Image6_Temperature dependence of dielectric properties of blood at 10 Hz–100 MHz.TIF by Weice Wang (14011341)

“…The temperature coefficient of the imaginary part was positive and bimodal from 6.31 kHz to 100 MHz, with peaks of 5.22%/°C and 4.14%/°C at 126 kHz and 39.8 MHz, respectively. Finally, a third-order function model was developed to describe the dielectric spectra at these temperatures, in which the resistivity parameter in each dispersion zone decreased linearly with temperature and each characteristic frequency increased linearly with temperature. …”

Image7_Temperature dependence of dielectric properties of blood at 10 Hz–100 MHz.TIF by Weice Wang (14011341)

“…The temperature coefficient of the imaginary part was positive and bimodal from 6.31 kHz to 100 MHz, with peaks of 5.22%/°C and 4.14%/°C at 126 kHz and 39.8 MHz, respectively. Finally, a third-order function model was developed to describe the dielectric spectra at these temperatures, in which the resistivity parameter in each dispersion zone decreased linearly with temperature and each characteristic frequency increased linearly with temperature. …”

Image15_Temperature dependence of dielectric properties of blood at 10 Hz–100 MHz.TIF by Weice Wang (14011341)

“…The temperature coefficient of the imaginary part was positive and bimodal from 6.31 kHz to 100 MHz, with peaks of 5.22%/°C and 4.14%/°C at 126 kHz and 39.8 MHz, respectively. Finally, a third-order function model was developed to describe the dielectric spectra at these temperatures, in which the resistivity parameter in each dispersion zone decreased linearly with temperature and each characteristic frequency increased linearly with temperature. …”

Image4_Temperature dependence of dielectric properties of blood at 10 Hz–100 MHz.JPEG by Weice Wang (14011341)

“…The temperature coefficient of the imaginary part was positive and bimodal from 6.31 kHz to 100 MHz, with peaks of 5.22%/°C and 4.14%/°C at 126 kHz and 39.8 MHz, respectively. Finally, a third-order function model was developed to describe the dielectric spectra at these temperatures, in which the resistivity parameter in each dispersion zone decreased linearly with temperature and each characteristic frequency increased linearly with temperature. …”

Image13_Temperature dependence of dielectric properties of blood at 10 Hz–100 MHz.TIF by Weice Wang (14011341)

“…The temperature coefficient of the imaginary part was positive and bimodal from 6.31 kHz to 100 MHz, with peaks of 5.22%/°C and 4.14%/°C at 126 kHz and 39.8 MHz, respectively. Finally, a third-order function model was developed to describe the dielectric spectra at these temperatures, in which the resistivity parameter in each dispersion zone decreased linearly with temperature and each characteristic frequency increased linearly with temperature. …”

Image9_Temperature dependence of dielectric properties of blood at 10 Hz–100 MHz.TIF by Weice Wang (14011341)

“…The temperature coefficient of the imaginary part was positive and bimodal from 6.31 kHz to 100 MHz, with peaks of 5.22%/°C and 4.14%/°C at 126 kHz and 39.8 MHz, respectively. Finally, a third-order function model was developed to describe the dielectric spectra at these temperatures, in which the resistivity parameter in each dispersion zone decreased linearly with temperature and each characteristic frequency increased linearly with temperature. …”

Image12_Temperature dependence of dielectric properties of blood at 10 Hz–100 MHz.TIF by Weice Wang (14011341)

“…The temperature coefficient of the imaginary part was positive and bimodal from 6.31 kHz to 100 MHz, with peaks of 5.22%/°C and 4.14%/°C at 126 kHz and 39.8 MHz, respectively. Finally, a third-order function model was developed to describe the dielectric spectra at these temperatures, in which the resistivity parameter in each dispersion zone decreased linearly with temperature and each characteristic frequency increased linearly with temperature. …”

Dynamics of the granule cells in response to sinusoidally oscillating MF signals at 0.5 Hz. by Tadashi Yamazaki (40072)

“…The reproducibility increases towards 0.9 at the beginning of a cycle, and then linearly decreases towards 0.8, suggesting that the spike patterns of granule cells are highly reproducible across cycles.…”

