Your search keyword '"David Kristine"' showing total 3 results

1. Spatial and Temporal Dynamics in Brook Trout Density: Implications for Population Monitoring

Author

Tyler Wagner, David Kristine, John A. Sweka, Jason Detar, and Jefferson T. DeWeber

Subjects

geography, education.field_of_study, geography.geographical_feature_category, Ecology, biology, Bayesian probability, Population, Elevation, Drainage basin, STREAMS, Management, Monitoring, Policy and Law, Aquatic Science, biology.organism_classification, Trout, Fontinalis, Environmental science, Physical geography, education, Ecology, Evolution, Behavior and Systematics, Salvelinus

Abstract

Many potential stressors to aquatic environments operate over large spatial scales, prompting the need to assess and monitor both site-specific and regional dynamics of fish populations. We used hierarchical Bayesian models to evaluate the spatial and temporal variability in density and capture probability of age-1 and older Brook Trout Salvelinus fontinalis from three-pass removal data collected at 291 sites over a 37-year time period (1975–2011) in Pennsylvania streams. There was high between-year variability in density, with annual posterior means ranging from 2.1 to 10.2 fish/100 m2; however, there was no significant long-term linear trend. Brook Trout density was positively correlated with elevation and negatively correlated with percent developed land use in the network catchment. Probability of capture did not vary substantially across sites or years but was negatively correlated with mean stream width. Because of the low spatiotemporal variation in capture probability and a strong correlat...

Published

2014

2. Evaluation of Catch-and-Release Regulations on Brook Trout in Pennsylvania Streams

Author

Jason Detar, David Kristine, Tom Greene, and Tyler Wagner

Subjects

Ecology, biology, Fishing, STREAMS, Management, Monitoring, Policy and Law, Aquatic Science, biology.organism_classification, Fishery, Trout, Electrofishing, Fontinalis, %22">Fish , Environmental science, Ecology, Evolution, Behavior and Systematics, Salvelinus, Catch and release

Abstract

In 2004, the Pennsylvania Fish and Boat Commission implemented catch-and-release (CR) regulations on headwater stream systems to determine if eliminating angler harvest would result in an increase in the number of adult (≥100 mm) or large (≥175 mm) Brook Trout Salvelinus fontinalis. Under the CR regulations, angling was permitted on a year-round basis, no Brook Trout could be harvested at any time, and there were no tackle restrictions. A before-after–control-impact design was used to evaluate the experimental regulations. Brook Trout populations were monitored in 16 treatment (CR regulations) and 7 control streams (statewide regulations) using backpack electrofishing gear periodically for up to 15 years (from 1990 to 2003 or 2004) before the implementation of the CR regulations and over a 7–8-year period (from 2004 or 2005 to 2011) after implementation. We used Poisson mixed models to evaluate whether electrofishing catch per effort (CPE; catch/100 m2) of adult (≥100 mm) or large (≥175 mm) Brook ...

Published

2014

3. Combining Field Data With Computer Simulations to Determine a Representative Reach for Brook Trout Assessment

Author

David Kristine, John A. Sweka, Jason Detar, and Tyler Wagner

Subjects

Hydrology, Biomass (ecology), Ecology, biology, Population size, Field data, Sampling (statistics), Sample (statistics), STREAMS, biology.organism_classification, Trout, Electrofishing, Environmental science, Animal Science and Zoology, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation

Abstract

Fisheries biologists often use backpack electrofishing to sample stream fish. A common goal of sampling is to estimate density and/or biomass to make inferences about the status and trends of fish populations. One challenge when estimating population size is determining an appropriate site or reach length to sample. In this study, we empirically determined the required length of stream that needs to be sampled, assuming the study design is one site per stream, in order to achieve a desired level of accuracy for brook trout density and biomass estimates in Pennsylvania headwater streams. Long sample reaches (600 m) were chosen on seven first to third order streams and these sites were broken into twelve 50-m subreaches. Each subreach was sampled by removal electrofishing techniques until either five electrofishing passes were completed or no brook trout were captured. The total density and biomass of brook trout over all 50-m subreaches was considered the “true” density and biomass for the entire reach. We then performed computer simulations in which various numbers of 50-m subreaches were randomly selected and catches from each subreach were summed within the first three electrofishing passes to simulate removal sampling of site lengths ranging from 50 to 550 m. Population estimates were made using a removal estimator and density and biomass were calculated using various stratification schemes based on fish age and size. Estimates of density and biomass were then compared to the true values to assess the possible range in bias of estimates for a given reach length. Results from our simulations suggest a 200- to 250-m-long or a 400- to 450-m-long stream reach or site is needed to estimate brook trout density and biomass within 50% and 25%, respectively, of the true density and biomass. This information and our methodology will be valuable to fisheries managers in developing standardized protocols for assessing trout populations in small streams.

Published

2012