Vascular perfusion and hypoxic areas in RIF-1 tumours after photodynamic therapy

Geel, I. P. J. van; Oppelaar, Hugo; Rijken, P.F.J.W.; Bernsen, H.J.J.A.; Hagemeier, N.E.M.; Kogel, Albert J. van der; Hodgkiss, R.J.; Stewart, Fiona

doi:10.1038/bjc.1996.51

Cited by 53 publications

(31 citation statements)

References 21 publications

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“…Consistent with the above observations, no differences were found in tumour perfusion after high-or low-fluence-rate PDT. In both cases, tumour perfusion progressively decreased with time after treatment as has been described by others (Roberts et al, 1994;van Geel et al, 1994van Geel et al, , 1996. However, marked differences were found in cutaneous perfusion.…”

Section: Discussionsupporting

confidence: 81%

Reduction of tumour oxygenation during and after photodynamic therapy in vivo: effects of fluence rate

Sitnik

Hampton²,

Henderson³

1998

Br J Cancer

250

204

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Summary It has been proposed that the generation of 102 during photodynamic therapy (PDT) may lead to photochemical depletion of ambient tumour oxygen, thus causing acute hypoxia and limiting treatment effectiveness. We have studied the effects of fluence rate on P02, in the murine RIF tumour during and after PDT using 5 mg kg-' Photofrin and fluence rates of 30, 75 or 150 mW cm-2. Median P02 before PDT ranged from 2.9 to 5.2 mmHg in three treatment groups. Within the first minute of illumination, median tumour P02 decreased with all fluence rates to values between 0.7 and 1.1 mmHg. These effects were rapidly and completely reversible if illumination was interrupted. During prolonged illumination (20-50 J cm-2) P02 recovered at the 30 mW cm-2 fluence rate to a median value of 7.4 mmHg, but remained low at the 150 mW cm-2 fluence rate (median P02 1.7 mmHg). Fluence rate effects were not found after PDT, and at both 30 and 150 mW cm-2 median tumour P02 fell from control levels to 1.0-1.8 mmHg within 1-3 h after treatment conclusion. PDT with 100 J cm-2 at 30 mW cm-2 caused significantly (P= 0.0004) longer median tumour regrowth times than PDT at 150 mW cm-2, indicating that lower fluence rate can improve PDT response. Vascular perfusion studies uncovered significant fluence rate-dependent differences in the responses of the normal and tumour vasculature. These data establish a direct relationship between tumour P02, the fluence rate applied during PDT and treatment outcome. The findings are of immediate clinical relevance.

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Section: Discussionsupporting

confidence: 81%

Reduction of tumour oxygenation during and after photodynamic therapy in vivo: effects of fluence rate

Sitnik

Hampton²,

Henderson³

1998

Br J Cancer

250

204

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“…Numerous reports have shown that PDT induces microvascular damage within treated tumors (3 -5) and that this leads to tumor hypoxia (4,11). Because hypoxia induces increased expression and stabilization of HIF-1a and activates the HIF-1 transcription factor, recent molecular studies have thus far investigated the effects of PDTinduced hypoxia on expression of proangiogenic factors and their relevance to treatment efficacy.…”

Section: Discussionmentioning

confidence: 99%

“…The oxygen levels gradually decreased due to PDT-induced photochemical oxygen consumption. However, the oxygen concentration in the medium surrounding the cells remained high throughout 4 http://rsb.info.nih.gov/ij/ the treatment fluence of 2.5 J cm À2 and never decreased below 90% of the air-saturated level. These experiments thus confirmed that transient hypoxia was not induced under these PDT irradiation conditions.…”

Section: Cell Linesmentioning

confidence: 99%

“…Briefly, the digitized images were analyzed using ImageJ (NIH) 4 and MATLAB (The MathWorks, Inc., Natick, MA). Quantifying the extent of GFP expression in these samples required various image processing and analysis steps.…”

Section: Cell Linesmentioning

confidence: 99%

“…Various immune responses to PDT have also been described (2, 6 -8). The therapy-induced decrease in blood flow leads to strong and persistent tumor tissue hypoxia (4). Further, because the PDT photochemistry consumes oxygen, oxygen consumption during the therapy can also create rapid and severe transient tissue hypoxia (9 -11).…”

Section: Introductionmentioning

confidence: 99%

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Photodynamic therapy mediates the oxygen-independent activation of hypoxia-inducible factor 1α

Mitra¹,

Cassar²,

Niles

et al. 2006

Molecular Cancer Therapeutics

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Photodynamic therapy (PDT) induces the expression of the hypoxia-inducible factor 1A (HIF-1A) subunit of the HIF-1 transcription factor and its target genes in vitro and in vivo. PDT also induces the expression of the enzyme cyclooxygenase-2 and its metabolite, prostaglandin E 2 (PGE 2 ). PGE 2 and hypoxia act independently and synergistically to increase HIF-1A accumulation and nuclear translocation. To examine the expression of HIF-1 target genes in response to PDT-mediated oxidative stress and PGE 2 under normoxic conditions, we established EMT6 cells transfected with a plasmid consisting of a hypoxia response element promoter and a downstream gene encoding for green fluorescent protein (GFP). To examine the temporal kinetics of HIF-1A nuclear translocation in response to PDT, we transfected a second line of EMT6 cells with a GFP-tagged HIF-1A fusion vector. Cell monolayers were incubated with 1 Mg mL À1 Photofrin for 24 h and irradiated with fluences of 1, 2.5, and 5 J cm À2 . Direct measurement of oxygen concentration during irradiation confirmed that cells remained well oxygenated. Cells were also exposed to 1 and 10 Mmol/L PGE 2 for 3 h. In normoxic conditions, Photofrin, PDT, and PGE 2 treatment activated HIF-1A and induced its nuclear translocation. Maximal Photofrin-PDT -mediated HIF-1A activation was intermediate in magnitude between that induced by PGE 2 and that by the hypoxia mimic cobalt chloride. This work establishes that PDT induces significant activation of the HIF-1A pathway in the absence of hypoxia and supports the interpretation that the induction of HIF-1 target genes by PDT may be mediated, at least in part, by the prostaglandin pathway.

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Oxygen Effects in Photodynamic Therapy

Juzeniene

2012

Handbook of Biophotonics

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The sections in this article are Introduction The Role of Oxygen in Photodynamic Therapy: 1 O 2 Generation Dependence of the Photosensitizing Effect on O 2 Concentration The Oxygenation Status in Tumors and Normal Tissues PDT ‐Induced Reduction of Tumor Oxygenation O 2 Consumption (Primary Reduction) Vascular Damage (Secondary Reactions) Photosensitizer Photobleaching (Secondary Reactions) Methods to Reduce Tumor Deoxygenation During PDT Low Fluence Rates Fractionated Light Exposure Other Methods Changes of Quantum Yields Related to Photosensitizer Relocalization Changes of Optical Penetration Caused by Changes in O 2 Concentration Conclusion

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Vascular perfusion and hypoxic areas in RIF-1 tumours after photodynamic therapy

Cited by 53 publications

References 21 publications

Reduction of tumour oxygenation during and after photodynamic therapy in vivo: effects of fluence rate

Reduction of tumour oxygenation during and after photodynamic therapy in vivo: effects of fluence rate

Photodynamic therapy mediates the oxygen-independent activation of hypoxia-inducible factor 1α

Oxygen Effects in Photodynamic Therapy

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