PHOTOPHYSICAL AND PHOTOBIOLOGICAL PROPERTIES OF DIPORPHYRIN ETHERS

Spectral properties of several diporphyrin ethers were assessed in different solvents and after accumulation by leukemia L1210 cells in vitro. To facilitate studies in a variety of solvents, both tetramethylesters of the diporphyrin ethers and free acids were employed. For comparison, studies on the corresponding porphyrin monomers were also carried out. The joining of two porphyrins by an ether linkage had several consequences. We observed a blue shift in the Soret band of the ethers, but not of the corresponding simple porphyrins, in protic solvents. This phenomenon is likely related to ether aggregation under conditions which promote H-bonding. The presence of an ether linkage was associated with enhanced fluorescence at 630-640 nm and decreased fluorescence lifetimes and yields, especially in protic solvents. The ether linkage was unaffected by intracellular enzymes, but porphyrin esters were readily hydrolyzed upon accumulation by L1210 cells. The joining of two hematoporphyrin molecules by an ether linkage promoted dye accumulation by L1210 cells. In contrast, accumulation of mesoporphyrin and protoporphyrin was thereby retarded.     

Hematoporphyrin as a photosensitizer of tumors

Abstract— The ability of hematoporphyrin (Hp) to act as a photosensitizer of cells in vitro or in vivo is a matter of dispute, while hematoporphyrin derivative (Hpd), a mixture of porphyrins including hematoporphyrin, has been consistently found to be an effective photosensitizer both in vitro and in vivo. Until recently the actual component of the Hpd mixture responsible for these effects had not been identified. We have found that those preparations of Hp which contain, as an impurity, a porphyrin similar to that found to be responsible for the tumor photosensitizing ability of Hpd, may be effective photosensitizers of tumors but are generally of low efficacy. This material accounts for the entire photosensitizing activity of both Hp and Hpd in the SMT-F mammary carcinoma in DBA/2 HeHa mice.     

Characterization of intra-tumoral porphyrin following injection of hematoporphyrin derivative or its purified component

Photodynamic therapy (PDT) utilizes either hematoporphyrin derivative (Hpd) or a purified form of Hpd termed DHE, as photosensitizers for treatment of a variety of solid tumors in man. The reasons for long retention of these porphyrins in a wide range of histologically diverse tumors remain obscure. We have found that the RIF fibrosarcoma and SMT-F mammary carcinoma in mice, a intrapancreatic tumor in the hamster and a tumor removed from a patient with a myxoid sarcoma, make take up Hpd or DHE by endocytosis. On the other hand the RIF tumor cells in vitro show a tendency for selective uptake and retention of the more hydrophobic components of the mixture.     

FLUORESCENCE SPECTRAL CHANGES OF HEMATOPORPHYRIN DERIVATIVE UPON BINDING TO LIPID VESICLES, Staphylococcus aureus AND Escherichia coli CELLS

Abstract— The binding of hematoporphyrin derivated (Hpd) to lipid vesicles and bacterial membranes was determined by fluorescence spectroscopy. The fluorescence measurements of Hpd in aqueous solutions showed two bands at 613 and 677 nm. In lipid environments of lecithin vesicles the fluorescence spectrum was shifted to 631 and 692 nm, respectively. Hpd was rapidly bound to the cell membrane of Staphylococcus aureus while much less binding occurred in the presence of Escherichia coli. At the same time, spheroplasts of both bacteria were shown to bind Hpd to a similar extent. These results are well correlated with the photoinactivation of the gram positive bacteria with Hpd while the gram negative cells were shown to be resistant. The pH dependence of both Hpd binding to S. aureus as well as the photodynamic inhibitory effect of the same bacteria are similar. It is concluded that the segregation of Hpd to the cell membrane is a prerequisite for its photodynamic effect.     

PHOTOSENSITIZED LYSIS OF LIPOSOMES BY HEMATOPORPHYRIN DERIVATIVE

The spectral properties and efficiency for photosensitizing the lysis of phosphatidylcholine liposomes have been measured for the components of hematoporphyrin derivative (Hpd) after alkaline hydrolysis and fractionation by polyacrylamidc gel chromatography. Two major and two minor Hpd fractions have been identified whose spectral properties correlate with the anoxic sensitizing efficiency and the oxygen enhancement ratio (OER). The fastest moving fraction, which is the putative biologically active component, comprised one-third of the starting material and had OER = 2.7. Liposome lysis by this fraction was inhibited in the presence of human serum albumin at concentration ratios comparable to those employed for photoradiation therapy. The present results show that Hpd can act as an oxic and anoxic photosensitizer of a model biomembrane and suggest that separation from serum proteins is required for in vivo photosensitization.     

