var fadeimages=new Array();

fadeimages[0]=["images/gallery/synapses-story.jpg",    "http://www.its.caltech.edu/~mbklab", "newWindow",""];
fadeimages[1]=["images/gallery/plant-story.jpg",       "http://www.its.caltech.edu/~plantlab", "newWindow",""];
fadeimages[2]=["images/gallery/viralsim-story.jpg",    "http://www.jensenlab.caltech.edu", "newWindow"                 ,""];
fadeimages[3]=["images/gallery/vertebrates-story.jpg", "http://biology.caltech.edu/Members/Bronner-Fraser", "newWindow",""];
//fadeimages[3]=["images/gallery/flower-story.jpg", "", ""];

var fadebgcolor="#61a99c";

fadeimages[0][3]= "<b>Modeling of synaptic plasticity</b><br>"+
	"Synaptic plasticity refers to the process whereby neuronal connections in the brain are modified in response to stimuli; it is the fundamental physiological basis of learning and memory. Changes in synaptic strength are the result of a complex biochemical signaling network that is sensitive to the discrete distributions in both space and time of the component molecules."+
         "<br>"+
         "<a href=http://www.its.caltech.edu/~mbklab/>[more]</a>";

fadeimages[1][3]= "<b>Modeling of Plant Development</b><br>"+
	"The Meyerowitz group, working with Eric Mjolsness at the University of California at Irvine, is studying the growth of plan shoots at the cellular level, obtaining new dynamic descriptions of patterns of cell division and gene expression by using real-time laser scanning confocal microscopy of plant meristems that have been marked with fluorescent reporters." +
	"<br>"+
         "<a href=http://www.its.caltech.edu/~plantlab/>[more]</a>";


fadeimages[2][3]= "<b>Spatially explicit simulations of cellular and viral ultrastructure</b><br>"+
	"Spatial organization of cellular ultrastructure determines major physical properties of cells, is a prerequisite for some functions of cell metabolism and division and also influences characteristics of viruses such as HIV-1. Using a powerful miscroscopy technique known as electron cryotomography, the lab of Grant Jensen collects images of both bacterial subcellular structures and viruses" +
        "<br>"+
         "<a href=http://www.jensenlab.caltech.edu/>[more]</a>";

fadeimages[3][3]= "<b>Evolution of developmental mechanisms in vertebrates</b><br>"+
	"Neural crest cells ultimately give rise to many defining characteristics of vertebrates, including a well-defined head and peripheral neural ganglia. Thus, understanding the genetic changes driving the evolution of definitive neural crest cells from their early evolutionary precursors is critical to understanding vertebrate origins."+
	"<br>"+
         "<a href=http://biology.caltech.edu/Members/Bronner-Fraser/>[more]</a>";

/*
fadeimages[4]= "<b>Flower Development</b><br>"+
         "In the flower area we have had a long-standing interest in"+
         "the genes that regulate organ identity in flowers. Flowers"+
         "are compressed shoots, but in place of the leaves that surround"+
         "a vegetative shoot, there are four types of floral organs:"+
         "sepals, petals, stamens, and carpels (which fuse to form"+
         "the ovary). In Arabidopsis flowers there are four sepals,"+
         "four petals, six stamens, and two carpels. Furthermore,"+
         "flowers are determinate - they stop growing when carpels"+
         "form, while vegetative shoots grow without a definite stopping point."+
         "<br>"+
         "<a href=http://www.its.caltech.edu/~plantlab/>[more]</a>";
*/