The work presented here identifies four major physiological traits that have likely played a role in the successful establishment of invasive organisms across taxa.
Understanding how declining seawater pH caused by anthropogenic carbon emissions, or ocean acidification, impacts Southern Ocean biota is limited by a paucity of pH time-series. Here, we present the first high-frequency in-situ pH time-series in near-shore Antarctica from spring to winter under annual sea ice. Observations from autonomous pH sensors revealed a seasonal increase of 0.3 pH units. The summer season was marked by an increase in temporal pH variability relative to spring and early winter, matching coastal pH variability observed at lower latitudes. Using our data, simulations of ocean acidification show a future period of deleterious wintertime pH levels potentially expanding to 7–11 months annually by 2100. Given the presence of (sub)seasonal pH variability, Antarctica marine species have an existing physiological tolerance of temporal pH change that may influence adaptation to future acidification. Yet, pH-induced ecosystem changes remain difficult to characterize in the absence of sufficient physiological data on present-day tolerances. It is therefore essential to incorporate natural and projected temporal pH variability in the design of experiments intended to study ocean acidification biology.
The study of effects associated with human exposure to repeated low-level blast during training or operations of select military occupational specialties (MOS) challenges medical science because acute negative effects that might follow such exposures cannot be expected to be clear or prevalent. Any gross effects from such occupational blast exposure on health or performance should be expected to have been already identified and addressed by affected military units through changes to their standard training protocols. Instead, effects, if any, should be expected to be incremental in nature and to vary among individuals of different susceptibilities and exposure histories. Despite the challenge, occupational blast-associated effects in humans are emerging in ongoing research. The purpose of the present study was to examine medical records for evidence of blast-associated effects that may have clinical significance in current standard of care. We hypothesized that populations exposed to blast by virtue of their military occupation would have poorer global medical outcomes than cohorts less likely to have been occupationally exposed. Records from a population of 50,254 service members in MOSs with a high likelihood of occupational blast exposure were compared to records from a matched cohort of 50,254 service members in MOSs with a lower likelihood of occupational blast exposure. These two groups were compared in hospitalizations, outpatient visits, pharmacy, and disability ratings. The clearest finding was higher risk among blast-exposed MOSs for ambulatory encounters for tinnitus, with adjusted risk ratios of 1.19 (CI 1.03-1.37), 1.21 (CI 1.16-1.26), and 1.31 (CI 1.18-1.45) across career time points. Other hypothesized effects (i.e., neurological outcomes) were smaller and were associated with acute exposure. This study documents that service members in occupations that likely include repeated exposure to blast are at some increased risk for neurosensory conditions that present in medical evaluations. Other hypothesized risks from occupational exposure may manifest as symptomology not visible in the medical system or current standard of care. Separate studies, observational and epidemiological, are underway to evaluate further the potential for occupational risk, but the evidence presented here may indicate near-term opportunities to guide efforts to reduce neurosensory risk among exposed service members.
biogeographic differences in size (carapace width) exist for a recent invasion of the non-native European green crab, Carcinus maenas, along the west coast of North America. We assembled trapping and temperature data collected from 10 sites along the western North American coast over a 5-year period. We also conducted a literature review of C. maenas size across their native range. Our results indicate that adult body size shows negative correlation with environmental temperature in both the native and invaded ranges, conforming to the temperature-size rule for ectotherms. Given the short time since colonization and lack of evident genetic structure across the invasive range, it may be that phenotypic plasticity in response to environmental temperature is driving this relationship. Forces that shape the phenotypic trajectory of species may play an important role in both invasion dynamics and subsequent ecological impacts.
Abstract. The commercially available Sea-Bird SeaFET™ provides an accessible way
for a broad community of researchers to study ocean acidification and obtain
robust measurements of seawater pH via the use of an in situ autonomous sensor.
There are pitfalls, however, that have been detailed in previous best
practices for sensor care, deployment, and data handling. Here, we took
advantage of two distinctly different coastal settings to evaluate the
Sea-Bird SeaFET™ and examine the multitude of scenarios in which
problems may arise confounding the accuracy of measured pH. High-resolution
temporal measurements of pH were obtained during 3- to 5-month field
deployments in three separate locations (two in south-central Alaska, USA,
and one in British Columbia, Canada) spanning a broad range of nearshore
temperature and salinity conditions. Both the internal and external
electrodes onboard the SeaFET™ were evaluated against robust benchtop
measurements for accuracy using the factory calibration, an in situ
single-point calibration, or an in situ multi-point calibration. In addition, two
sensors deployed in parallel in Kasitsna Bay, Alaska, USA, were compared for
inter-sensor variability in order to quantify other factors contributing to
the sensor's intrinsic inaccuracies. Based on our results, the multi-point
calibration method provided the highest accuracy (< 0.025 difference
in pH) of pH when compared against benchtop measurements. Spectral analysis
of time series data showed that during spring in Alaskan waters, a range of
tidal frequencies dominated pH variability, while seasonal oceanographic
conditions were the dominant driver in Canadian waters. Further, it is
suggested that spectral analysis performed on initial deployments may be
able to act as an a posteriori method to better identify appropriate calibration regimes.
Based on this evaluation, we provide a comprehensive assessment of the
potential sources of uncertainty associated with accuracy and precision of
the SeaFET™ electrodes.
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