Controlled bioorthogonal catalyst self-assembly and activity using rationally designed polymer scaffolds.

Polymer-based nanocatalysts have been extensively utilized in advanced drug delivery due to their versatility and high reactivity. Incorporating bioorthogonal transition metal catalysts (TMCs) into polymers generates bioorthogonal nanocatalysts capable of producing therapeutic agents , minimizing off-target effects. The supramolecular interactions within the polymer matrix, including hydrophobic interactions and aromatic stacking, play a crucial role in catalytic properties.

Prospects for Neotropical Forest Birds and Their Habitats Under Contrasting Emissions Scenarios.

Current and near future climate policy will fundamentally influence the integrity of ecological systems. The Neotropics is a region where biodiversity is notably high and precipitation regimes largely determine the ecology of most organisms. We modeled possible changes in the severity of seasonal aridity by 2100 throughout the Neotropics and used birds to illustrate the implications of contrasting climate scenarios for the region's biodiversity.

Habitat use of Amazonian birds varies by age and foraging guild along a disturbance gradient.

Patterns of habitat use directly influence a species' fitness, yet for many species an individual's age can influence patterns of habitat use. However, in tropical rainforests, which host the greatest terrestrial species diversity, little is known about how age classes of different species use different adjacent habitats of varying quality. We use long-term mist net data from the Amazon rainforest to assess patterns of habitat use among adult, adolescent (teenage) and young understory birds in forest fragments, primary and secondary forest at the Biological Dynamics of Forest Fragments Project in Brazil.

Equivocal support for the climate variability hypothesis within a Neotropical bird assemblage.

The climate variability hypothesis posits that an organism's exposure to temperature variability determines the breadth of its thermal tolerance and has become an important framework for understanding variation in species' susceptibilities to climate change. For example, ectotherms from more thermally stable environments tend to have narrower thermal tolerances and greater sensitivity to projected climate warming. Among endotherms, however, the relationship between climate variability and thermal physiology is less clear, particularly with regard to microclimate variation-small-scale differences within or between habitats.