PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
32897613-3	2020	Uniform two-dimensional (2-D) Co-MOF nanosheets (Co-MNS) grow on nickel foam, followed by a MOF-mediated tandem (carbonization/phosphidation) pyrolysis.	Nickel	65-71	lysine acetyltransferase 8	Homo sapiens	33-36	
35465672-0	2022	Morphology-Dependent Electrocatalytic Performance of a Two-Dimensional Nickel-Iron MOF for Oxygen Evolution Reaction.	Nickel	71-77	lysine acetyltransferase 8	Homo sapiens	83-86	
31978792-2	2020	Herein, Cu(NiCo)2S4/Ni3S4, a three-dimensional (3D) hierarchical hollow heterostructured electrode material, is designed by etching the well-defined bimetal organic framework (MOF) via sequential in-situ ion-exchange processes.	Nickel	8-19	lysine acetyltransferase 8	Homo sapiens	176-179	
31978792-2	2020	Herein, Cu(NiCo)2S4/Ni3S4, a three-dimensional (3D) hierarchical hollow heterostructured electrode material, is designed by etching the well-defined bimetal organic framework (MOF) via sequential in-situ ion-exchange processes.	Nickel	20-25	lysine acetyltransferase 8	Homo sapiens	176-179	
31667482-4	2019	During this process, we converted a Co-MOF to a CoNi-MOF by ion exchange and low-temperature phosphating to achieve CoNiP nanoboxes.	Nickel	116-121	lysine acetyltransferase 8	Homo sapiens	39-42	
31904031-1	2020	Controlled partial decomposition of 2-selenonicotinic acid in the presence of Co2+ or Ni2+ resulted in the in situ formation of an unusual MOF based on triselenane ligands (RSeSeSeR) coordinated to M2+ centers as NSeN-pincers.	Nickel	86-90	lysine acetyltransferase 8	Homo sapiens	139-142	
31667482-4	2019	During this process, we converted a Co-MOF to a CoNi-MOF by ion exchange and low-temperature phosphating to achieve CoNiP nanoboxes.	Nickel	116-121	lysine acetyltransferase 8	Homo sapiens	53-56	
31739418-2	2019	The first one involves an aluminum containing MOF precursor used as sacrificial template to deposit nickel while the second is based on a one-pot synthesis combined to an EISA method.	Nickel	100-106	lysine acetyltransferase 8	Homo sapiens	46-49	
31638777-1	2019	RuNi nanoparticles supported on a metal-organic framework (RuNi@MOF) and formed in situ from a ruthenium complex enclosed inside a nickel-based MOF act as a highly active catalyst for the Guerbet reaction of ethanol to 1-butanol, providing turnover numbers up to 725 000 Ru-1.	Nickel	131-137	lysine acetyltransferase 8	Homo sapiens	64-67	
31638777-1	2019	RuNi nanoparticles supported on a metal-organic framework (RuNi@MOF) and formed in situ from a ruthenium complex enclosed inside a nickel-based MOF act as a highly active catalyst for the Guerbet reaction of ethanol to 1-butanol, providing turnover numbers up to 725 000 Ru-1.	Nickel	131-137	lysine acetyltransferase 8	Homo sapiens	144-147	
31310439-1	2019	Hexagonal nickel-organic framework (Ni-MOF) [Ni(NO3 )2  6H2 O, 1,3,5-benzenetricarboxylic acid, 4-4"-bipyridine] is fabricated through a one-step solvothermal method.	Nickel	10-16	lysine acetyltransferase 8	Homo sapiens	39-42	
31252455-3	2019	Herein, we report a heterogeneous nanostructure of a Ni-based MOF-modified Ni3S2/NiS hollow nanoparticle.	Nickel	81-84	lysine acetyltransferase 8	Homo sapiens	62-65	
29513268-3	2018	With this perspective, MOF derived hollow cubes of nickel cobalt ferrites have been synthesized via a facile process using sacrificial templates at 600  C. Microcubes, composed of tiny grains in a size range from 10 nm +- 2 nm were obtained in pure form as a polycrystalline material.	Nickel	51-57	lysine acetyltransferase 8	Homo sapiens	23-26