoherent light source (l ¼ 580 -740 nm) was employed. Since significant amounts of additional porphyrins, besides PpIX, are formed in this model following systemic application of ALA (Fritsch et al, 1997) absorbing beyond 635 nm; the wavelength range of the incoherent light source covers their absorption spectrum, thus leading to a more pronounced photodynamic effect.…”

Section: Ala -Pdt Following Different Dosimetric Protocols P Babilas mentioning

confidence: 99%

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Effects of light fractionation and different fluence rates on photodynamic therapy with 5-aminolaevulinic acid in vivo

et al. 2003

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To improve efficacy of photodynamic therapy (PDT) with intravenously administered 5-aminolaevulinic acid (ALA) fractionating the light dose or reducing the light intensity may be a possibility. Therefore, Syrian Golden hamsters were fitted with dorsal skinfold chambers containing an amelanotic melanoma (n ¼ 26). PDT was performed (100 mW cm À2 , 100 J cm À2 , continuously or fractionated, and 25 mW cm À2 , 100 J cm À2 ; continuously or fractionated) using an incoherent light source following i.v. application of ALA. Following fractionated irradiation, the light was paused after 20 J cm À2 for 15 min. Prior to and up to 24 h after PDT tissue, pO 2 was measured using luminescence lifetime imaging. The efficacy was evaluated by measuring the tumour volume of amelanotic melanoma cells grown subcutaneously in the back of Syrian Golden hamsters (n ¼ 36). Only high-dose PDT resulted in a significant decrease of pO 2 . Irrespective of the mode of irradiation only high-dose PDT induced complete remission of all tumours (13 out of 13). It could be shown that low-dose PDT failed to induce a significant decrease of pO 2 . No significant effect of fractionated irradiation was shown regarding the therapeutic efficacy 28 days after PDT. Thus performing a fractionated PDT with ALA or reducing the light intensity seems not to be successful in clinical PDT according to the present data.

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Section: Ala -Pdt Following Different Dosimetric Protocols P Babilas mentioning

confidence: 95%

Section: Ala -Pdt Following Different Dosimetric Protocols P Babilas mentioning

confidence: 99%

Effects of light fractionation and different fluence rates on photodynamic therapy with 5-aminolaevulinic acid in vivo

et al. 2003

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“…It is worthy of note that the explant culture system has been a useful and simple tool for testing ex-vivo the ability of organs to synthesize PpIX from ALA (Fukuda et al, 1989;Fritsch et al, 1997). Using floating explant cultures, the drugs are absorbed through the dermis to reach the epidermis, resembling the systemic pathway of drug delivery.…”

Section: Discussionmentioning

confidence: 99%

“…The mechanism of ALA transport in human cells is not yet clear, but it has been well characterized in yeast (Bermudez Moretti et al, 1995). It would therefore be of interest to know whether ALA derivatives diffuse passively across the plasma membrane or have other active transport mechanisms similar or different from ALA.At present it is not clear which enzymes might be involved in the liberation of ALA although in the case of compounds 3 and 4 and the methyl and hexyl esters it is likely that non-specific esterases are implicated and, in the case of compounds 5, 6 and 7 it may be that proteases are responsible for the release.It is worthy of note that the explant culture system has been a useful and simple tool for testing ex-vivo the ability of organs to synthesize PpIX from ALA (Fukuda et al, 1989;Fritsch et al, 1997). Using floating explant cultures, the drugs are absorbed through the dermis to reach the epidermis, resembling the systemic pathway of drug delivery.…”

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confidence: 99%

Comparative effect of ALA derivatives on protoporphyrin IX production in human and rat skin organ cultures

