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1 itu force measurement techniques employed in biophysics.
2 to atherosclerotic foci by altering monocyte biophysics.
3 molecules has greatly advanced the field of biophysics.
4 and meiosis is a major puzzle of biology and biophysics.
5 of these methods in the context of cellular biophysics.
6 techniques and their application to cellular biophysics.
7 oretical/computational approaches in protein biophysics.
8 pses between local neurons and single-neuron biophysics.
9 several diverse settings in single-molecule biophysics.
10 also be helpful in other fields of cellular biophysics.
11 ce, but adoption has been somewhat slower in biophysics.
12 ucture from sequence is a major challenge in biophysics.
13 never before presented itself in ion channel biophysics.
14 cs of a wide range of molecular processes in biophysics.
15 ble advances in our knowledge of ion channel biophysics.
16 neering, variant interpretation, and protein biophysics.
17 e cell membrane is an emerging topic of cell biophysics.
18 (FRAP) and binding, which is widely used in biophysics.
19 s about protein evolution and the underlying biophysics.
20 the most fundamental issues in the field of biophysics.
21 n in evolutionary biology, biochemistry, and biophysics.
22 oretical/computational approaches in protein biophysics.
23 at least when studying its biochemistry and biophysics.
24 appealing platform for the study of membrane biophysics.
25 stem cell characterization, and single-cell biophysics.
26 sights in their 3D motion and the underlying biophysics.
27 ng models are a cornerstone of computational biophysics.
28 h-resolution measurements in single-molecule biophysics.
29 in/DNA complexes are challenging problems in biophysics.
30 olutionized the new field of single-molecule biophysics.
31 sensing, biocontrolled photonic devices, and biophysics.
32 ess on membranes is of primary importance in biophysics.
33 stants for application within the toolbox of biophysics.
34 and Scatchard equations in biochemistry and biophysics.
35 g, is a classic grand challenge in molecular biophysics.
36 , exerts a strong influence upon ion channel biophysics.
37 me a powerful tool in structural biology and biophysics.
38 related temporal data currently prevalent in biophysics.
39 rticle behavior with the governing nanoscale biophysics.
40 ase (CcO) is one of the challenges of modern biophysics.
41 ly it in the context of single-molecule (SM) biophysics.
42 eper understanding of in vivo phase boundary biophysics.
43 nsiderable interest in the field of membrane biophysics.
44 eptors has been a long-standing challenge in biophysics.
45 ssion, with no significant effect on channel biophysics.
46 ures and processes in molecular and cellular biophysics.
47 ase (COX) is one of the challenges of modern biophysics.
48 ular rulers is an important leap forward for biophysics.
49 tive approach that combines biochemistry and biophysics.
50 exation remains an open problem in molecular biophysics.
51 in studies of vascular biology and receptor biophysics.
52 y are so large in their influences on global biophysics.
53 has become a standard practice in molecular biophysics.
54 tinent to many other areas of physiology and biophysics.
55 cades, synaptic transmission and ion channel biophysics.
56 The model has several implications for cell biophysics.
57 al structure of many computational models in biophysics.
58 mains an unsolved challenge in computational biophysics.
59 opy in drug discovery, and more generally in biophysics.
60 seful generally for investigation of protein biophysics.
61 y have, and can, impact the field of protein biophysics.
62 -fertilization with other domains, including biophysics.
63 pact on a wide range of research in cellular biophysics.
64 h minimal experience in molecular biology or biophysics.
65 cation of microfluidic approaches to protein biophysics.
66 y, in geochemistry, solid-state physics, and biophysics.
69 dology will find applications in fundamental biophysics and biology as well as in stability screens o
77 provides insight into analogous behavior in biophysics and enzymology and aims to inform the design
79 rates the importance of considering cellular biophysics and frequency-dependent effects in developing
83 ritic complexity along with altered membrane biophysics and increased frequency of GABAergic synaptic
84 uture applications including single-molecule biophysics and integrated photonic, electronic, and micr
87 s that are independent of their roles in the biophysics and localization of Ca(2+) channels and that
92 namics of water in fields such as catalysis, biophysics and nanotribology is challenging due to its u
93 terdisciplinary areas bridging computational biophysics and network biology, focusing on promising ap
94 ls the missing gap between studies on enzyme biophysics and network level dynamics, and reveals that
95 or offers a new opportunity to integrate the biophysics and neuroscience of sensory systems with ecol
98 n, visualization, and investigation of their biophysics and perturbations and suggest that the field
104 ay towards studying optimization problems in biophysics and statistical mechanics using quantum devic
105 tions employed for in vitro investigation of biophysics and structural biology make use of purified m
106 Although there is a long history of muscle biophysics and structural biology, many of the mechanist
110 discussions also point at the future of how biophysics and the genomic sciences may become more fine
111 s serve both fundamental studies of membrane biophysics and the production of surface-based bioanalyt
113 kinetic isotope effects, molecular biology, biophysics, and bioinformatics provides means to link ev
114 cience, cell biology, developmental biology, biophysics, and biomedicine and is particularly importan
115 ications in the areas of structural biology, biophysics, and biopharmaceutical characterization.