PHOTOSENSITIZING EFFECTS OF HEMATOPORPHYRIN DERIVATIVE IMMOBILIZED ON SEPHAROSE

Abstract— The cytotoxicity that ensues following photosensitization by hematoporphyrin derivative (Hpd) is attributed to production of singlet oxygen. Many of the cellular end points reported to be affected are localized to membranes, hydrophobic environments conducive to partitioning of hydrophobic porphyrins in Hpd. In order to test the hypothesis that efficacy of Hpd-induced photosensitization is enhanced by its ability to freely enter cells or subcellular organelles, we immobilized Hpd on a sepharose support. This immobilized reagent was found to produce ¹O₂ when photoradiated, in yields similar to those observed for Hpd in solution, as evidenced by the bleaching of p -nitrosodimethylaniline in the presence of imidazole. The immobilized Hpd was capable of photosensitizing, i.e. inhibit, cytochrome c oxidase activity in intact mitochondrial membranes and in aqueous solution. However, enzymes located on the interior of mitochondrial membranes (F₀F₁ ATP synthase and succinate dehydrogenase), in the mitochondrial matrix (malate dehydrogenase), or on the inside of the plasma membrane, (Na++ K+)- ATPase, were unaffected by immobilized Hpd plus photoradiation compared to free Hpd. The results suggest that photosensitization by Hpd most likely arises from entry of the photosensitizer into the biological membrane, although proteins on the exterior membrane surface may be susceptible to damage by ¹O₂ produced in proximity to their location.     

Configuration of triporphyrin ethers probed by fluorescence measurements.

The fluorescence spectra and lifetimes of triporphyrin ethers derived from hematoporphyrin, mesoporphyrin and protoporphyrin were examined, together with relative hydrophobicities estimated from reverse-phase high performance liquid chromatography (HPLC) elution times. The following data suggest a molecular arrangement with two of the three rings in a "folded configuration". The trimers display a greater fluorescence yield (phi f) than the corresponding diporphyrin ethers which contain only the two folded rings. The fluorescence lifetime data for the trimers are consistent with signals from both a folded ring pair (7-8 ns) and a free ring (14 ns). Reverse-phase HPLC studies indicate that the trimers are intermediate in hydrophobicity between the monomers and dimers. Preliminary data suggest that, for certain peripheral substitutions, the trimer configuration is superior to the dimer for photodynamic therapy.     

THE EFFECT OF LIPOSOMES'' MEMBRANE COMPOSITION ON THE BINDING OF THE PHOTOSENSITIZERS HPD AND PHOTOFRIN II

Abstract— Photofrin II (PF-II) is the commercial name of the active photosensitizer which is used in photodynamic therapy of cancer. The effect of the composition of lipid membranes on the binding of PF-II was studied and compared to hematoporphyrin derivative (Hpd), which is a complex mixture of porphyrins and from which PF-II is separated. We find that increasing the content of cholesterol in the bilayer decreases the partitioning of PF-II into the bilayer, similar to what we have found earlier with Hpd. However, inserting DMPC or DPPC into the membrane, which was shown to decrease the binding of Hpd, causes the opposite trend with PF-H. A membrane fluidizer such as benzyl alcohol also has different effects on the membrane binding of Hpd and PF-II. The rate of binding of PF-II to a lipid membrane is about 10 times lower than that of Hpd. These results as well as I^- quenching of the fluorescence of the two porphyrins indicate that PF-II is immersed less homogeneously and deeper in the bilayer than Hpd. The unique additive-dependent binding of PF-II to lipid membranes calls for care in using Hpd as a model photosensitizer.     

Polymeric porphyrins as new photocatalysts in photodynamic therapy of cancer

Photodynamic therapy and diagnosis (PDT) is described as an efficient clinical method for the treatment of cancer patients using hematoporphyrin derivative (Hpd) as sensitizer. Newly developed metal-containing porphyrin type compounds are potential agents for PDT. A concept for covalently bound polymeric metal-containing or metal-free sensitizers is discussed. First results of these polymeric sensitizers are reported from in vivo experiments. High tumor accumulation up to 30% was observed. Results of fluorescence diagnosis are shown.     