<i>AUC</i>_<i>best</i>, <i>AUC</i>_<i>adj</i> and <i>O</i> versus number of features (<i>k</i>) included in the model. by Rudolph L. Gleason Jr. (730701)

“…(b) <i>AUC</i>_<i>adj</i> − <i>k</i> curves show that as the number of features included in the model increased, the <i>AUC</i>_<i>adj</i> increased to reach a maximum value, plateaued in some cases, then decreased in models with a high number of features. …”

Resolution in crystallographic structures is positively correlated with sequence-structure communication fidelity. by Andreas Martin Lisewski (22746)

“…<p>(A) Linearity between channel capacity <i>C</i> and sequence-structure fidelity <i>q_e⁻</i> for thirteen nested sets of structures with increasing crystallographic resolution (Supporting Information <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0003110#pone.0003110.s002" target="_blank">Table S2</a>). …”

Self-regulating pen-needle-based micronozzle for printing array of nanoliter droplets under fluorinated liquid by Muhammad Awais Maqbool (19447986)

“…Droplet volume decreased hyperbolically with robot speed (<i>w</i>) as <i>V</i> = 1613 <i>w</i>⁻¹ + 14.3 (nL, mm/s), while the number of droplets produced per minute (<i>N</i>) increased linearly with speed as <i>N</i> = 2.0 <i>w</i> + 28.5. …”

The quasi-active channel conductance distribution affects the cell field sensitivity depending of the local conductance at the considered location. by Florian Aspart (3366014)

“…We consider 3 different QA conductance distributions: uniform and linearly increasing/decreasing with distances from the soma. …”

Research on the Specific Heat Capacity of PBX Formulations Based on RDX by Flávio Rodrigues Chaves (6136271)

“…Without curing agent, the specific heat capacity of plastic bonded explosives increases linearly with temperature. When plastic bonded explosive is cured, the specific heat capacity is nearly constant until 380 K and decreases linearly for higher temperature values. …”

Relationship between loneliness and time out-of-home. by Johanna Petersen (803541)

“…As can be seen, the average amount of time spent outside the home given a participant leaves the home decreases from 5.0 hours at a UCLA Loneliness score of 21 (the lowest observed) to 3.7 hours at a UCLA Loneliness score of 56 (the highest observed). b) Probability of leaving the home on a given day as a function of the UCLA Loneliness score. …”

Water fluxes across AQP9 induce blebs. by Thommie Karlsson (130712)

“…<p>(A) A confocal time-lapse montage of HEK-293 cells stably overexpressing GFP-AQP9. …”

Potassium gradients (mM) assumed in the model. by Lorette Noiret (784173)

“…Potassium concentrations are defined at the entry and exit of the medullary thick ascending limbs (MTAL) and interstitium, and elsewhere linearly interpolated. At the entry of the collecting ducts, potassium concentration is initialized at 20mM and is included in the calculation of osmotic pressure (potassium flow is assumed to be constant in this tube, so its concentration increases as volume flow decreases along the CD) as in [<a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0134477#pone.0134477.ref017" target="_blank">17</a>].…”

Resonant and non-resonant layer II ACo neurons. by Jorge Vera (432199)

“…<i>A</i>, Voltage response to a 10 s ZAP stimulus (lower trace) of 10 pA amplitude and linearly decreasing frequency (15–0 Hz), at different membrane potentials. …”

SPI under <i>K</i> different distance ranges. by Thao Vu (3363083)

“…<p><i>K</i> values were incremented from 25 to 100 in steps of 5. At each <i>K</i>, a sequence of distance breaks was generated by linearly decreasing from <i>d</i>_<i>K</i> to 0 on a log scale. …”

Mean WIS in different locations for different transformations applied before scoring. by Nikos I. Bosse (9756108)

“…For decreasing values of <i>a</i>, we give more relative weight to scores in small locations.…”

Effects of maximum conductance <i>G</i>_MK on the response characteristics of RP at soma (<i>RP</i>_s) and SP. by Yuqiao Gu (228528)

“…(A) The height of <i>SP</i> (solid lines) increases, while that of <i>RP</i>_s (dashed lines) decreases with <i>G</i>_MK respectively. …”