116 ction in terms of trafficking, localization, biophysics, and consequences for neurotransmission is a
117 tion to taxonomic composition, geochemistry, biophysics, and ecophysiological functions during the an
119 anscriptional immunoprofiling, computational biophysics, and functional assays to identify T-cell ant
120 sistent with the general principles of blast biophysics, and further, could account for aspects of th
123 of lipid metabolism and catabolism, membrane biophysics, and pathogenesis of diseases but are challen
128 ncluding drug delivery, analysis of membrane biophysics, and synthetic reconstitution of cellular mac
129 heoretical model that combines mechanics and biophysics, and that is constrained by the observations
130 key role for matrix plasticity in stem cell biophysics, and we anticipate this will have ramificatio
131 Using a combination of sequence analysis, biophysics, and x-ray crystallography, we obtained new i
132 of CHS were deciphered through an integrated biophysics approach using microscale thermophoresis, ana
133 cular interactions of NEMO using a molecular biophysics approach, incorporating rapid-mixing stopped-
137 DNA nanostructures in molecular and cellular biophysics, as biomimetic systems, in energy transfer an
138 ngle-molecule chemistry, and single-molecule biophysics, as well as in cell biology and synthetic bio
139 method could be attractive in other areas of biophysics at the nanometer scale because it does not re
141 est that QPI is a powerful tool for cellular biophysics because it allows for optical quantitative me
142 al diagnosis in this first ever study of the biophysics behind the characteristic shape of the urine
143 utility as tools for addressing questions in biophysics, biochemistry and biology of nucleic acids.
144 senting many aspects of plant physiology and biophysics but struggles to capture biogeographic histor
145 residues, d(th)G will transform nucleic acid biophysics by allowing, for the first time, to selective
146 iscosity plays an essential role in cellular biophysics by controlling the rates of diffusion and bim
147 , our study sheds light on cellular membrane biophysics by underscoring the nonequilibrium metabolic
150 ng, illustrate how subtle changes in channel biophysics can have significant and distinct effects in
151 ields (that is, polymer mechanochemistry and biophysics) can be harnessed to guide the rational desig
152 te manipulation applications in biomedicine, biophysics, chemistry, and condensed-matter physics.
153 lifetimes can have numerous applications in biophysics, clinical diagnostics, DNA analysis, and drug
154 Almost everything we know about protein biophysics comes from studies on purified proteins in di
155 ng software (IC-ITC; freely available to the biophysics community), which simultaneously fits ligand
158 cision in self-assembly for fields including biophysics, diagnostics, therapeutics, photonics, and na
160 ns would provide insight into the underlying biophysics, enable mathematical analysis of the behavior
161 ogen exchange (HX) is widely used in protein biophysics even though our ignorance about the HX mechan
163 develop novel devices and methods in protein biophysics for sample manipulation, functional and struc
167 an genetics to physiology, cell biology, and biophysics has cast light on the special function of fiv
168 biochemistry, genetics, and single-molecule biophysics has provided a renewed impetus for the constr
170 netics, molecular biology, biochemistry, and biophysics has spanned more than half a century-from the
171 structural bioinformatics and computational biophysics has undergone a revolution in the last 10 yea
172 neuromodulation of biochemical signaling and biophysics have been investigated separately in modeling
173 Recent advances in computational systems biophysics have provided promising avenues to reliably i
174 , which have been successful in the field of biophysics, have been applied to study chemical processe
175 ich combine evolutionary theory with protein biophysics, have completely revolutionized our view of t
177 cements in the fields of polymer physics and biophysics, how applicable they are to life inside the c
178 lectrostatics is a well established model in biophysics; however, its application to large-scale biom
179 b initio model of living cells where protein biophysics (i.e., folding and protein-protein interactio
180 evolutionary in shaping our understanding of biophysics in areas as diverse as dynamic bond strength,
182 rovide crucial information of the underlying biophysics in TES applications in humans and the optimiz
183 tructures that have illuminated the field of biophysics in the 54 years since the first excitement of
184 extract precise information about regulatory biophysics in the face of experimental noise is made pos
185 ely used in modern in vitro biochemistry and biophysics, in particular to aid the characterization of
187 we describe, using the methods of molecular biophysics, interactions of a series of biologically-act
188 the critical unanswered questions in genome biophysics is how the primary sequence of DNA bases infl
189 ing paradigm in the field of in vivo protein biophysics is that nascent-protein behavior is a type of
192 a new and efficient NMR method, BLUU-Tramp (Biophysics Laboratory University of Udine temperature ra
194 increasingly important role in chemistry and biophysics, mainly thanks to improvements in hardware an
195 structures, known as gelation, is central to biophysics, materials science, nanotechnology, and food
196 stic microclimate model coupled to an animal biophysics model to predict the spatially explicit effec
197 understand how single-molecule and multibond biophysics modulate the macroscopic cell behavior in div
198 n, the continuum field description of tissue biophysics must be linked to discrete descriptions of mo
199 ct of these and other new imaging methods in biophysics, neuroscience, and developmental and cell bio
201 states in vitro by studying the myofilament biophysics of amino acid substitutions that act as const
204 how that, because the method is based on the biophysics of binding rather than on empirical parametri
205 useful insights into the thermodynamics and biophysics of biological membranes and binding of small
207 These findings provide new insight into the biophysics of chromatin formation, both in the context o
208 features of ciliary behavior illuminate the biophysics of cilia motion and, in future studies, may h
213 atively, and it has been unclear whether the biophysics of DNA self-assembly allows that threshold to
214 ion and require strong assumptions about the biophysics of DNA to transform interaction frequencies t
215 w nucleic acid nanostructural designs, model biophysics of DNA/RNA processes, and rationalize experim
216 mathematical model developed to describe the biophysics of epithelial tissue to explore this problem.
