Liquid-liquid separation in solutions of normal and sickle cell hemoglobin. - Wikidata - wikimedia - TriplyDB

Liquid-liquid separation in solutions of normal and sickle cell hemoglobin.

Liquid-liquid separation in solutions of normal and sickle cell hemoglobin.

http://www.wikidata.org/entity/Q30476248

about

Observation of liquid-liquid phase separation for eye lens gammaS-crystallin Metastable mesoscopic clusters in solutions of sickle-cell hemoglobin Protein-protein interaction on lysozyme crystallization revealed by rotational diffusion analysis.Multiple pathways of crystal nucleation in an extremely supersaturated aqueous potassium dihydrogen phosphate (KDP) solution droplet.Carbonate-coordinated metal complexes precede the formation of liquid amorphous mineral emulsions of divalent metal carbonates.Phase separation and crystallization of hemoglobin C in transgenic mouse and human erythrocytes Self-catalyzed growth of S layers via an amorphous-to-crystalline transition limited by folding kinetics Evidence of multi-step nucleation leading to various crystallization pathways from an Fe-O-Al melt.Phase transitions in human IgG solutions.Free heme and the polymerization of sickle cell hemoglobin Liquid-liquid phase separation in hemoglobins: distinct aggregation mechanisms of the beta6 mutants.Aggregation of normal and sickle hemoglobin in high concentration phosphate buffer Nucleation Effect of polyethylene glycol on the liquid-liquid phase transition in aqueous protein solutions.Atomic-level observation of macromolecular crowding effects: escape of a protein from the GroEL cage Do protein crystals nucleate within dense liquid clusters?Two-step mechanism of homogeneous nucleation of sickle cell hemoglobin polymers.Altered phase diagram due to a single point mutation in human gammaD-crystallin.Observing in space and time the ephemeral nucleation of liquid-to-crystal phase transitions.Structural fingerprints and their evolution during oligomeric vs. oligomer-free amyloid fibril growth The dynamics and energetics of matrix assembly and mineralization.The energetics of prenucleation clusters in lattice solutions.Gelation behaviour of a bent-core dihydrazide derivative: effect of incubation temperature in chloroform and toluene.Liquid-liquid phase separation of a monoclonal antibody and nonmonotonic influence of Hofmeister anions.Population and size distribution of solute-rich mesospecies within mesostructured aqueous amino acid solutions.NMR study of the cataract-linked P23T mutant of human gammaD-crystallin shows minor changes in hydrophobic patches that reflect its retrograde solubility.Second-harmonic scattering in aqueous urea solutions: evidence for solute clusters?Tuning crystallization pathways through sequence engineering of biomimetic polymers.Real-time molecular scale observation of crystal formation.Protein phase behavior and crystallization: effect of glycerol.A finite-size scaling study of a model of globular proteins.Effects of patch size and number within a simple model of patchy colloids.Sequence variability of proteins evolutionarily constrained by solution-thermodynamic function.Self-Assembly through Noncovalent Preorganization of Reactants: Explaining the Formation of a Polyfluoroxometalate.Kinetics of liquid-liquid phase separation in protein solutions exhibiting LCST phase behavior studied by time-resolved USAXS and VSANS.Multiple extrema in the intermolecular potential and the phase diagram of protein solutions.Spinodal for the solution-to-crystal phase transformation.Nucleation of ordered solid phases of proteins via a disordered high-density state: phenomenological approach.Smooth transition from metastability to instability in phase separating protein solutions.Protein Phase Separation: A New Phase in Cell Biology

