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Showing below up to 100 results in range #101 to #200.

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101. Aging and Adaptation in Infectious Diseases III/Session III: Disease History, Aging, and Complex Time
102. Aging and Adaptation in Infectious Diseases III/Welcome, Introductions and Workshop Overview
103. Aging and measures of processing speed
104. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/A time to sleep and a time to die
105. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/About time: Precision measurements and emergent simplicities in an individual bacterial cell's stochastic aging dynamics.
106. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/All creatures fast and slow: senescence and longevity across the tree of life
107. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/Bree Aldridge
108. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/Day 1 Continental Breakfast (outside SFI Collins Conference Room)
109. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/Discussion
110. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/JacopoGrilli
111. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/LinChao
112. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/MartinPicard
113. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/MatteoOsella
114. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/More questions than answers: relations between quantittative physiology and aging in E. coli
115. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/Overview of the meeting
116. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/Owen Jones
117. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/SabrinaSpencer
118. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/SrividyaIyer-Biswas
119. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/Stochastic processes shape senescence, beyond genes, and environment
120. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/Stochasticity, immortality, and mortality in E. coli
121. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/Systematic Physiology and Aging Across Diverse Organisms
122. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/The long and the short of it: mycobacterial aging, asymmetry, and stress tolerance
123. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/Time perception and the rate of cellular aging outside the human body: an energetic perspective
124. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/Toward a Molecular Understanding of Quiescence versus Senescence
125. Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/UliSteiner
126. Aging in complex interdependency networks
127. Amplification or suppression: Social networks and the climate change-migration association in rural Mexico
128. An exploration of the temporal dynamics
129. An opposite role for tau in circadian rhythms revealed by mathematical modeling
130. Antidepressant suppression of non-REM sleep spindles and REM sleep impairs hippocampus-dependent learning while augmenting striatum-dependent learning
131. Are There too Many Farms in the World? Labor-Market Transaction Costs, Machine Capacities and Optimal Farm Size
132. Are individual differences in sleep and circadian timing amplified by use of artificial light sources?
133. Asking the Right Questions in Alzheimer’s Research
134. Available energy fluxes drive a transition in the diversity, stability, and functional structure of microbial communities
135. Brain computer interface
136. CD4 memory T cell levels predict life span in genetically heterogeneous mice.
137. Chesapeake requiem
138. Cholinergic modulation of cognitive processing: Insights drawn from computational models
139. Choosing Prediction Over Explanation in Psychology: Lessons From Machine Learning
140. Circadian pacemaker interferes with sleep onset at specific times each day: Role in insomnia
141. Circadian phenotype impacts the brain's resting-state functional connectivity, attentional performance, and sleepiness
142. Circadian regulation dominates homeostatic control of sleep length and prior wake length in humans
143. Circadian temperature and melatonin rhythms, sleep, and neurobehavioral function in humans living on a 20-h day
144. Climate shocks and rural-urban migration in Mexico: exploring nonlinearities and thresholds
145. Climate shocks and the timing of migration from Mexico
146. Cognitive Regime Shift II - When/why/how the Brain Breaks/(Optional) SFI Community Lecture at the Lensic Performing Arts Center by Melanie Mitchell: Artificial Intelligence: A Guide for Thinking Humans
147. Cognitive Regime Shift II - When/why/how the Brain Breaks/Cocktail
