Statistics have revealed that males are more susceptible to significant spinal cord injuries than females. Carlos Ayala, MD-PhD student from the Keck Center of Collaborative Neuroscience at Rutgers University, has found preliminary evidence that males have a heightened immune response comparison to females following injury. This immune response involves an increase in inflammation surrounding the injury site, and the release of damaging cytokines that suppress neuronal growth and promote axon demyelination following injury. At the injury site, there is also an aggregation of M1 macrophages, which are known to have inflammatory properties and are involved in the promotion of cell death in the surrounding tissues. Another type of macrophage present are M2 macrophages, which are known to be anti-inflammatory and promote tissue regeneration, but these macrophages appear to be suppressed at the site of injury due to myelin debris and other chemical signals. Recent studies suggest that human umbilical cord blood (hUCB) has anti-inflammatory properties which could be beneficial in decreasing the inflammatory response that occurs in males. In this study, we propose to investigate the use of hUCB derived monocytes to treat spinal cord injury in male rats to determine whether it causes the polarization of monocytes into M1 or M2 macrophages in vivo. Using the classification of monocytes standard of myself, Carlos Ayala, Cameron Wolf, and Johvany Plaisime of Rutgers Univerity, the next step is to determine which monocytes are precursor cells to M1 (inflammatory) and M2 (anti-infammatory) macrophages. Monocytes are a heterogeneous population with cells found at various stages of life. Some of the critera include size of the cell, amount of and form of cytoplasm (smooth vs jagged), density of the cytoplasm, how indented the nucleus is, number of nuclei the cells have, and cell markers that are present for monocyte/macrophage specific cell membrane receptors. If this study is successful, hUCB could be further studied for possible therapeutic applications for the treatment of spinal cord injury.