P2860

Q24599462-D43527FA-D898-4182-AD15-8257ED74C7EE Q24673168-7580DBBB-E06B-4F4F-ADF9-2C37C2E97AFA Q30368006-40EEA6A2-EF74-49F3-B77B-20857DCAE7D2 Q30368214-1F14B748-9D6E-485A-8D19-1EA57AE9FAD7 Q30475176-35B4F826-D0FD-4EDB-8323-F77858DB9395 Q30483729-8409AEB5-A1D1-4DAD-8E92-FC33527525E5 Q30496709-BF629DA6-AE3D-4FD1-AA01-32B3D144275C Q33671899-06EF24AA-2410-4C5B-AE04-0E3C237A66C8 Q33941043-39D7B35D-0F9B-407A-97FA-2802E8BF2CBD Q34134652-65388ABA-4D6B-489E-A3E4-8F719138152B Q34185062-C31B6D63-B442-4BF9-BE83-C13CC5AFB93A Q34188180-F269F590-FB03-4608-98DE-C21292A098AC Q34369231-4CA034C0-BAEF-47A6-BDA4-D226493F62FC Q34392528-A7D0471F-97D0-4602-B1B1-0295D0669897 Q34805263-84D159E8-478D-4CB1-BF91-654CEB21239E Q35841497-7F645F3E-0C65-44B6-822B-03DE05F63C66 Q35878610-02F7AAAC-81C5-4062-A999-3A8E70C26A86 Q36089188-769C05BE-5BD5-4AD2-99D3-6392CCEB1C43 Q36341559-A7E95E26-3620-442E-9775-0895E304E1D4 Q37028081-DD8134A5-C894-4C1D-BEBB-718A1CA446C2 Q38086496-1538F6BA-36D7-44B2-9CA1-5737B3B71F60 Q38629208-333057B5-D451-4E3E-9340-EB81DFCF664B Q40219440-D28B4B7C-FEF7-4A0E-9140-D1153BE07AA6 Q41152457-34918E97-0B1F-4DD0-BAEF-537F482E7616 Q41611848-9A3B5356-82E8-445F-BFF3-CF2BB0FB7DDD Q41909394-AEFC6976-3DCE-48B9-A0AF-379249BC8F6D Q44783762-2E9503A8-505C-437C-AA44-3042C2CC6691 Q46020460-A5751802-F0CC-498D-85E3-E596173790F9 Q46397692-8AE1FF50-F697-40EA-8007-955DD51D709C Q46976380-9BB31232-0C71-41AB-8A8A-E27AF6155544 Q47413168-FF78B2E4-4C8F-4A2F-8449-CFE770EB7AAC Q47432695-ACE8A1B8-8443-4D27-98B4-4D8610FE6DCA Q48011915-5585BC44-7FE2-476E-9333-9E2B38A8B07C Q48137411-0238C81E-EC09-4F98-8166-2163DFCC7279 Q48235322-D43E1E51-DCF1-4860-A29F-5C9245F3CE18 Q51146612-139F8BDF-DD08-4126-8A26-F1358031152D Q51393818-7C4ADF9A-57F7-481D-AB25-C156BCB68E5A Q51457778-FCDB1D75-403D-4EFF-BBB5-7B802FC49C67 Q51601749-64411DF4-E5EF-4910-89E1-570256458F7B Q57244896-85D6F227-0173-4114-ABAD-653BDB9E47F0

P2860

Liquid-liquid separation in solutions of normal and sickle cell hemoglobin.

http://www.wikidata.org/entity/Q30476248

description

2002 nî lūn-bûn

@nan

2002 թուականի Յունիսին հրատարակուած գիտական յօդուած

@hyw

2002 թվականի հունիսին հրատարակված գիտական հոդված

@hy

2002年の論文

@ja

2002年論文

@yue

2002年論文

@zh-hant

2002年論文

@zh-hk

2002年論文

@zh-mo

2002年論文

@zh-tw

2002年论文

@wuu

name

Liquid-liquid separation in solutions of normal and sickle cell hemoglobin.

@ast

Liquid-liquid separation in solutions of normal and sickle cell hemoglobin.

@en

type

label

Liquid-liquid separation in solutions of normal and sickle cell hemoglobin.

@ast

Liquid-liquid separation in solutions of normal and sickle cell hemoglobin.

@en

prefLabel

Liquid-liquid separation in solutions of normal and sickle cell hemoglobin.

@ast

Liquid-liquid separation in solutions of normal and sickle cell hemoglobin.

