PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
33140638-0	2020	Voltammetric pH Measurements in Unadulterated Foodstuffs, Urine, and Serum with 3D-Printed Graphene/Poly(Lactic Acid) Electrodes.	Graphite	91-99	phenylalanine hydroxylase	Homo sapiens	13-15	
33167215-5	2021	An iridium oxide film was electrodeposited onto the graphite working electrode providing the pH sensitive layer, while the integrated circuit board allows for data acquisition and storing.	Graphite	52-60	phenylalanine hydroxylase	Homo sapiens	93-95	
33140638-4	2020	In this work, we describe a voltammetric pH sensor that uses a three-dimensional (3D)-printed graphene/poly(lactic acid) filament electrode that is pretreated to introduce quinone functional groups to the graphene surface.	Graphite	94-102	phenylalanine hydroxylase	Homo sapiens	41-43	
33140638-4	2020	In this work, we describe a voltammetric pH sensor that uses a three-dimensional (3D)-printed graphene/poly(lactic acid) filament electrode that is pretreated to introduce quinone functional groups to the graphene surface.	Graphite	205-213	phenylalanine hydroxylase	Homo sapiens	41-43	
31846894-0	2020	Graphene aerogel nanoparticles for in-situ loading/pH sensitive releasing anticancer drugs.	Graphite	0-8	phenylalanine hydroxylase	Homo sapiens	51-53	
34624190-0	2021	Defect Engineering of Graphene to Modulate pH Response of Graphene Devices.	Graphite	22-30	phenylalanine hydroxylase	Homo sapiens	43-45	
27940234-2	2017	Specifically, we prepared iron doped polyacrylic hydrazide modified reduced graphene nanocomposites (Fe@RGO/PAH) by in-situ polymerization approach and subsequent a one-pot reaction with hydrazine.	Graphite	76-84	phenylalanine hydroxylase	Homo sapiens	108-111	
34894599-1	2022	Electrografted anthraquinone on graphite was used as a probe to monitor the pH change at the biofilm-electrode interface at the anode of a microbial fuel cell inoculated with wastewater.	Graphite	32-40	phenylalanine hydroxylase	Homo sapiens	76-78	
25686536-0	2015	The power of power: electrokinetic control of PAH interactions with exfoliated graphite.	Graphite	79-87	phenylalanine hydroxylase	Homo sapiens	46-49	
24270708-6	2014	We demonstrate that deuterium atoms adsorbed on graphite can react with adsorbed PAH molecules, forming superhydrogenated PAH species.	Graphite	48-56	phenylalanine hydroxylase	Homo sapiens	81-84	
24270708-6	2014	We demonstrate that deuterium atoms adsorbed on graphite can react with adsorbed PAH molecules, forming superhydrogenated PAH species.	Graphite	48-56	phenylalanine hydroxylase	Homo sapiens	122-125	
23081889-0	2012	A boron-containing PAH as a substructure of boron-doped graphene.	Graphite	56-64	phenylalanine hydroxylase	Homo sapiens	19-22	
7687023-3	1993	On the basis of PAH levels in the work environment and hydroxypyrene concentrations in the urine, the workers from the graphite electrode producing plant were the most exposed.	Graphite	119-127	phenylalanine hydroxylase	Homo sapiens	16-19	
34624190-9	2021	The overall pH-sensing characteristics of the graphene will be determined by the balance of these two mechanisms.	Graphite	46-54	phenylalanine hydroxylase	Homo sapiens	12-14	
34624190-0	2021	Defect Engineering of Graphene to Modulate pH Response of Graphene Devices.	Graphite	58-66	phenylalanine hydroxylase	Homo sapiens	43-45	
34624190-1	2021	Graphene-based pH sensors are a robust, durable, sensitive, and scalable approach for the sensitive detection of pH in various environments.	Graphite	0-8	phenylalanine hydroxylase	Homo sapiens	15-17	
34624190-1	2021	Graphene-based pH sensors are a robust, durable, sensitive, and scalable approach for the sensitive detection of pH in various environments.	Graphite	0-8	phenylalanine hydroxylase	Homo sapiens	113-115	
34624190-2	2021	However, the mechanisms through which graphene responds to pH variations are not well-understood yet.	Graphite	38-46	phenylalanine hydroxylase	Homo sapiens	59-61	
34624190-3	2021	This study provides a new look into the surface science of graphene-based pH sensors to address the existing gaps and inconsistencies among the literature concerning sensing response, the role of defects, and surface/solution interactions.	Graphite	59-67	phenylalanine hydroxylase	Homo sapiens	74-76	
35500463-0	2022	A wearable electrochemical sensor based on beta-CD functionalized graphene for pH and potassium ion analysis in sweat.	Graphite	66-74	phenylalanine hydroxylase	Homo sapiens	79-81	
35500463-2	2022	The sensor was composed of flexible reference electrode, pH response electrode and K+ selective electrode, which were prepared through printing beta-CD functionalized graphene (beta-CD/RGO) water suspension on conductive PET substrate with microelectronic printer.	Graphite	167-175	phenylalanine hydroxylase	Homo sapiens	57-59	
35569853-1	2022	Here, nanocomposite-decorated laser-induced graphene-based flexible hybrid sensor is newly developed for simultaneous detection of heavy metals, pesticides, and pH in freshwater.	Graphite	44-52	phenylalanine hydroxylase	Homo sapiens	161-163	
35569853-7	2022	Furthermore, a polyaniline/antimony/laser-induced graphene-based pH sensor is also integrated, showing an excellent sensitivity of -72.08 mV pH-1 in the pH range (2-9).	Graphite	50-58	phenylalanine hydroxylase	Homo sapiens	65-67	
35569853-7	2022	Furthermore, a polyaniline/antimony/laser-induced graphene-based pH sensor is also integrated, showing an excellent sensitivity of -72.08 mV pH-1 in the pH range (2-9).	Graphite	50-58	phenylalanine hydroxylase	Homo sapiens	141-143	
35569853-7	2022	Furthermore, a polyaniline/antimony/laser-induced graphene-based pH sensor is also integrated, showing an excellent sensitivity of -72.08 mV pH-1 in the pH range (2-9).	Graphite	50-58	phenylalanine hydroxylase	Homo sapiens	153-155