PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
16506751-2	2006	Electron-deficient alkenes, p-X-trans-beta-nitrostyrene (X = OCH3, CH3, H, F, Br, CF3, NO2), react quantitatively with (bc)Pd(eta2-O2) (bc = bathocuproine) in dichloromethane at room temperature to form the corresponding palladium(0)-alkene complexes.	Palladium	123-125	DNA polymerase iota	Homo sapiens	126-133	
29172489-1	2018	Reaction of [Pd(IPr)2] (IPr = 1,3-bis(2,6-diisopropylphenyl)imidazol-2-ylidene) and O2 leads to the surprising discovery that at low temperature the initial reaction product is a highly labile peroxide complex cis-[Pd(IPr)2(eta2-O2)].	Palladium	12-15	DNA polymerase iota	Homo sapiens	224-228	
24281882-2	2013	It coordinates to palladium and platinum in a eta(2) -fashion giving complexes (red) with a trans-bent geometry, in contrast to eta(2) -alkyne complexes.	Palladium	18-27	DNA polymerase iota	Homo sapiens	46-52	
24281882-2	2013	It coordinates to palladium and platinum in a eta(2) -fashion giving complexes (red) with a trans-bent geometry, in contrast to eta(2) -alkyne complexes.	Palladium	18-27	DNA polymerase iota	Homo sapiens	46-51	
21725574-0	2011	Reaction of bis(o-phosphinophenyl)silane with M(PPh3)4 (M = Ni, Pd, Pt): synthesis and structural analysis of eta2-(Si-H) metal(0) and pentacoordinate silyl metal(II) hydride complexes of the Ni triad bearing a PSiP-pincer ligand.	Palladium	64-66	DNA polymerase iota	Homo sapiens	110-114	
16749844-0	2006	Molybdenum and tungsten eta2-alkyne-1-thio complexes acting as sulfur donors in homoleptic Werner type complexes with nickel(II) and palladium(II).	Palladium	133-142	DNA polymerase iota	Homo sapiens	24-28	
28868805-0	2017	Formation of Palladium eta2 -Bound Chalcogenoketones across a Pd+ -C- Bond.	Palladium	62-64	DNA polymerase iota	Homo sapiens	23-27	
17450904-3	2007	Similarly, trinuclear complexes (eta2 : eta2-C60) M(cis-dppet)M1 (dppr) (7-10; M, M1 = Pd, Pt; dppr = (eta5-Ph2PC5H4)2Ru) could be synthesized by reaction of the in situ prepared 3-6 with dppr.	Palladium	87-89	DNA polymerase iota	Homo sapiens	33-37	
17450904-3	2007	Similarly, trinuclear complexes (eta2 : eta2-C60) M(cis-dppet)M1 (dppr) (7-10; M, M1 = Pd, Pt; dppr = (eta5-Ph2PC5H4)2Ru) could be synthesized by reaction of the in situ prepared 3-6 with dppr.	Palladium	87-89	DNA polymerase iota	Homo sapiens	40-44	
17450904-5	2007	Cyclic voltammetric studies on 2 (M = Pt), 3 (M = Pd, M1 = Pd) and 9 (M = Pt, M1 = Pd) provided further evidence for the eta2-coordination of C60 to one metal fragment or two metal fragments in these complexes.	Palladium	50-52	DNA polymerase iota	Homo sapiens	121-125	
17450904-5	2007	Cyclic voltammetric studies on 2 (M = Pt), 3 (M = Pd, M1 = Pd) and 9 (M = Pt, M1 = Pd) provided further evidence for the eta2-coordination of C60 to one metal fragment or two metal fragments in these complexes.	Palladium	59-61	DNA polymerase iota	Homo sapiens	121-125	
15369351-1	2003	The direct addition of a proton to a carbonyl oxygen in an eta2-enone complex of palladium and platinum led to the quantitative formation of eta3-1-hydroxyallyl complexes of palladium and platinum, of which X-ray diffraction analysis showed typical eta3-allyl structure.	Palladium	81-90	DNA polymerase iota	Homo sapiens	59-63	
15469264-2	2004	In the solid state, complex 4 has one tricyclohexylphosphine ligand bound unsymmetrically to the palladium center in regard to the eta2-disilene moiety.	Palladium	97-106	DNA polymerase iota	Homo sapiens	131-135	
15369351-1	2003	The direct addition of a proton to a carbonyl oxygen in an eta2-enone complex of palladium and platinum led to the quantitative formation of eta3-1-hydroxyallyl complexes of palladium and platinum, of which X-ray diffraction analysis showed typical eta3-allyl structure.	Palladium	174-183	DNA polymerase iota	Homo sapiens	59-63	
34669411-3	2021	Control experiments and density functional theory (DFT) calculations support the idea that the palladium(0) acts as a pi-Lewis base catalyst by chemoselectively forming eta2-complexes with the alkene moiety of 1,3-enynes, thus increasing the nucleophilicity of the alkyne group based on the principle of vinylogy, to attack imines enantioselectively.	Palladium	95-104	DNA polymerase iota	Homo sapiens	169-173	
19750645-0	2002	Hexakis(silyl)palladium(VI) or palladium(II with eta2-disilane ligands?.	Palladium	14-23	DNA polymerase iota	Homo sapiens	49-53	
10840970-4	2000	When the PhPN ligand is present in excess, it behaves as a monodentate phosphane ligand, since [Pd0(eta2-dba)(eta1-PhPN)2] is formed first by preferential cleavage of the Pd-N bond instead of the Pd olefin bond.	Palladium	96-98	DNA polymerase iota	Homo sapiens	100-104	
12526399-2	2000	In palladium complexes of methylenecyclopropane or trimethylenemethane, the eta 2 forms have been shown to be more stable than the palladacyclobutane forms.	Palladium	3-12	DNA polymerase iota	Homo sapiens	76-81	
12526399-4	2000	With respect to the palladium-catalyzed [3 + 2] cycloaddition reaction of methylenecyclopropane with alkenes, the path via palladacyclobutanes has been demonstrated to be more favorable than the path via an eta 2 complex.	Palladium	20-29	DNA polymerase iota	Homo sapiens	207-212	
35623059-1	2022	Here we report an asymmetric formal nucleophilic o-cresolylation reaction with the Morita-Baylis-Hillman (MBH) carbonates from 2-cyclohexanones and diverse aldehydes under palladium catalysis, by in situ generation of electron-neutral and HOMO-raised eta2-Pd(0)-dienone complexes via an oxidative insertion/pi-sigma-isomerization/beta-H elimination activation sequence.	Palladium	172-181	DNA polymerase iota	Homo sapiens	251-255	
33730847-1	2021	Here we report that palladium(0) complexes can coordinate in a eta2 fashion to 1,3-dienes and significantly raise the energy of their highest occupied molecular orbital (HOMO) by donating the electrons from the d-orbitals to the empty antibonding molecular orbitals of double bonds (pi*) via back-bonding.	Palladium	20-29	DNA polymerase iota	Homo sapiens	63-67	
30897237-2	2019	The reaction proceeds via an eta2 -Pd complex, the pyramidalization of which (confirmed by quantum chemistry calculations) offers a favorable antiperiplanar alignment of the Pd-C and allylic C-O bonds (C), thus allowing the formation of an eta3 -Pd intermediate.	Palladium	34-37	DNA polymerase iota	Homo sapiens	29-33