@en

P1433

Q30476248-185A00BF-D17E-40DB-9D51-E0B3573F0940

P1476

Q30476248-544D6575-CF2F-49D5-B14C-EBE7F1D4E528

P2093

Q30476248-1CF134FC-3591-44EE-9F7F-3521A96A913E

Q30476248-26EDD692-3749-460B-A717-44355976F43D

Q30476248-753DE47E-257D-4F7D-A3C5-3F00D8E7ECEC

Q30476248-8061C391-7E13-4DA9-B307-EE7BA1D9AA69

Q30476248-97D6F664-B24B-4D6A-85FE-DF73A35716CE

P2860

Q30476248-00EEBD1A-DAF8-4EE6-88C5-645190AFAC3E

Q30476248-01D438F4-CCB4-468C-B48B-C549DF8171B9

Q30476248-0AFCA03A-FFF2-4DFE-A2D3-A1307E08A57B

Q30476248-1BEE5F5A-C86C-46D8-9B01-751196B5465C

Q30476248-24A60F4B-1F0B-4B17-B46A-6957EA6A94C8

Q30476248-3FEACE1A-65D3-46E1-B23C-CEF7342D5669

Q30476248-448647AD-40CB-40FC-8779-BDBC0872418B

Q30476248-52A697DB-3F72-410B-9528-8D0F69BB25E5

Q30476248-62303623-B14E-4D06-899E-362EFB906BB4

Q30476248-76437240-A808-440D-86F0-FD3E47574FCE

P304

Q30476248-BA7B75C8-CA2C-46C2-9DBA-3A6A98DC8C15

P31

Q30476248-90D7D5E5-C0E1-432C-BD41-E8BEF33369B9

P356

Q30476248-85C06007-C9ED-4EA5-8DD8-94E83B4AF1DA

P407

Q30476248-689CA6B0-9172-44E3-8F91-B2F4171437C8

P433

Q30476248-A77C5DE0-E28F-4E02-9182-1DF1A63CC0DA

P478

Q30476248-1F8F3DCB-C378-4EE9-9A29-98752A8443B0

P577

Q30476248-DDBBE10A-7778-4547-8A07-6767095A437D

P5875

Q30476248-48F16941-57DF-42BF-A409-BDF7340C0C55

P698

Q30476248-A5FC9ABB-7C58-4824-B639-32B0E1DD4574

P932

Q30476248-5D7B375C-86CF-40CD-8A53-F4471E2B2365

P356

P1433

Proceedings of the National Academy of Sciences of the United States of America

P1476

Liquid-liquid separation in solutions of normal and sickle cell hemoglobin.

@en

P2093

Kai Chen

http://www.w3.org/2001/XMLSchema#string

Oleg Galkin

http://www.w3.org/2001/XMLSchema#string

Peter G Vekilov

http://www.w3.org/2001/XMLSchema#string

Rhoda Elison Hirsch

http://www.w3.org/2001/XMLSchema#string

Ronald L Nagel

http://www.w3.org/2001/XMLSchema#string

P2860

Nonideality and the nucleation of sickle hemoglobin

Molecular-level thermodynamic and kinetic parameters for the self-assembly of apoferritin molecules into crystals.

Microvascular sites and characteristics of sickle cell adhesion to vascular endothelium in shear flow conditions: pathophysiological implications.

Kinetic studies on photolysis-induced gelation of sickle cell hemoglobin suggest a new mechanism

Binary liquid phase separation and critical phenomena in a protein/water solution.

Kinetics and mechanism of deoxyhemoglobin S gelation: a new approach to understanding sickle cell disease

Control of protein crystal nucleation around the metastable liquid-liquid phase boundary.

Kinetics of sickle hemoglobin polymerization. I. Studies using temperature-jump and laser photolysis techniques.

Nucleation and polymerization of sickle hemoglobin with Leu beta 88 substituted by Ala.

Binary-liquid phase separation of lens protein solutions

P304

8479-8483

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1073/PNAS.122055299

http://www.w3.org/2001/XMLSchema#string

P407

P433

13

http://www.w3.org/2001/XMLSchema#string

P478

99

http://www.w3.org/2001/XMLSchema#string

P577

2002-06-17T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

11305041

http://www.w3.org/2001/XMLSchema#string

P698

12070342

http://www.w3.org/2001/XMLSchema#string

P932

124280

http://www.w3.org/2001/XMLSchema#string