221 , and contribute to the understanding of the biophysics of information transfer of single neurons in
226 s provide a mechanistic understanding of the biophysics of multi-electrode TACS and enable future dev
228 ificant advances in our understanding of the biophysics of myofilament activation, coupled to the eme
229 A recent study examined the structure and biophysics of N-terminally extended peptides in complex
230 ment models have long been used to study the biophysics of neurons, it is still challenging to infer
232 in Huntington's disease, suggesting that the biophysics of poly(Gln) aggregation nucleation may play
233 hanism of aggregation because the underlying biophysics of polyglutamine-mediated association can be
234 rotocell research, fueled by advances in the biophysics of primitive membranes and the chemistry of n
240 iewed as a distortion that is imposed by the biophysics of receptor binding, here we show that it als
241 earch over the past decade, ranging from the biophysics of sound reception to molecular aspects of au
243 of Neuron, Remme and colleagues examine the biophysics of synchronization between oscillating dendri
244 e model a telomere state on the basis of the biophysics of t-loop formation, allowing us to develop a
245 R-loop formation is needed to understand the biophysics of target searching and develop rational appr
246 egulatory sequences, making use of the known biophysics of the binding of regulatory proteins to DNA
247 ular Ca(2+) is universally acknowledged, the biophysics of the Ca(2+) flux responsible for the effect
251 effects of each of the gamma subunits on the biophysics of the T-type VSCC encoded by the alpha(1I) s
252 Unlike ciliary or flagellar motility, the biophysics of this mode is not well understood, includin
253 investigations aimed at fully clarifying the biophysics of this unique genome editing machinery and a
257 -standing areas of investigation such as the biophysics of water permeation across cell membranes, th
258 lled by L-type Ca(V)1.3 Ca(2+) channels, the biophysics of which are still unknown in native mammalia
259 the gap between the integrated mechanics and biophysics of whole cells and the microscopic molecular
262 d membranes is of key importance in membrane biophysics, primarily since cholesterol enriched regions
263 ic lipids further our understanding of lipid biophysics, promote targeted drug delivery and improve l
264 e tracking has seen numerous applications in biophysics, ranging from the diffusion of proteins in ce
268 magnetoencephalography-or been restricted to biophysics studies of excised neurons probed with cryoge
269 The traditional approach to computational biophysics studies of molecular systems is brute force m
272 ion and collagen deposits, and impaired lung biophysics, suggestive of a fibrosis-like pathology.
273 tablish the singe-cell computation that this biophysics supports, we show that the combination of fre
275 tal for their use as model cell membranes in biophysics, synthetic biology, and origins of life studi
276 ctopus cells have dendritic morphologies and biophysics tailored to accomplish the precise encoding o
277 mbining molecular biology, biochemistry, and biophysics techniques, we discover that ACT has intrinsi
278 are relatively new additions to the field of biophysics that allow one to manipulate individual molec
280 s abnormalities in surfactant components and biophysics, these responses are exacerbated by IRD.
283 ethods from bioinformatics and computational biophysics to quantify structural and dynamical differen
285 d a combination of quantitative genetics and biophysics to rule out broad classes of models of the re
290 ist between reptilian and mammalian auditory biophysics, understanding lizard OAE generation mechanis
292 f genetics, biochemistry and single-molecule biophysics, we characterize how IDRs regulate the functi
293 KII phosphorylation of Kv4.2 affects channel biophysics, we expressed wild-type or mutant Kv4.2 and t
294 y approach to probing molecular and cellular biophysics, we feature its application to three leading
295 bination of genetics, molecular biology, and biophysics, we have identified Halo, a novel regulator o
296 o study how lipid oxidation affects membrane biophysics, we used a chlorin photosensitizer to oxidize
297 , followed by a discussion of the underlying biophysics; we consider actin treadmilling, actin-myosin
298 s a fundamental question in cell biology and biophysics whether sphingomyelin (SM)- and cholesterol (
300 most active areas of research in biology and biophysics, yet the basic physical origins of their diff