The pre-launch characterization of SIMBIO-SYS/VIHI imaging spectrometer for the BepiColombo mission to Mercury. II. Spectral calibrations.

The Visible and near Infrared Hyperspectral Imager (VIHI) is the VIS-IR spectrometer with imaging capabilities aboard the ESA BepiColombo mission to Mercury. In this second paper, we report the instrument spectral characterization derived by the calibration campaign carried out before spacecraft integration. Complementary measurements concerning radiometric and linearity responses, as well as geometric performances, are described in Paper I [G. Filacchione et al., Rev. Sci. Instrum. 88, 094502 (2017)]. We have verified the VIHI spectral range, spectral dispersion, spectral response function, and spectral uniformity along the whole slit. Instrumental defects and optical aberrations due to smiling and keystone effects have been evaluated, and they are lower than the design requirement (<1/3 pixel). The instrumental response is uniform along the whole slit, while spectral dispersion is well represented by a second order curve, rather than to be constant along the spectral dimension.

Synthesis and biological activity of linear and angular 4-methoxymethylthienocoumarins and 4-acetoxymethylthienocoumarins.

This paper reports the synthesis of 4-methoxymethyl and 4-acetoxymethyl-6,9-dimethyl-2H-thieno[3,2-g]-1-benzopyran-2-one as well as 4-methoxymethyl- and 4-acetoxymethyl-6,9-dimethyl-2H-thieno[2,3-h]-1- benzopyran-2-one. The synthesized derivatives were tested on human cells in UVA irradiation conditions. Skin phototoxicity and cross-link formation in DNA were also studied. Results indicate that the new thienocoumarins have good antiproliferative activity, greater than that of the well-known photochemotherapeutic drug 8-methoxypsoralen, but they are practically devoid of skin photosensitization effects.

Photochemical and photobiological properties of 4,8-dimethyl-5'-acetylpsoralen.

The photochemical and photobiological properties of 4,8-dimethyl-5'-acetylpsoralen (AcPso), proposed for the photochemotherapy of some skin diseases, were investigated. The photoreaction of AcPso with DNA is weaker in the presence of air than in a nitrogen atmosphere, in terms of total photobinding and DNA cross-linking; when UVA irradiation is performed in air, AcPso behaves as a monofunctional reagent. The quenching effect of oxygen is related to the high capacity of AcPso to produce singlet oxygen. Furthermore, it is demonstrated that AcPso photoadducts are better producers of singlet oxygen than free AcPso in solution. Using DNA sequencing methodology, two modes of DNA photosensitization by AcPso are shown, these lead to the formation of photoadducts mainly at T residues (and at C to a lesser extent) and to photo-oxidized G residues probably via singlet oxygen. Chemical or enzymatic cleavage were used as probes in these experiments. A rapid assay for the detection of the photodynamic effect of a photosensitizer on DNA, involving oxygen, is also described. Finally, the cytotoxicity and genotoxicity of AcPso on E. coli WP2 cells appear to be related to its ability to form photoadducts, in particular cross-links, rather than to its capacity to produce singlet oxygen.

Synthesis and photobiological properties of acetylpsoralen derivatives.

In an investigation to find monofunctional reactants for DNA which can act as new agents in the photochemotherapy of psoriasis, we have synthesized and studied some methylpsoralen derivatives which contain an acetyl group at one of the two reactive sites of the furocoumarin skeleton (at the 3 or 5' positions). The compounds do not react easily with DNA; their photobiological properties (e.g. the lack of an ability to inhibit DNA synthesis in Ehrlich ascites tumour cells, to induce T2 phage sensitization and to induce erythema in guinea-pig skin) are exactly in line with this behaviour. Some interesting features are shown by 4,8-dimethyl-5'-acetylpsoralen: it is capable of producing a very large amount of singlet oxygen--an order of magnitude higher than the other compounds and 8-methoxypsoralen (used as reference). In spite of this property, 4,8-dimethyl-5'-acetylpsoralen is non-phototoxic to the skin, and its other photobiological properties appear to be in line with its lack of interaction with DNA rather than its enhanced singlet oxygen production.

6-Methylangelicins: a new series of potential photochemotherapeutic agents for the treatment of psoriasis.

The possible presence of methylpsoralens as undesired inquinants in synthetic methylangelicins has been avoided through a synthetic pathway starting from umbelliferones carrying a methyl group in the 6-position. The new 6-methylangelicins show a high affinity toward DNA, forming in the dark a molecular complex; the complexed angelicins under UV-A irradiation photobind effectively to the macromolecule, forming only monoadducts. The new compounds show an evident antiproliferative activity by inhibiting DNA synthesis on Ehrlich cells; great differences, however, can be seen between the various compounds. All the compounds are lacking of skin erythemogenic activity. Some of the new 6-methylangelicins, evaluated in terms of mutagenic activity, demonstrate to be less effective than 8-methoxypsoralen (8-MOP), used for a comparison. On the basis of antiproliferative activity, lack of skin phototoxicity, and low mutagenicity, two compounds have been chosen for clinical evaluation. The compounds tested on seven psoriatic patients by topical application and UV-A irradiation proved to be more effective than 8-MOP, used in the same conditions.

