PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
30572687-0	2018	Theaflavins Improve Insulin Sensitivity through Regulating Mitochondrial Biosynthesis in Palmitic Acid-Induced HepG2 Cells.	theaflavin	0-11	insulin	Homo sapiens	20-27	
30572687-1	2018	Theaflavins, the characteristic and bioactive polyphenols in black tea, possess the potential improving effects on insulin resistance-associated metabolic abnormalities, including obesity and type 2 diabetes mellitus.	theaflavin	0-11	insulin	Homo sapiens	115-122	
30572687-3	2018	In this research, we investigated the protective effects of theaflavins against insulin resistance in HepG2 cells induced by palmitic acid.	theaflavin	60-71	insulin	Homo sapiens	80-87	
30572687-4	2018	Theaflavins significantly increased glucose uptake of insulin-resistant cells at noncytotoxic doses.	theaflavin	0-11	insulin	Homo sapiens	54-61	
30572687-8	2018	Taken together, these results suggested that theaflavins could improve hepatocellular insulin resistance induced by free fatty acids, at least partly through promoting mitochondrial biogenesis.	theaflavin	45-56	insulin	Homo sapiens	86-93	
30572687-9	2018	Theaflavins are promising functional food ingredients and medicines for improving insulin resistance-related disorders.	theaflavin	0-11	insulin	Homo sapiens	82-89