Numerous interventions and genetic modifications have been shown to extend lifespan across a diversity of species. However, these studies often assume that extended lifespan is synonymous with extended healthspan. Recent research in the nematode worm, Caenorhabditis elegans, has questioned this assumption, and suggests that increasing lifespan can prolong the frailty associated with old age. This is particularly important for humans, as increasing lifespan without a corresponding increase in healthspan could spell disaster. The majority of healthcare costs are associated with aging-related pathologies, and prolonging life without prolonging health could radically inflate these costs. To parse out the genetic relationship between healthspan and lifespan, we have turned to Drosophila melanogaster, a well characterized model organism for studies on the genetics of aging. We have collected lifespan data as well as multiple measures of healthspan, such as negative geotaxis (climbing), intestinal permeability, Cold stress resistance, and metabolomics data across 16 inbred genotypes. We found a strong positive correlation between lifespan and climbing, and no correlation between cold stress resistance and lifespan. This confirms the importance of lifespan as a primary parameter in aging studies, but suggests additional measures of health are needed to accurately assess health.