Deciphering PDT-induced inflammatory responses using real-time FDG-PET in a mouse tumour model.

Dynamic positron emission tomography (PET), combined with constant infusion of 2-deoxy-2-[(18)F]fluoro-d-glucose (FDG), enables real-time monitoring of transient metabolic changes in vivo, which can serve to understand the underlying physiology. Here we investigated characteristic changes in the tumour FDG-uptake profiles in relation to acute localized inflammatory responses induced by photodynamic therapy (PDT). Dynamic PET imaging with constant FDG infusion was used with EMT-6 tumour bearing mice. FDG time-activity uptake curves were measured simultaneously, in treated and reference tumours, for 3 hours, before, during and after PDT light treatment. Inflammation was studied when evoked, either by PDT using a trisulfonated porphyrazine photosensitizer, or lipopolysaccharide (LPS), and inhibited using indomethacin. The distinct transient patterns, characterized by drops and subsequent recovery of tumour FDG uptake rates, were also analysed using immunohistochemical markers for apoptosis, necrosis, and inflammation. Typical profiles for tumour FDG-uptake, consisted of a drop during PDT, followed by a gradual recovery period. Tumours treated with LPS, but not with light, showed a continuous increase in FDG-uptake during the 3 h experimental period. Treatment with indomethacin, inhibited the rise in FDG-uptake observed with either LPS or PDT. Tumour FDG-uptake profiles correlated with necrosis markers during PDT, and inflammatory response markers post-PDT, but not with an apoptosis marker at any time during or after PDT. Dynamic FDG-PET imaging combined with indomethacin reveals that, the drop in the tumour FDG-uptake rate during the PDT illumination phase reflects vascular collapse and necrosis, while the increased tumour FDG-uptake rate immediately post-illumination involves an acute localized inflammatory response. Dynamic FDG infusion and PET imaging, combined with the use of selective inhibitors, provides unique insight for deciphering the complex underlying processes leading to tumour response in PDT, and allows for rapid as well as cost effective optimization of PDT protocols.

Predicting efficacy of photodynamic therapy by real-time FDG-PET in a mouse tumour model.

Dynamic positron emission tomography (PET) combined with the constant infusion of 2-deoxy-2-[(18)F]fluoro-D-glucose (FDG) as a tracer permits real-time monitoring of systemic transient metabolic changes resulting from photodynamic therapy (PDT) in tumour bearing animals. The effect of PDT on tumour FDG uptake rates was evaluated using four different sulfonated phthalocyanine analogs as photosensitizers (PS) in combination with either continuous or fractionated illumination protocols. Mice bearing two EMT-6 tumours were infused with FDG to start PDT 30 min later. Dynamic images were acquired to produce FDG uptake over time for the treated and reference tumours. Practically all PDT protocols induced a reduction in the FDG uptake rates in the treated tumour during PDT, except for the zinc tetrasulfophthalocyanine, when using fractionated light, reflecting the low photodynamic efficacy of this PS. In general, the response to PDT was characterized by a rebound in the FDG uptake rate after illumination. A strong drop in FDG tumour uptake rates during PDT, followed by a strong rebound, together with short delay-to-response times, corresponded to optimal long-term tumour response outcomes. This dynamic FDG-PET protocol provides real-time observations to predict long-term PDT efficacy, while using fewer animals than conventional methods, thus making possible the rapid optimization of treatment parameters.

Structure-activity relationships of mono-substituted trisulfonated porphyrazines for the photodynamic therapy (PDT) of cancer.

The impact of lipophilicity on biological parameters critical to photodynamic efficacy was analyzed for a new generation of trisulfobenzo(mononaphtho)porphyrazines. The porphyrazines were substituted on the naphtho ring with linear alkynyl side chains of various lengths. When compared to the analogous phthalocyanine structures, the added benzo ring in the porphyrazine structures increased the lipophilicity for analogs with short alkynyl chains, while this effect disappeared for analogs with longer side chains. In aqueous media, the analogous phthalocyanine series showed aggregation tendencies. In contrast, no correlation between aggregate formation and the length of the alkynyl side chain was evident in the porphyrazine series. At low concentrations, the length of the side chain did not affect cell uptake, while phototoxicity towards EMT-6 mouse tumour cells showed a parabolic relationship, where the hexynyl derivative showed the highest activity. The trisulfonated porphyrazines localized at intracellular organelles, plasma and perinuclear membranes, but could not be found in the nucleus. Total cell uptake of dye did not correlate with phototoxicity, suggesting that localization in certain intracellular organelles, and distribution into critical intracellular sites are important determinants of their photodynamic activity. The hexynyl trisulfonated zinc porphyrazine derivative (ZnNPcS(3)C(6)) showed the strongest in vitro photodynamic activity and therefore was further studied in an EMT-6 mouse tumour model. An i.v. dose of 1 micromol of ZnNPS(3)C(6) per kg, followed 24 h later by activation with light, induced 100% tumour necrosis within 24 h post-PDT. This treatment delayed tumour volume doubling time from 5 days to >2 weeks, and gave 41% tumour cure >3 weeks post-PDT. Applying the same light dose fractionated (5 min on, 2 min off), further improved tumour response, leading to a doubling time of 26 days and a 73% tumour cure. At the administered 1 micromol kg(-1) dye dose, no skin phototoxicity was observed and >90% blood clearance was observed within 5 h post-injection. Compared to the analogous trisulfo monohexynyl zinc phthalocyanine, the new trisulfobenzo(mononaphthohexynyl)porphyrazine provided a broader range of excitation wavelengths, and improved photodynamic potency, while apparently being free of unwanted systemic side effects.

