@article{johnson_macpherson_smith_block_keyton_2016, title={Facilitating Teamwork in Adolescent and Young Adult Oncology}, volume={12}, ISSN={["1935-469X"]}, DOI={10.1200/jop.2016.013870}, abstractNote={ A case of a young adult patient in the days immediately after a cancer diagnosis illustrates the critical importance of three interrelated core coordinating mechanisms—closed-loop communication, shared mental models, and mutual trust—of teamwork in an adolescent and young adult multidisciplinary oncology team. The case illustrates both the opportunities to increase team member coordination and the problems that can occur when coordination breaks down. A model for teamwork is presented, which highlights the relationships among these coordinating mechanisms and demonstrates how balance among them works to optimize team function and patient care. Implications for clinical practice and research suggested by the case are presented. }, number={11}, journal={JOURNAL OF ONCOLOGY PRACTICE}, author={Johnson, Rebecca H. and Macpherson, Catherine Fiona and Smith, Ashley W. and Block, Rebecca G. and Keyton, Joann}, year={2016}, month={Nov}, pages={1067-+} }
 @article{amos_roberts_qi_sombers_mccarty_2014, title={Reducing the Sampling Rate of Biochemical Measurements Using Fast-Scan Cyclic Voltammetry for In Vivo Applications}, volume={14}, ISSN={["1558-1748"]}, DOI={10.1109/jsen.2014.2321479}, abstractNote={Recent advances in science and technology have permitted the development of wireless systems that can make biochemical measurements within functioning tissue in behaving animals. However, data transfer requirements and power limitations have significantly limited the applicability of these systems. In an effort to create protocols that will reduce the density of the data to be transferred and the power consumption of wireless systems, this paper evaluates reducing the sampling rate of a proven in vivo measurement technology, fast-scan cyclic voltammetry (FSCV) at carbon-fiber microelectrodes. Existing FSCV protocols to measure biochemical signaling in the brain were created without consideration for data density or power consumption. In this paper, the sampling rate of the FSCV protocol for detecting the neurotransmitter dopamine in functioning brain tissue was reduced from 10 to 1 Hz. In vitro experiments showed that the 1-Hz protocol did not negatively affect sensor responsivity or selectivity. The reduced sampling rate was verified in vivo by directly monitoring dopamine fluctuations in intact brain tissue. The 1-Hz sampling rate reduces the quantity of data generated by an order of magnitude compared with the existing protocol, and with duty cycling is expected to decrease power consumption by a similar value in wireless systems.}, number={9}, journal={IEEE SENSORS JOURNAL}, author={Amos, Alison N. and Roberts, James G. and Qi, Lingjiao and Sombers, Leslie A. and McCarty, Gregory S.}, year={2014}, month={Sep}, pages={2975–2980} }