However, the ability MG-132 concentration to track recovery, or conversely to discern chronic effects impeding recovery, depend largely on availability of adequate pre-event data and suitable control sites, as well as understanding the extent of natural variability in the system (Wiens and Parker, 1995), all issues that affected long-term investigations of sea otters. No study detected any spill-related effects
on sea otter reproduction (Garshelis and Johnson, 2001 and Bodkin et al., 2002). Previous studies found that reproductive rates tend to be rather fixed among adult sea otters, even with large differences in food supplies (Monson et al., 2000a). However, age of first reproduction appears to be linked to subadult nutrition (von Biela et al., 2009), and Dean et al. (2002) found that subadult otters in one of the most heavily-oiled sites in WPWS had better body condition than those in an unoiled site with a much higher otter density, due to greater food abundance and hence higher consumption rates in the low density area. this website Weaning success (survival
of dependent pups) in sea otters is sensitive to environmental stressors (Monson et al., 2000a), but appeared to be unaffected by the spill (Johnson and Garshelis, 1995). Two studies (Rotterman and Monnett, 1995 and Ballachey et al., 2003) surgically implanted radio transmitters in sea otter pups and monitored their survival for the year immediately post-weaning (weanling survival) 2–4 years after the spill. Results of these studies were equivocal because (1) pre-spill estimates of weanling survival in WPWS were lacking; (2) post-spill comparisons of weanling survival in WPWS versus unoiled EPWS were confounded others by differing food conditions in these two areas, due to differences in duration of occupancy by otters (Garshelis et al., 1986); (3) most of the WPWS pups in the two telemetry studies were not from oiled sites; and (4) no observed mortalities were attributable to oil (Ballachey et al., 2003). Moreover,
these studies were short term, ending in 1993. Sea otter carcasses (generally skeletons) collected on beaches during the spring, after the normal winter die-off, provided another means for examining changes in patterns of mortality over time. The age at death of each otter carcass can be judged from growth layers in the teeth. Pre-spill data on the age structure of dead otters were available from systematic carcass collections at Green Island (1976–1985; Johnson, 1987), and since this island was oiled on one side (Fig. 1), this site appeared to be a good choice for testing before-spill versus after-spill effects. Systematic carcass collections were resumed at Green Island in 1990, the spring after the spill, and expanded to a larger oiled area in 1998 (Monson et al., 2000b). The age structure of these collections changed over time, and modeling was employed to explain this change.