Philip J Reeves
Overview
Explore the profile of Philip J Reeves including associated specialties, affiliations and a list of published articles.
Author names and details appear as published. Due to indexing inconsistencies, multiple individuals may share a name, and a single author may have variations. MedLuna displays this data as publicly available, without modification or verification
Snapshot
Snapshot
Articles
48
Citations
1637
Followers
0
Related Specialties
Related Specialties
Top 10 Co-Authors
Top 10 Co-Authors
Published In
Affiliations
Affiliations
Soon will be listed here.
Recent Articles
1.
Reeves P
Biophys Rev
. 2023 Mar;
15(1):93-101.
PMID: 36909956
Here I will review the development of gene expression systems for production of bovine rhodopsin in the Khorana laboratory with particular focus on stable mammalian cell lines made using human...
2.
Bassey E, Reeves P, Seymour I, Grey C
J Am Chem Soc
. 2022 Oct;
144(41):18714-18729.
PMID: 36201656
Modern studies of lithium-ion battery (LIB) cathode materials employ a large range of experimental and theoretical techniques to understand the changes in bulk and local chemical and electronic structures during...
3.
Grime R, Logan R, Nestorow S, Sridhar P, Edwards P, Tate C, et al.
Nanoscale
. 2021 Sep;
13(31):13519-13528.
PMID: 34477756
Membrane proteins are of fundamental importance to cellular processes and nano-encapsulation strategies that preserve their native lipid bilayer environment are particularly attractive for studying and exploiting these proteins. Poly(styrene-co-maleic acid)...
4.
Bassey E, Reeves P, Jones M, Lee J, Seymour I, Cibin G, et al.
Chem Mater
. 2021 Jul;
33(13):4890-4906.
PMID: 34276134
P2-layered sodium-ion battery (NIB) cathodes are a promising class of Na-ion electrode materials with high Na mobility and relatively high capacities. In this work, we report the structural changes that...
5.
Reeves P
Methods Mol Biol
. 2021 Jun;
2268:43-60.
PMID: 34085260
Large-scale recombinant expression of G protein-coupled receptors (GPCRs) is required for structure and function studies where there is a need for milligram amounts of protein in pure form. Here we...
6.
Griffith K, Hope M, Reeves P, Anayee M, Gogotsi Y, Grey C
J Am Chem Soc
. 2020 Oct;
142(44):18924-18935.
PMID: 33095562
MXenes, derived from layered MAX phases, are a class of two-dimensional materials with emerging applications in energy storage, electronics, catalysis, and other fields due to their high surface areas, metallic...
7.
Xu C, Marker K, Lee J, Mahadevegowda A, Reeves P, Day S, et al.
Nat Mater
. 2020 Aug;
20(1):84-92.
PMID: 32839589
Ni-rich layered cathode materials are among the most promising candidates for high-energy-density Li-ion batteries, yet their degradation mechanisms are still poorly understood. We report a structure-driven degradation mechanism for NMC811...
8.
Pope A, Sanchez-Reyes O, South K, Zaitseva E, Ziliox M, Vogel R, et al.
Structure
. 2020 May;
28(9):1004-1013.e4.
PMID: 32470317
Despite high-resolution crystal structures of both inactive and active G protein-coupled receptors (GPCRs), it is still not known how ligands trigger the large structural change on the intracellular side of...
9.
Grenier A, Reeves P, Liu H, Seymour I, Marker K, Wiaderek K, et al.
J Am Chem Soc
. 2020 Mar;
142(15):7001-7011.
PMID: 32202112
Substituted Li-layered transition-metal oxide (LTMO) electrodes such as LiNiMnCoO (NMC) and LiNiCoAlO (NCA) show reduced first cycle Coulombic efficiency (90-87% under standard cycling conditions) in comparison with the archetypal LiCoO...
10.
Shi Y, Zhou H, Seymour I, Britto S, Rana J, Wangoh L, et al.
ACS Omega
. 2019 Aug;
3(7):7310-7323.
PMID: 31458891
ε-LiVOPO is a promising multielectron cathode material for Li-ion batteries that can accommodate two electrons per vanadium, leading to higher energy densities. However, poor electronic conductivity and low lithium ion...