Photodynamic therapy effect of m-THPC (Foscan®) in vivo: correlation with pharmacokinetics

Jones, Helen M.F.; Vernon, David I.; Brown, Stanley B.

doi:10.1038/sj.bjc.6601101

Cited by 81 publications

(77 citation statements)

References 31 publications

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“…The initial rapid elimination phase, representing the distribution of the photosensitiser to the various organs was followed by a second phase representing drug elimination. The two half-lives are similar to those for the clearance of m-THPC (Cramers et al, 2003;Jones et al, 2003). At the start of the second phase (about 24 h after administration), the serum concentration is approximately 30-fold lower than in tumour tissue, so from this time onwards, there is unlikely to be a significant PDT effect on blood components under the conditions required for tumour necrosis.…”

Section: Discussionmentioning

confidence: 50%

Enhanced photodynamic destruction of a transplantable fibrosarcoma using photochemical internalisation of gelonin

et al. 2005

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Photochemical internalisation (PCI) is a technique for releasing biologically active macromolecules from endocytic vesicles by light activation of a photosensitiser localised in the same vesicles of targeted cells. This study investigated the PCI of the toxin gelonin as a way of enhancing the effect of photodynamic therapy (PDT) on a human malignant fibrous histiocytoma transplanted into nude mice using the photosensitiser disulphonated aluminium phthalocyanine (AlPcS 2a ). Pharmacokinetic studies after intraperitoneal administration showed that the serum level of AlPcS 2a fitted a biexponential model (half-lives of 1.8 and 26.7 h). The tumour concentration was roughly constant up to 48 h, although fluorescence microscopy showed that the drug location was initially mainly vascular, but became intracellular by 48 h. To compare PDT with PCI, 48 h after intraperitoneal injection of 10 mg kg À1 AlPcS 2a , and 6 h after direct intratumour injection of 50 mg gelonin (PCI) or a similar volume of phosphate-buffered saline (PDT controls), tumourbearing animals were exposed to red light (150 J cm À2 ). Complete response was observed for more than 100 days in 50% of the PCI tumours but only 10% of the PDT tumours (Po0.01). In tumours examined histologically 4 days after light delivery, the depth of necrosis was 3 -4 mm after PDT, but 7 mm after PCI. The deeper effect after PCI demonstrates that the light fluence needed to kill tumour is less than with PDT. We conclude that PCI with gelonin can markedly enhance the effect of PDT on this type of tumour and may have a role clinically as an adjunct to surgery to control localised disease.

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Section: Discussionmentioning

confidence: 50%

Enhanced photodynamic destruction of a transplantable fibrosarcoma using photochemical internalisation of gelonin

et al. 2005

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“…This suggests that illumination in clinical PDT should be done at highest plasma levels, targeting the vasculature more than the tumor cell directly. In another study, m-THPC-PDT had two peaks of activity: an early effect on tumor vasculature synchronous to the plasma peak level followed by a late direct effect at maximum tumor accumulation (9). After having determined the tumor and tissue peaks in the feline species, our next step will be to compare the PDT outcome of the cats treated to date with cats treated optimally (i.e., at the time of highest liposomal m-THPC tumor accumulation versus cats treated at the time of the plasma peak).…”

Section: Patientmentioning

confidence: 99%

“…A longer drug-light interval results in maximal concentration of the photosensitizer in the tumor, causing direct tumor cell destruction. This was shown recently for the secondgeneration photosensitizer meta-(tetrahydroxyphenyl)chlorin [m-THPC (Foscan)] and indicates that the in vivo effects occur via an indirect vascular effect as well as a more direct effect at different drug-light intervals (9,10).…”

mentioning

confidence: 99%

Optimizing Photodynamic Therapy:In vivoPharmacokinetics of Liposomalmeta-(Tetrahydroxyphenyl)Chlorin in Feline Squamous Cell Carcinoma

Buchholz

Kaser‐Hotz²,

Khan

et al. 2005

Clinical Cancer Research

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Purpose: The aim of the present study was to optimize and simplify photodynamic therapy using a new liposomal formulation of the photosensitizer meta-(tetrahydroxyphenyl)chlorin [m-THPC (Foscan); liposomal m-THPC (Fospeg)] and to reduce systemic reactions to the photosensitizer. Experimental Design:To examine the pharmacokinetics of liposomal m-THPC, we determined tissue and plasma variables in feline patients with spontaneous squamous cell carcinoma. In vivo fluorescence intensity measurements of tumor and skin were done with a fiber spectrophotometer after i.v. injection of m-THPC or liposomal m-THPC in 10 cats. Blood samples, drawn at several time points after photosensitizer administration, were analyzed by high-performance liquid chromatography. The first reports on photodynamic therapy (PDT) date back to the beginning of the last century, when researchers observed that a combination of light with hematoporphyrin induces cell death (1). In 1995, the U.S. Food and Drug Administration approved PDT as a novel form of therapy against cancer, and since then, PDT has been used more frequently.PDT includes two components combined to induce cellular and tissue effects in an oxygen-dependent manner. The first is a ''light-sensitive'' substance called the photosensitizer. The second is light of a specific wavelength (laser light) to maximally activate the tumor-localized photosensitizer. On activation, a photosensitizer undergoes type I (electron or hydrogen transfer) or type II (local generation of cytotoxic singlet oxygen) photochemical reactions.Tumor destruction associated with PDT involves three principal mechanisms (2): (a) direct tumor cell kill (3), (b) destruction of tumor-associated vasculature (4 -6), and (c) activation of an immune response against tumor cells (7,8). A short drug-light interval allows the photosensitizer to accumulate predominantly in the vascular compartment. PDTmediated vascular effects range from transient vascular spasm, vascular stasis, and thrombus formation to total permanent vessel occlusion and can include enhanced vascular leakiness (5). A longer drug-light interval results in maximal concentration of the photosensitizer in the tumor, causing direct tumor cell destruction. This was shown recently for the secondgeneration photosensitizer meta-(tetrahydroxyphenyl)chlorin [m-THPC (Foscan)] and indicates that the in vivo effects occur via an indirect vascular effect as well as a more direct effect at different drug-light intervals (9, 10).To optimize PDT, liposomes are presently being tested as carrier and delivery systems with the aim of improving the tumoritropic behavior of photosensitizers.

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“…A successful example was Foscan (Tetra-meso hydroxyphenyl chlorin, Figure 2F), which is a powerful intra-cellular photosensitizer. Its high photodynamic efficiency has been explained by the photooxidation of intracellular targets, because the quantum yields of singlet oxygen production is comparable or inferior to other relevant photosensitizers [36,37]. The intracellular generation of protoporphyrin IX by administration of its metabolic precursors (ALA), was another successful example that helped to expand the applications of PDT ( Figure 2E).…”

Section: Mechanisms and Drug Development In Pdtmentioning

confidence: 99%

Photodynamic Therapy in the Treatment of Osteomyelitis

Tardivo¹,

Baptista²

2012

Osteomyelitis

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Photodynamic therapy effect of m-THPC (Foscan®) in vivo: correlation with pharmacokinetics

Cited by 81 publications

References 31 publications

Enhanced photodynamic destruction of a transplantable fibrosarcoma using photochemical internalisation of gelonin

Enhanced photodynamic destruction of a transplantable fibrosarcoma using photochemical internalisation of gelonin

Optimizing Photodynamic Therapy:In vivoPharmacokinetics of Liposomalmeta-(Tetrahydroxyphenyl)Chlorin in Feline Squamous Cell Carcinoma

Photodynamic Therapy in the Treatment of Osteomyelitis

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