4'-Methylangelicins: new potential agents for the photochemotherapy of psoriasis.

Three derivatives of angelicin (1) [4'-methyl-, 4,4'-dimethyl-, and 4',5-dimethylangelicin (2a-c)] have been prepared with the aim of obtaining new agents for the photochemotherapy of psoriasis. These compounds form a complex in the dark with DNA that shows an affinity for the macromolecule higher than that of the parent angelicin (1). A correlation between their octanol/water partition coefficients and the association constants of the complexes has been observed. Compounds 2a-c photobind to DNA to a much higher extent than 1 and also more effectively than 8-methoxypsoralen (8-MOP), taken as reference compound. When activated with UV-A, the three compounds strongly inactivate T2 phage and inhibit epidermal DNA synthesis in mice. Moreover, they show a mutagenic activity markedly lower than that of 8-methoxypsoralen on Escherichia coli wild-type strain. Due to its lack of skin phototoxicity, its low mutagenic activity, and its antiproliferative activity, 2c was chosen for clinical evaluation. It proved to be effective in clearing psoriasis in two patients.

A new water soluble derivative of 4,5'-dimethylangelicin as a potential agent for photochemotherapy.

A water soluble derivative of 4,5'-dimethylangelicin (I) having a long chain linking an amino group to the planar furocoumarinic moiety, that is 4'-N,N-dimethylaminoethoxymethyl-4,5'-dimethylangelicin (III), has been prepared. This compound is able to form effectively the intercalated complex with DNA like the previously prepared 4'-aminomethyl-4,5'-dimethylangelicin (II), however while the compound (II) showed very poor photobinding to DNA, the new derivative (III) shows high photobinding to the macromolecule. It is proposed that these data illustrate the importance of the geometry of intercalation for the subsequent covalent photobinding to the macromolecule. Also some photophysical data of (II) and of (III) appear to confirm the critical role of the position assumed by the chromophore of the two compounds when intercalated in duplex DNA. The compound (III) displays high photobiological effects, also in terms of antiproliferative activity as shown by its capacity to inhibit DNA and RNA synthesis in Ehrlich cells, the growth of an E. coli culture and the infectivity of T2 phage. (III) on the basis of these properties seems to deserve a clinical evaluation of its potential photochemotherapeutic activity in the treatment of psoriasis.

Photochemical and photobiological properties of 4,5'-dimethylpsoralen, a bifunctional contaminant of synthetic 4,5'-dimethylangelicin.

4,5'-Dimethylpsoralen, a bifunctional furocoumarin, can be formed as an impurity in the synthesis of its angular isomer, that is 4,5'-dimethylangelicin; the latter has recently been proposed as a potential monofunctional agent for photochemotherapy. To have precise information on the possible modifications of the photochemical and photobiological properties of synthetic 4,5'-dimethylangelicin caused by the presence of its linear isomer, we have studied the interactions of the latter with DNA in both the ground and the excited state and its photobiological activity. 4,5'-Dimethylpsoralen photobinds much more effectively to DNA than its angular isomer and is capable to form effectively inter-strand cross-linkages in DNA while dimethylangelicin is unable to form these bifunctional adducts in DNA. Dimethylpsoralen shows a strong skin-phototoxicity while angelicin lacks this activity. Moreover the antiproliferative activity of the psoralen derivative in terms of DNA synthesis inhibition in Ehrlich cells and of inhibition of infectivity of T2 phages, is about four times higher than that of the angular isomer. These data stress the necessity of the absence of the isomeric linear furocoumarin in the synthetic 4,5'-dimethylangelicin because its presence can markedly modify the photobiological and phototherapeutic properties of the angelicin derivative.

Bis-basic derivatives of planar heterocyclic compounds.

Four compounds derived from the furocoumarin, benzodipyrone and benzodifuran nucleus respectively, have been synthesized. They have molecular structures analogous to that of tilorone, namely an aromatic tricyclic moiety and two basic chains linked to the nucleus through ester or amido groups. Like tilorone, the new compounds efficiently from complexes with DNA, consisting in an intercalation of the planar aromatic moiety between two base pairs and an electrostatic interaction of the positively charged nitrogen atoms of the side chains with the phosphate groups of the macromolecule. When tested for their capacity to stimulate interferon production in mice, the compounds showed different activities; in particular the diethylamino ethyl ester of bis-benzodifuranic acid (III) proved to be twice as active as tilorone, assayed in the same experimental conditions for comparison purposes.