INTERDEPENDENCE OF FLUENCE, DRUG DOSE and OXYGEN ON HEMATOPORPHYRIN DERIVATIVE INDUCED PHOTOSENSITIZATION OF TUMOR MITOCHONDRIA

Abstract— Studies were conducted to assess the interdependence of three discrete parameters known to influence hematoporphyrin derivative (Hpd)-induced photosensitization. The effects of fiuence, drug dose and oxygen environment were examined for their role in causing an inhibition of the activity of mitochondrial cytochrome c oxidase. Experiments were performed on R3230AC mammary tumor mitochondria in vitro and on mitochondria isolated from tumors of animals pre-treated with Hpd in vivo. Inhibition of cytochrome c oxidase activity was observed to be directly proportional to total energy density. Photosensitization was dependent on oxygen concentration, with total energy density dependent photosensitization being diminished in environments containing less than 5% oxygen. At 1% oxygen environments, photosensitization was significantly impaired and demonstrated no drug-dose relationship. These results suggest that tissue oxygen concentration may represent a critical factor for the therapeutic usefulness of Hpd photodynamic therapy in treatment of cancer.     

PORPHYRIN PHOTOSENSITIZATION OF PROTEINS IN CELL MEMBRANES AS STUDIED BY SPIN-LABELLING AND BY QUANTIFICATION OF DTNB-REACTIVE SH-GROUPS

Abstract— Human cells of the line NHIK 3025 were exposed to hematoporphyrin derivative (Hpd) and light and analysed with respect to; (i) the mobility of membrane proteins as determined by electron spin resonance measurements of a protein-bound spin label, (ii) fluorescence excitation spectra, (iii) relative number of DTNB-reactive SH-groups on their surface and in sonicated cell homogenates, (iv) survival, and (v) morphologic appearance as seen by ordinary phase contrast microscopy. A significant fraction of the porphyrins bound to the outer cell membrane was in close contact with proteins. 5,5'-Dithiobis-2-nitrobenzoic acid reactive SH-groups on the outer cell membrane were very sensitive to the treatment with Hpd + light and were degraded according to non-exponential kinetics. When the cells were irradiated after spin labelling, the labelled proteins became less mobile during the irradiation, indicating protein cross linking. Irradiation before spinlabelling resulted in a selective degradation of low-mobility proteins.     

血卟啉醚衍生物的核磁共振研究

用核磁共振方法研究了近三十个新的血卟啉醚的结构，对１Ｈ－ＮＭＲ谱进行了归宿，讨论了取代基结构对卟啉化学位移的影响。     

THE STRUCTURE OF THE ACTIVE MATERIAL IN HEMATOPORPHYRIN DERIVATIVE

Abstract The structure of the active material in hematoporphyrin derivative is shown to be a condensation polymer of hematoporphyrin linked by ether functional groups. When a mixture of the monoacetates and the diacetate of hematoporphyrin is treated with dilute sodium hydroxide solution a polymeric fraction is formed which constitutes the active material of hematoporphyrin derivative. This fraction is stable to basic hydrolysis using conditions which are shown to hydrolyse porphyrin esters, but is hydrolysed by acidic conditions which cleave porphyrin ethers as well as esters. When hematoporphyrin diacetate is similarly treated with base a polymeric fraction is formed which is hydrolysed by both acidic and basic conditions showing it to be ester linked. This ester linked polymer is unstable in aqueous solution at pH 7 and converts to the polyether within 2 days at room temperature.     

PHOTOSENSITIZATION BY DIPORPHYRINS JOINED VIA METHYLENE BRIDGES

Abstract— Photodynamic and biophysical properties of three porphyrin dimers joined by methylene bridges were examined. Fluorescence emission spectra and fluorescence lifetimes of the methylene-linked dimers were similar to values obtained with porphyrin monomers. Singlet oxygen quantum yields were not significantly different when the three diporphyrins were compared. The diporphyrins were short-acting tumor photosensitizers in vivo, and were rapidly cleared from plasma. Of the 3 diporphyrins examined, one was essentially ineffective as a sensitizer in vivo. This could not have been predicted from in vitro studies which indicated photodamage to membrane and mitochondrial loci. The methyiene-linked diporphyrins were hydrophilic dyes (water/octanol distribution ratio =120–200) and bound mainly to plasma high-density lipoprotein. In contrast, the more hydrophobic diporphyrin ester/ether fraction from HPD was a long-persisting photosensitizer in vivo. Compared with hematoporphyrin, this hematoporphyrin derivative (HPD) fraction demonstrated a red-shift in fluorescence emission and a shortened fluorescence lifetime. These comparisons suggest that ring-ring interactions occur in the ester/ether-linked diporphyrins from HPD, but not in the methyiene-linked diporphyrins.     