Early upregulation of kinin B1 receptors in retinal microvessels of the streptozotocin-diabetic rat.

(1) Retinal microvessel responses to kinin B1 and B2 receptor agonists and antagonists were investigated in streptozotocin (STZ)-diabetic rats and age-matched controls. In addition, quantitative in vitro autoradiography was performed on retinas from control and STZ-diabetic rats with radioligands specific for B2 ([125I]HPP-Hoe 140), and B1 receptors ([125I]HPP-[des-Arg10]-Hoe 140). (2) In control rats, the B2 receptor agonist bradykinin (BK, 0.1-50 nm) vasodilated retinal vessels in a concentration and time-dependent manner. This effect was completely blocked by the B2 receptor antagonist Hoe140 (1 microm). In contrast, the B1 receptor agonist des-Arg9-BK (0.1-50 nm) was without effect. (3) Des-Arg9-BK was able to produce a concentration-dependent vasodilatation as early as 4 days after STZ injection, and the effect of 1 nm des-Arg9-BK was inhibited by the B1 receptor antagonist des-Arg10-Hoe140 (1 microm). Low-level B1 receptor binding sites were detected in control rats, but densities were 256% higher in retinas from 4- to 21-day STZ-diabetic rats. (4) In control rats, the vasodilatation in response to 1 nm BK involved neither calcium influx nor nitric oxide (NO) as GdCl3 and l-NAME were without effect. However, the vasodilatation did involve intracellular calcium mobilization as well as products of the cyclooxygenase-2 (COX-2) pathway as 2,5-di-t-butylhydroquinone (BHQ), cADP ribose and l-745 337 inhibited this response. The vasodilatation response was blocked by trans-2-phenyl cyclopropylamine (TPC) demonstrating that prostacyclins mediate this response. (5) In STZ-diabetic rats, the vasodilatation in response to des-Arg9-BK involved both calcium influx and intracellular calcium mobilization from stores both IP3 sensitive and non-IP3 sensitive. Indeed, the effect was blocked by GdCl3, BHQ and cADP ribose. Furthermore, NO production and products of the COX-2 pathway including prostacyclin are involved as the response was inhibited by l-NAME, l-745 377 and TPC. (6) Vasodilatation in response to either 1 nm BK or 1 nm des-Arg9-BK were blocked by NF023 demonstrating that a Go/Gi G-protein transduces both these effects. (7) This is the first report on the retinal circulation which provides evidence for vasodilator B2 receptors and the upregulation of B1 receptors very early following induction of diabetes with STZ rats. These results suggest that kinin receptors may be potential targets for therapeutics to treat retinopathies.

Trisulfonated porphyrazines: new photosensitizers for the treatment of retinal and subretinal edema.

A new series of water-soluble, mononaphthotrisulfobenzoporphyrazines, bearing an alkynyl side chain of varying lengths on the naphtho ring, were prepared and tested for their efficacy to inhibit plasma extravasation when used as photosensitizers during photodynamic therapy (PDT) of the retina in the rat. The hexynyl substituted photosensitizer was the most potent, and was able to produce complete inhibition, at low doses of photosensitizer and light.

Mechanisms which mediate the antiapoptotic effects of angiopoietin-1 on endothelial cells.

The main objective of this study was to identify molecular mechanisms through which angiopoietin-1 (Ang-1), a ligand for Tie-2 receptors, influences endothelial cell apoptosis. Human umbilical vein endothelial cells were cultured in a medium enriched with 2% fetal bovine serum (FBS) and growth supplements. Apoptosis was induced over 24 h by reducing FBS to 0.1%. Activation of caspase-9, -8, -7, and -3 and the expression of Bcl-2 family proteins, inhibitors of apoptosis (IAPs), cytochrome c, as well as Smac proteins were evaluated with immunoblotting. Ang-1 clearly attenuated serum deprivation-evoked apoptosis, an effect which required Tie-2 receptor activation. Activation of caspase-9, -7, and -3, but not caspase-8, was inhibited by Ang-1. The inhibitory effects of Ang-1 on apoptosis and caspase activation were reversed by a PI-3 kinase inhibitor (wortmannin). Ang-1 exposure upregulated the expression of Survivin but not XIAP (members of IAPs), reduced the cystosolic levels of Smac, but not that of cytochrome c, and had no effect on the expression of Bcl-2 family proteins. This is the first study to report on the mitochondrial mechanisms through which Ang-1 inhibits apoptosis and to investigate the role of the newly discovered Smac. We conclude that Ang-1 inhibits endothelial cell apoptosis through several pathways, which include PI-3 kinase/AKT activation, inhibition of Smac release from the mitochondria, and upregulation of Survivin protein.