PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
32778291-5	2020	Up to 468 mL L-1 of hydrogen and 203 mg L-1 of poly-beta-hydroxybutyrate can be produced starting from an initial chemical oxygen demand of 1500 mg L-1.	Hydrogen	20-28	L1 cell adhesion molecule	Homo sapiens	13-16	
32812959-7	2020	Furthermore, complexation of L1 with Cu(BF4)2 H2O and Zn(CF3SO3)2 provided a 2D   3D interpenetrated network containing a classic dimeric copper paddle-wheel SBU, and an infinite 1D chain which extended into a 3D structure facilitated by hydrogen-bonding interactions, respectively.	Hydrogen	238-246	L1 cell adhesion molecule	Homo sapiens	29-31	
31806513-2	2020	RCPH-biochar at concentration of 15 g L-1 substantially enhanced hydrogen generation during batch tests, with the highest cumulative hydrogen volume (3990 mL L-1) being 1.7 times that without RCPH-biochar.	Hydrogen	65-73	L1 cell adhesion molecule	Homo sapiens	38-41	
31806513-2	2020	RCPH-biochar at concentration of 15 g L-1 substantially enhanced hydrogen generation during batch tests, with the highest cumulative hydrogen volume (3990 mL L-1) being 1.7 times that without RCPH-biochar.	Hydrogen	133-141	L1 cell adhesion molecule	Homo sapiens	158-161	
31806513-2	2020	RCPH-biochar at concentration of 15 g L-1 substantially enhanced hydrogen generation during batch tests, with the highest cumulative hydrogen volume (3990 mL L-1) being 1.7 times that without RCPH-biochar.	Hydrogen	133-141	L1 cell adhesion molecule	Homo sapiens	38-41	
31806513-3	2020	Then, continuous hydrogen production performance demonstrated that RCPH-biochar was capable of retaining biomass in the reactor, at 6 h hydraulic retention time, hydrogen production rate (22.8 mmol H2 L-1 h-1) was tripled compared to the control, meanwhile, glucose and xylose utilization reached to 82.3% and 54.6%, respectively.	Hydrogen	162-170	L1 cell adhesion molecule	Homo sapiens	201-204	
31799844-2	2019	L1 displays crystallographic symmetry (orthorhombic, Pccn) higher than its molecular symmetry (point group C1) and also displays supercooling, with a difference in the melting and solidification points of over 100  C. Upon complexation with ZnCl2, L1 engages in both primary cation and secondary anion coordination via hydrogen bonding, and the complex exhibits a room-to-low-temperature single crystal-to-crystal phase transition.	Hydrogen	319-327	L1 cell adhesion molecule	Homo sapiens	0-2	
23939620-6	2013	Thus, the RNA loading and tight coupling of NTPase activity with RNA translocation in 8 P4 is due to a remarkable C-terminal structure, which wraps right around the outside of the molecule to insert into the central hole where RNA binds to coupled L1 and L2 loops, whereas in 12 P4, a C-terminal residue, serine 282, forms a specific hydrogen bond to the N7 of purines ring to confer purine specificity for the 12 enzyme.	Hydrogen	334-342	L1 cell adhesion molecule	Homo sapiens	248-257	
31299615-1	2019	Here in we report tris (3-aminopropyl) amine based tripodal receptors L, L1 and L2 which were functionalized with 4-nitrophenyl moieties having thio-urea, amide and sulfonamide as hydrogen bonding moieties respectively, shows a strong selectivity towards cyanide.	Hydrogen	180-188	L1 cell adhesion molecule	Homo sapiens	73-82	
28956596-2	2017	The ligand L1 and complexes 1 and 2 have been meticulously characterized by elemental analyses and spectral studies (IR, electrospray ionization mass spectrometry, 1H and 13C NMR, UV/vis, fluorescence) and their structures explicitly authenticated by single-crystal X-ray analyses.	Hydrogen	164-166	L1 cell adhesion molecule	Homo sapiens	11-35	
30633442-2	2019	L1 and L2 comprise pyridyl triazole chelating units with pendant diaminotriazine units, capable of donor-acceptor-donor (DAD) hydrogen bonding, while L3 and L4 contain ADA hydrogen bonding units proximal to N^N and N^O cleating sites, respectively.	Hydrogen	126-134	L1 cell adhesion molecule	Homo sapiens	0-9	
30633442-3	2019	X-ray crystallography shows the L1 and L2 containing RuII complexes to assemble via  R 2 2 8   hydrogen bonding dimers, while [RuII (bpy)2 L4] assembles via extended hydrogen bonding motifs to form one dimensional chains.	Hydrogen	95-103	L1 cell adhesion molecule	Homo sapiens	32-41	
30633442-6	2019	The L1 and L2 complexes of IrIII and RuII complexes are emissive in the solid state and it seems likely that hydrogen bonding to complementary species may facilitate tuning of their 3 ILCT emission.	Hydrogen	109-117	L1 cell adhesion molecule	Homo sapiens	4-13	
25635520-3	2015	Neighboring molecules in L1H and 1 are linked into supramolecular chains through hydrogen bonds.	Hydrogen	81-89	L1 cell adhesion molecule	Homo sapiens	25-34	
18165316-7	2008	A homology model of hL1 Ig1-4 (residues 33-422), based on the structure of the Ig1-4 domains of axonin-1, suggests that Glu-33 and Tyr-418 hydrogen-bond at the interface of Ig1 and Ig4 to stabilize a horseshoe conformation of L1 that favors homophilic binding.	Hydrogen	139-147	L1 cell adhesion molecule	Homo sapiens	20-23	
18165316-7	2008	A homology model of hL1 Ig1-4 (residues 33-422), based on the structure of the Ig1-4 domains of axonin-1, suggests that Glu-33 and Tyr-418 hydrogen-bond at the interface of Ig1 and Ig4 to stabilize a horseshoe conformation of L1 that favors homophilic binding.	Hydrogen	139-147	L1 cell adhesion molecule	Homo sapiens	21-23	
11468348-2	2001	In the structure, four out of the six hypervariable loops of the Fab (complementarity determining regions [CDRs] L1, H1, H2, and H3) are involved in peptide association through hydrogen bonding, salt bridge formation, and hydrophobic interactions.	Hydrogen	177-185	L1 cell adhesion molecule	Homo sapiens	113-131	
16333500-1	2005	Treatment of a glycosylamine derived Cu(II) complex with ethylamine resulted in crystal-to-crystal transformation from trinuclear complex [Cu3(L1)2(EtNH2)2(MeOH)2]x2MeOHxCHCl3 (2x2MeOHxCHCl3) to a dimeric structure of mononuclear complex [Cu(HL1)(EtNH2)] (3) through proton transfer reaction and rearrangement of hydrogen bonding networks.	Hydrogen	313-321	L1 cell adhesion molecule	Homo sapiens	139-145