Bioactive potential of sea urchin Temnopleurus toreumaticus from Devanampattinam, Southeast coast of India

The present investigation elucidates the bioactive potential of aqueous extract of sea urchin Temnopleurus toreumaticus. In this investigation biochemical, heamolytic, cytotoxic and FT-IR analysis were followed by standard methods. In biochemical analysis, proteins content 2.70 mgmL-1, total carbohydrates content 2.15 mgmL-1 and total lipids content 0.03 mgmL-1 were showed in aqueous extract of sea urchin. In heamolytic assay, the goat and chicken erythrocytes showed the maximum 64 Hemolytic Unit (HU) and human blood group “A” shows 32 HU, blood group “B” shows 64 HU, blood group “AB” shows 32 HU and blood group “O” shows 128 HU. In cytotoxic study, aqueous extract of sea urchin showed LC50 value 0.12±0.09 mgmL-1 concentration was showed 50% mortality. In antimicrobial assay, maximum zone inhibition 12.26 ± 0.6 mm showed by K. oxytoca and 3.33 ± 0.9 mm showed by Mucor sp. against chloroform extract of sea urchin T. toreumaticus. Thin layer chromatogram showed the spots of Rf values of 0.38, 0.85 cm. The FT-IR study shows the presence of functional groups such as chloroalkanes, bromoalkanes, iodoalkanes, alcohols groups, acids or aromatic ethers, methyl alkyl groups, 1° amines groups and ammonium ions. These results indicate that, sea urchin has remarkable hemolytic and cytotoxic activities.Keywords: Antimicrobial Assay, Biochemical, FT-IR, Sea Urchin, Heamolyti

Spin-State Ordering in Hydroxo-Bridged Diiron(III)bisporphyrin Complexes

We report the synthesis, structure, and spectroscopic characterization of 1,2-bis[μ-hydroxo iron(III) 5-(2,3,7,8,12,13,17,18-octaethylporphyrinyl)]ethane with PF6– and SbF6– counteranions. The two iron centers are nonequivalent with admixed intermediate spin state (S = 3/2 with a minor contribution of S = 5/2) on each metal both in the solid and in solution. The molecules are compared with previously known μ-hydroxo complexes with other counterions, such as I3–, BF4–, and ClO4–, which demonstrates that the nature of the counterion can affect the spin-state ordering dramatically. To understand how the spin-state ordering is affected by external perturbations, we also have done a comprehensive computational study. The calculations show that subtle environmental perturbations affect the spin-state ordering and relative energies and are likely to be the root cause of the variation in spin-state ordering observed experimentally