ABSTRACT
The study focused on development of mathematical modeling and numerical simulation technique for selected heavy metal transport in Uyo municipal solid waste dumpsite in Akwa Ibom State to investigate the level in depth to which leachate from the dumpsite extends and the quantity of leachate at various depth of the dumpsite soil. Uyo waste dumpsite is operating open dumping system where provisions are not made for preservation and conservation of soil and water quality, hence, the need for this study. Three monitoring pits within Uyo waste dumpsite were constructed and infiltration runs were measured, and soil samples were collected beside infiltration points from nine designated depths ranging from 0 to 0.9 m for modeling heavy metal transport in the soil. Data collected were subjected to descriptive and inferential statistics while the COMSOL Multiphysics software 6.0 was used to simulate the movement of pollutants in the soil. It was observed that heavy metal contaminant transport in soil of the study area is in the power functional form. The transport of heavy metals in the dumpsite can be described by a power model from linear regression and a numerical model based on finite element. Their validation equations showed that the predicted and the observed concentrations yielded a very high R2 value of over 95%. The power model and the COMSOL finite element model show very strong correlation for all selected heavy metals. Findings from the study has identified level in depth to which leachate from the dumpsite extends and the quantity of leachate at various depth of the dumpsite soil which can be accurately predicted using leachate transport model of this study.
ABSTRACT
Two distinct families of low-molecular-weight toxins (argiotoxins) have been isolated from the venom of the orb-web spider. Argiope trifasciata. The toxins have been purified to homogeneity and characterised by spectroscopic, mass spectrometric and microchemical analysis. The major biologically active member of the first family of toxins is 2,4-dihydroxyphenylacetyl-asparagine linked through a C11-tetra-amine to N-terminal arginine; other members of this family are methylene homologues. The second family of toxins possesses an indolic group in place of the 2,4-dihydroxyphenyl chromophore. The toxins act as non-competitive inhibitors at quisqualate-type glutamatergic receptors on a metathoracic retractor unguis nerve-muscle preparation of Schistocerca gregaria. The loss of the N-terminal arginine reduces biological activity of the first family of toxins, but not of the second. The nature of the polyamine appears to be less important, perhaps acting as a spacer between the cationic arginine and the more hydrophobic aromatic tail of the toxins.