et al. 1999

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Summary Samples of human and rat skin in short-term organ culture exposed to ALA or a range of hydrophobic derivatives were examined for their effect on the accumulation of protoporphyrin IX (PpIX) measured using fluorescence spectroscopy. With the exception of carbobenzoyloxy-D-phenylalanyl-5-ALA-ethyl ester the data presented indicate that, in normal tissues, ALA derivatives generate protoporphyrin IX more slowly than ALA, suggesting that they are less rapidly taken up and/or converted to free ALA. However, the resultant depot effect may lead to the enhanced accumulation of porphyrin over long exposure periods, particularly in the case of ALA-methyl ester or ALA-hexyl ester, depending on the applied concentration and the exposed tissue. Addition of the iron chelator, CP94, greatly increased PpIX accumulation in human skin exposed to ALA, ALA-methyl ester and ALA-hexyl ester. The effect in rat skin was less marked.Keywords: ALA; PDT; ALA derivatives; ALA esters; iron chelators; CP94 1525British Journal of Cancer (1999) 80(10), 1525-1532 © 1999 Cancer Research Campaign Article no. bjoc.1999 Received 9 October 1998 Revised 4 February 1999 Accepted 11 February 1999 Correspondence to: PA Riley Hider et al (1982) and was kindly donated by the Department of Pharmacy. King's College, London and used in a concentration of 100 µg ml -1 (equivalent to 0.6 mM). Synthesis of ALA derivativesNovel ALA derivatives are depicted in Figure 1, and were synthesized as follows.ALA-He was prepared according to the method of Takeya (1992) by reacting ALA with hexanol in the presence of thionyl chloride giving the compound as the hydrochloride (HCl) salt.ALA1-4 were synthesized according to the method of Tanaka et al (1993). The benzyl ester of ALA was prepared by reacting ALA with benzyl alcohol in the presence of thionyl chloride. This was then reacted with the appropriate freshly distilled acid chloride (N-butanoyl, N-pentanoyl, N-hexanoyl or N-heptanoyl chloride) in pyridine. The benzyl ester was removed by hydrogenation using 10% palladium on activated charcoal as a catalyst.ALA5-7 were prepared by reacting a Z-protected amino acid with an ester of ALA using N-cyclohexyl-3,2-morpholinoethyl carbodiimide metho p-toluene sulphonate in DCM as a coupling agent.ALA8 was prepared by reacting N-phthalimidolaevulinic acid with glucosamine tetraacetate using the same coupling agent as for ALA5-7. N-phthalimidolaevulinic acid was prepared using a method adapted from Iida et al (1998). Tetrahydrofurfuryl chloride was reacted with potassium phthalimide for 3 h (cf. the original method in which tetrahydrofurfuryl bromide was reacted for 1 h) giving N-tetrahydrofurfuryl phthalimide. N-phthalimidolaevulinic acid (ALA11) was obtained by oxidation using sodium metaperiodate and ruthenium (III) chloride n-hydrate in aqueous acetonitrile and 1,1,2-trichloro-1,2,2-trifluoroethane, a safer substitute for carbon tetrachloride. Glucosamine tetraacetate was prepared using the four-step procedure of Bergmann and Zervas (1932). The amine of glucos...

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“…According to our clinical experience, BCC and SCC reveal a strong, homogeneous, ALA-induced porphyrin fluorescence under Wood's light ( Figure 1A) (Fritsch et al, 1996a(Fritsch et al, , 1997b, whereas about 20-40% of psoriatic lesions show areas with inhomogeneous or absent fluorescence ( Figure 1B). For better comparison of intralesional porphyrin formation in PS and tumours, we selected only uniform fluorescing psoriatic areas for our study.…”

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confidence: 99%

Optimum porphyrin accumulation in epithelial skin tumours and psoriatic lesions after topical application of δ-aminolaevulinic acid

et al. 1999

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Photodynamic therapy with topically applied δ-aminolaevulinic acid is used to treat skin tumours by employing endogenously formed porphyrins as photosensitizers. This study examines the time course of porphyrin metabolite formation after topical application of δ-aminolaevulinic acid. Porphyrin biosynthesis in human skin tumours (basal cell carcinoma, squamous cell carcinoma), in psoriatic lesions, and in normal skin was investigated. Skin areas were treated with δ-aminolaevulinic acid, and levels of total porphyrins, porphyrin metabolites and proteins were measured in samples excised after 1, 2, 4, 6, 9, 12 and 24 h. There was an increase in porphyrin biosynthesis in all tissues with maximum porphyrin levels in tumours between 2 and 6 h and in psoriatic lesions 6 h after treatment. The pattern of porphyrins showed no significant difference between normal and neoplastic skin, protoporphyrin being the predominant metabolite. The results suggest that optimum irradiation time for superficial epithelial skin tumours may be as soon as 2 h after application of δ-aminolaevulinic acid, whereas for treatment of psoriatic lesions an application time of 6 h is more suitable. © 1999 Cancer Research Campaign

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Ex vivo Application of δ‐Aminolevulinic Acid Induces High and Specific Porphyrin Levels in Human Skin Tumors: Possible Basis for Selective Photodynamic Therapy

Cited by 29 publications

References 34 publications

Effects of light fractionation and different fluence rates on photodynamic therapy with 5-aminolaevulinic acid in vivo

Effects of light fractionation and different fluence rates on photodynamic therapy with 5-aminolaevulinic acid in vivo

Comparative effect of ALA derivatives on protoporphyrin IX production in human and rat skin organ cultures

Optimum porphyrin accumulation in epithelial skin tumours and psoriatic lesions after topical application of δ-aminolaevulinic acid

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