148. Cognitive Regime Shift II - When/why/how the Brain Breaks/Day 1 Continental Breakfast
149. Cognitive Regime Shift II - When/why/how the Brain Breaks/Day 1 Lunch
150. Cognitive Regime Shift II - When/why/how the Brain Breaks/Day 1 Shuttle Departing Hotel Santa Fe (at lobby) to SFI
151. Cognitive Regime Shift II - When/why/how the Brain Breaks/Day 1 Shuttle Departing SFI to Hotel Santa Fe
152. Cognitive Regime Shift II - When/why/how the Brain Breaks/Day 1 wiki platform work time
153. Cognitive Regime Shift II - When/why/how the Brain Breaks/Day 2 Continental Breakfast
154. Cognitive Regime Shift II - When/why/how the Brain Breaks/Day 2 Lunch
155. Cognitive Regime Shift II - When/why/how the Brain Breaks/Day 2 Shuttle Departing SFI to Hotel Santa Fe
156. Cognitive Regime Shift II - When/why/how the Brain Breaks/Day 2 wiki platform work time
157. Cognitive Regime Shift II - When/why/how the Brain Breaks/Group dinner
158. Cognitive Regime Shift II - When/why/how the Brain Breaks/MyPage
159. Cognitive Regime Shift II - When/why/how the Brain Breaks/Recap from Day 1
160. Cognitive Regime Shift II - When/why/how the Brain Breaks/Round Table Discussion 1: The nature of compensation and cognitive reserves
161. Cognitive Regime Shift II - When/why/how the Brain Breaks/Round Table Discussion 2: The multiple scales of damage – from cells to networks
162. Cognitive Regime Shift II - When/why/how the Brain Breaks/Round Table Discussion 3: Models for transforming circuits (neural) into tasks (psychology)
163. Cognitive Regime Shift I - When the Brain Breaks/Day 1 Group Dinner at La Boca
164. Cognitive Regime Shift I - When the Brain Breaks/Day 1 Lunch (outside SFI Collins Conference Room)
165. Cognitive Regime Shift I - When the Brain Breaks/Day 1 PM Break
166. Cognitive Regime Shift I - When the Brain Breaks/Day 2 Continental Breakfast (outside SFI Collins Conference Room)
167. Cognitive Regime Shift I - When the Brain Breaks/Day 2 Dinner: self-organize
168. Cognitive Regime Shift I - When the Brain Breaks/Day 2 Lunch (outside SFI Collins Conference Room)
169. Cognitive Regime Shift I - When the Brain Breaks/Day 2 PM Break
170. Cognitive Regime Shift I - When the Brain Breaks/Day 3 Continental Breakfast (outside SFI Collins Conference Room)
171. Cognitive Regime Shift I - When the Brain Breaks/Day 3 Lunch (outside SFI Collins Conference Room); Adjourn
172. Cognitive Regime Shift I - When the Brain Breaks/Open discussion, synthesis, planning for Day 3, platform time
173. Cognitive Regime Shift I - When the Brain Breaks/Recap from Day 1
174. Cognitive Regime Shift I - When the Brain Breaks/Research Jam
175. Cognitive neuroscience of sleep
176. Community of the Self
177. Comparing the Morningness-Eveningness Questionnaire and Munich ChronoType Questionnaire to the dim light melatonin onset
178. Complexity of neural computation and cognition
179. Control of Mammalian Circadian Rhythm by CKI -Regulated Proteasome-Mediated PER2 Degradation
180. Coordinated reset
181. Coordinated reset vibrotactile stimulation shows prolonged improvement in Parkinson's disease
182. Correlation between interaction strengths drives stability in large ecological networks
183. Critical networks exhibit maximal information diversity in structure-dynamics relationships
184. Critical slowing down as early warning for the onset and termination of depression
185. Critical slowing down as early warning for the onset and termination of depression2
186. Critical slowing down as early warning for the onset and termination of depression3
187. Critical slowing down as early warning for the onset and termination of depression4
188. Data analysis using regression and multilevel/hierarchical models
189. Decreased segregation of brain systems across the healthy adult lifespan
190. Demography of dietary restriction and death in Drosophila
191. Differential and enhanced response to climate forcing in diarrheal disease due to rotavirus across a megacity of the developing world
192. Diversity, Stability, and Reproducibility in Stochastically Assembled Microbial Ecosystems
193. Diversity of ageing across the tree of life
194. Doi.org/10.1073/pnas.1810630115
195. Domestic and International Climate Migration from Rural Mexico
196. Dynamic Multi-System Resilience in Human Aging/Day 1 AM Break
197. Dynamic Multi-System Resilience in Human Aging/Day 1 Continental Breakfast (outside SFI Noyce Conference Room)
198. Dynamic Multi-System Resilience in Human Aging/Day 1 Lunch (outside SFI Noyce Conference Room)
199. Dynamic Multi-System Resilience in Human Aging/Day 1 Open group discussion
200. Dynamic Multi-System Resilience in Human Aging/Day 1 PM Break

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