TYPE I AND TYPE II MECHANISMS IN THE PHOTOSENSITIZED LYSIS OF PHOSPHATIDYLCHOLINE LIPOSOMES BY HEMATOPORPHYRIN

Abstract The lysis of phosphatidylcholine (PC) liposomes was sensitized to visible light (>500nm) by hematoporphyrin (HP) incorporated in the liposomes (0.09-1.5%, wt/wt) or in the external buffer (1-15 μM). The lytic mechanism changed from the Type II pathway mediated by singlet oxygen (¹O₂) at low HP concentrations to the anoxic, Type I pathway at high HP concentrations. Spectral measurements of HP in aqueous and organic solvents indicate that the HP was not aggregated (monomers and/or dimers) for Type II sensitization and aggregated for Type I conditions. High concentrations of azide (>0.1 M) or DABCO (>0.5 M) were protective with high HP concentration under oxic and anoxic conditions, which cannot involve the scavenging of ¹O₂. Feasible protective mechanisms are quenching of the HP triplet state by high azide and repair of the damaged membrane by DABCO via an electron transfer process. There was significant protection against lysis under Type I conditions by low concentrations of ferricyanide (>1 mM), indicative of an electron transfer mechanism. The incorporation of 22 mol % cholesterol in PC liposomes with 1% HP had no effect on the lytic efficiency for oxic and anoxic conditions. Dipalmitoylphosphatidylcholine liposomes incorporating 1% HP showed negligible photosensitized lysis at 50°C compared with PC liposomes with 1% HP at 25°C. The promotion of photosensitized lysis by hydrodynamic agitation observed in prior work with methylene blue (Grossweiner and Grossweiner, 1982) was significant with HP sensitization for both Type I and Type II conditions. Actinometry with PC liposomes incorporating 1% HP indicated that photosensitized lysis was very inefficient, requiring many absorbed quanta per lysed liposome. Preliminary experiments with crude hematoporphyrin derivative (Hpd) showed similar concentration effects on lytic efficiency, where PC liposomes incorporating 0.1% (wt/wt) Hpd were strongly sensitized by oxygen, whereas sensitization by oxygen was insignificant with 3.1% Hpd. The results with HP and crude Hpd indicate that lytic damage in a biomembrane does not necessarily require oxygenation.     

EFFECT OF HEMATOPORPHYRIN DERIVATIVE ON HEMATOLOGICAL PARAMETERS IN RATS

Abstract— Wistar rats were injected with hematoporphyrin derivative (Hpd) intraperitoneally and kept in the dark. Rats were sacrificed 2, 24, 48 and 72 h after injection. It was observed that Hpd in the dark did not affect the hemoglobin content and number of erythrocytes, while the leukocyte count was increased and blood pH decreased. Blood levels of glucose and lactate were increased significantly. Because the food intake was similar in all the groups, glycogenolysis was suspected to be the source of increased glucose levels in blood. However, a significant increase in the glycogen content of the livers of Hpd-treated rats was observed, which rules out glycogenolysis. Hyperglycemia may result due to a number of reasons such as stimulation of the central nervous pathways innervating the liver and adrenal medulla, excessive glucogenesis in liver from glycogen and noncarbohydrate sources, emotional stress, anesthesia and hormonal effects. The present study rules out hyperglycemia due to anesthesia and glucogenesis in the liver. Maintenance of blood glucose levels is a highly complex mechanism. Further investigations to understand these mechanisms are in progress.     

Bay-area selective thermal [4+2] and [4+4] cycloaddition reactions of triply linked ZnII diporphyrin with o-xylylene

A triply linked ZnII diporphyrin underwent site-selective cycloaddition reactions with thermally generated o-xylylene to provide a triply linked porphyrin-chlorin hybrid and a triply linked chlorin dimer in moderate yields. The former product is a symmetry-allowed [4+2] cycloadduct, while the latter is a symmetry-forbidden [4+4] cycloadduct. Oxidation of the latter product with 2,3-dichloro-5,6-dicyano-1,4-benzoquinone (DDQ) provided a triply linked diporphyrin fused with a benzocyclooctatriene segment. This oxidized product and above [4+2] cycloadduct were structurally characterized by single crystal X-ray diffraction analysis. The observed site-selectivity is considered to arise from the large MO coefficients at the bay-area in the LUMO of the triply linked diporphyrin. The anomalous thermal [4+4] cycloaddition may be ascribed to the highly conjugated and quite perturbed electronic properties of triply linked ZnII diporphyrin.     

