PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
8569695-6	1996	Expressed human microsomal epoxide hydrolase and HLM catalyzed the attack of water predominantly (approximately 96%) at C5 of the 5R,6S-oxide, whereas 5S,6R-oxide was attacked less selectivity (approximately 60% at C5).	Water	77-82	epoxide hydrolase 1	Homo sapiens	16-44	
3780165-3	1986	During mouth breathing, temperatures are significantly higher (TI = 28.1 degrees C, TE = 31.5 degrees C) and the amount of expired water larger (MEH2O = 27.8 mg dm-3 BTPS) than during nose breathing (TI = 24.8 degrees C; TE = 29.6 degrees C; MEH2O = 26.6 mg dm-3 BTPS).	Water	131-136	epoxide hydrolase 1	Homo sapiens	145-148	
7835893-1	1994	Human microsomal epoxide hydrolase (mEH) is a xenobiotic-metabolizing enzyme that detoxifies reactive epoxides to more water soluble dihydrodiol compounds.	Water	119-124	epoxide hydrolase 1	Homo sapiens	6-34	
7516776-1	1994	Human microsomal epoxide hydrolase (mEH) is a biotransformation enzyme that metabolizes reactive epoxide intermediates to more water-soluble trans-dihydrodiol derivatives.	Water	127-132	epoxide hydrolase 1	Homo sapiens	6-34	
24684587-0	2014	Evaporative assembly of MEH-PPV rings using mixed solvents at the air/water interface.	Water	70-75	epoxide hydrolase 1	Homo sapiens	24-27	
25280013-1	2015	A simple and effective method was reported for the preparation from MEH-PPV of conjugated polymer nanoparticles (Pdots) that are water-soluble and well dispersed.	Water	129-134	epoxide hydrolase 1	Homo sapiens	68-71	
22196349-2	2012	After the surface modification, the water contact angle of MEH-PPV is changed from 95.5  to 82.1  without influence on its optical properties (based on the UV and PL spectra), and the water droplet can be absorbed on the modified MEH-PPV surface without sliding even at substrate tilt angles of 90  and 180 .	Water	36-41	epoxide hydrolase 1	Homo sapiens	59-62	
22196349-2	2012	After the surface modification, the water contact angle of MEH-PPV is changed from 95.5  to 82.1  without influence on its optical properties (based on the UV and PL spectra), and the water droplet can be absorbed on the modified MEH-PPV surface without sliding even at substrate tilt angles of 90  and 180 .	Water	36-41	epoxide hydrolase 1	Homo sapiens	230-233	
22196349-2	2012	After the surface modification, the water contact angle of MEH-PPV is changed from 95.5  to 82.1  without influence on its optical properties (based on the UV and PL spectra), and the water droplet can be absorbed on the modified MEH-PPV surface without sliding even at substrate tilt angles of 90  and 180 .	Water	184-189	epoxide hydrolase 1	Homo sapiens	59-62	
22196349-2	2012	After the surface modification, the water contact angle of MEH-PPV is changed from 95.5  to 82.1  without influence on its optical properties (based on the UV and PL spectra), and the water droplet can be absorbed on the modified MEH-PPV surface without sliding even at substrate tilt angles of 90  and 180 .	Water	184-189	epoxide hydrolase 1	Homo sapiens	230-233	
22196349-4	2012	In addition, the water transport test indicates that the modified MEH-PPV can be a candidate for transporting water droplet.	Water	17-22	epoxide hydrolase 1	Homo sapiens	66-69	
22196349-4	2012	In addition, the water transport test indicates that the modified MEH-PPV can be a candidate for transporting water droplet.	Water	110-115	epoxide hydrolase 1	Homo sapiens	66-69	
11721893-3	2001	Images of MEH-PPV were obtained with comparable spatial resolution in both air and water.	Water	83-88	epoxide hydrolase 1	Homo sapiens	10-13	
10576413-1	1999	Microsomal epoxide hydrolase catalyses the hydrolysis of epoxides to water-soluble trans-dihydrodiols.	Water	69-74	epoxide hydrolase 1	Homo sapiens	0-28	
24684587-4	2014	The morphology of the MEH-PPV thin film at the air/water interface can be controlled by the spreading solvent.	Water	51-56	epoxide hydrolase 1	Homo sapiens	22-25