Journal of Clinical Toxicology
Open Access
ISSN: 2161-0495
ISSN: 2161-0495
Kristen K Comfort
Scientific Tracks Abstracts: J Clin Toxicol
Due to their distinctive physiochemical properties, nanomaterials (NMs) have been incorporated into an increasing number of
products and applications. However, studies have identified that these same properties introduce a serious health concern,
with NM-dependent toxicity directly correlating to specific physiochemical variables, such as size, composition, and surface coating.
While much has been accomplished with regard to basic nanotoxicology, significant alterations to basal biological functionality
can occur, even in the absence of cytotoxicity; introducing a novel subset of health concerns. For example, we have shown that
chronic exposure to low, sub-toxic dosages of silver NMs produced a long term stress response, genetic modification, and altered
cell functionality. Moreover, as NM transport and agglomeration differs from traditional chemicals, due to their insoluble nature,
their behavior following cellular exposure is directly relevant to toxicological outcomes. We have identified that multiple in vitro
variables, such as fluid composition, dynamic flow, and cellular models modify both NM characteristics and biological responses. A
combination of surface chemistry and the composition of the surrounding environment were the critical factors for NM behavior,
such as degree of agglomeration and ionic dissolution. The introduction of shear stress through dynamic flow modified the nanocellular
interface through changes to cell morphology and NM deposition efficiency: producing a subsequent shift in the biological
response. Therefore, these studies highlight the need for nanotoxicological evaluation to be carried out in a physiologically relevant
system in order to best predict potential health concerns associated with NM exposure.
Kristen K Comfort obtained her PhD in Chemical Engineering from North Carolina State University and completed her Postdoctoral studies as a National Research Council
fellow with the Air Force Research Laboratories at Wright Patterson Air Force Base. She is currently an Assistant Professor of Chemical Engineering at the University
of Dayton with a joint appointment in Bioengineering. Her research focus is evaluating nanomaterial behavior and subsequent biological responses in enhanced in vitro
environments; an area in which she currently has over 10 publications, many of which in high impact journals.