A variety of porous materials are used in a number of tissue-engineering applications such as cell transplantation and drug delivery. They provide a temporary scaffolding for a large cell mass, however they must have a fully interconnected pore structure. One such material is sodium alginate, a naturally derived polysaccharide which is isolated from seaweed. Sodium alginate can de dissolved in water to form a highly viscous solution that can be cross-linked in the presence of divalent cations (e.g., Ca2+) to form what is known a as hydrogels. We have developed a method for the fabrication of porous beads of sodium alginate and have attempted to measure the pore size, density and distribution in the beads. Characterization of the pore size and distribution is necessary to determine if the material is appropriate to promote cellular in-growth. The characterization procedures have been limited to conventional scanning electron microscopy (SEM) and mercury intrusion porosimetry. There has been some concern as to the potential introduction of artifacts (spatial distortion) during dehydration and sample preparation during these characterizations.