On the preparation and properties of dihematoporphyrin ether, the tumor-localizing component of HPD

Abstract— A porphyrin mixture derived from hematoporphyrin and termed HPD (hematoporphyrin derivative) is used for localization and therapy of tumors. The major localizing component of HPD has been provisionally identified as a dihematoporphyrin ether (DHE). In this study, we describe HPLC procedures for analytical and preparative separation of HPD components. Optimal conditions for DHE formation were determined. A comparison of absorbance and fluorescence spectra in different solvents indicate that DHE aggregates are substantially more stable than are the analogous hematoporphyrin structures. Studies on the interaction between DHE and tumor cells indicate an initial binding of the drug at lipophilic membrane sites, followed by gradual relocation to intracellular loci.     

Polar nematic methyl (E)-[trans-4-cyclohexyl-substituted]allyl ethers: Synthesis, liquid crystal transition temperatures and some physical properties

We have introduced an oxygen atom and a carbon-carbon double bond with a trans-configuration (E) into the terminal alkyl chain attached to the cyclohexyl ring of a variety of two- and three-ring nematic liquid crystals of positive dielectric anisotropy. The new polar two-ring methyl (E)-allyl ethers often possess low melting points, but are not mesomorphic in general. The related three-ring methyl (E)-allyl ethers exhibit high clearing points and wide nematic ranges. Comparisons with the corresponding derivatives incorporating either just an oxygen atom or just a carbon-carbon double bond in the same position indicate that synergetic effects lead to broader nematic phases than would otherwise have been expected. This is partially due to the low smectic transition temperatures observed for the methyl (E)-allyl ethers. Selected physical properties of three binary mixtures of a weakly polar standard nematic liquid crystal and three difluoro-substituted (polar) liquid crystals (including the new ethers) differing only in the nature of the terminal chain show that, although some of the methyl (E)-allyl ethers exhibit longer switch-off times in TN cells than those of analogous liquid crystals incorporating either a methyl propyl ether or a 1-(E)-propenyl chain instead of the methyl (E)-allyl ether chain, they are still useful components for nematic mixtures, especially where a wide temperature range is required.     

Modified windmill porphyrin arrays: coupled light-harvesting and charge separattion, conformational relaxation in the S1 state, and S2-S2 energy transfer

The architecture of windmill hexameric zinc(II) -porphyrin array 1 is attractive as a light-harvesting functional unit in view of its three-dimensionally extended geometry that is favorable for a large cross-section of incident light as well as for a suitable energy gradient from the peripheral porphyrins to the meso-meso-linked diporphyrin core. Three core-modified windmill porphyrin arrays 2-4 were prepared for the purpose of enhancing the intramolecular energy-transfer rate and coupling these arrays with a charge-separation functional unit. Bisphenylethynylation at the meso and meso' positions of the diporphyrin core indeed resulted in a remarkable enhancement in the intramolecular S1-S1 energy transfer in 2 with tau=2 approximately 3 ps, as revealed by femtosecond time-resolved transient absorption spectroscopy. The fluorescence lifetime of the S2 state of the peripheral porphyrin energy donor determined by the fluorescence up-conversion method was 68 fs, and thus considerably shorter than that of the reference monomer (150 fs), suggesting the presence of the intramolecular energy-transfer channel in the S2 state manifold. Such a rapid energy transfer can be understood in terms of large Coulombic interactions associated with the strong Soret transitions of the donor and acceptor. Picosecond time-resolved fluorescence spectra and transient absorption spectra revealed conformational relaxation of the S1 state of the diporphyrin core with tau = 25 ps. Upon photoexcitation of models 3 and 4, which bear a naphthalenetetracarboxylic diimide or a meso-nitrated free-base porphyrin attached to the modified diporphyrin core as an electron acceptor, a series of photochemical processes proceeded, such as the collection of the excitation energy at the diporphyrin core, the electron transfer from the S1 state of the diporphyrin to the electron acceptor, and the electron transfer from the peripheral porphyrins to the diporphyrin cation radical, which are coupled to provide a fully charge-separated state such as that in the natural photosynthetic reaction center. The overall quantum yield for the full charge separation is better in 4 than in 3 owing to the slower charge recombination associated with smaller reorganization energy of the porphyrin acceptor.