PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
32861940-5	2020	However, due to global climatic changes, the secondary source of radiation pollution of the sea may be the Novaya Zemlya ice sheet, in which huge quantities of technogenic radionuclides were deposited during atmospheric tests of the 1950s and 1960s.	Radioisotopes	172-185	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	92-95	
32868093-0	2020	Models for predicting the transport of radionuclides in the Red Sea.	Radioisotopes	39-52	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	64-67	
28559055-0	2017	Determination of sedimentation, diffusion, and mixing rates in coastal sediments of the eastern Red Sea via natural and anthropogenic fallout radionuclides.	Radioisotopes	142-155	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	100-103	
29108726-3	2018	The spatial-temporal changes in the 239,240Pu distribution as well as effective half-life for these radionuclides in the Black Sea surface water in deep-sea area are presented.	Radioisotopes	100-113	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	127-130	
29108726-3	2018	The spatial-temporal changes in the 239,240Pu distribution as well as effective half-life for these radionuclides in the Black Sea surface water in deep-sea area are presented.	Radioisotopes	100-113	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	153-156	
25561003-1	2015	This study aims to establish a managed sampling plan for rapid estimate of natural radio-nuclides diffusion in the northern coast of the Oman Sea.	Radioisotopes	83-97	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	142-145	
26999368-0	2016	Radionuclides in ornithogenic sediments as evidence for recent warming in the Ross Sea region, Antarctica.	Radioisotopes	0-13	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	83-86	
25912795-0	2015	Distribution of radionuclides in a marine sediment core off the waterspout of the nuclear power plants in Daya Bay, northeastern South China Sea.	Radioisotopes	16-29	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	141-144	
18986686-1	2009	Artificial radionuclides enter the Mediterranean Sea mainly through atmospheric deposition following nuclear weapons tests and the Chernobyl accident, but also through the river discharge of nuclear facility effluents.	Radioisotopes	11-24	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	49-52	
24631918-1	2014	An approach to estimate the rate of biogenic sedimentation in the Black Sea using the naturally occurring radionuclide (40)K has been considered.	Radioisotopes	106-118	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	72-75	
23541149-1	2013	There is concern that sea level rise associated with projected climate change will lead to the inundation, flooding and erosion of soils and sediments contaminated with radionuclides at coastal nuclear sites, such as Dounreay (UK), with seawater.	Radioisotopes	169-182	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	22-25	
26224926-6	2012	Besides, a possibility of penetration of radionuclides into the sea waters from the additional radioactive sources is not excluded.	Radioisotopes	41-54	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	64-67	
21809941-5	2011	The radionuclides Cs-134 and Cs-137 accounting for the highest percentage of the released long-lived radionuclides were deposited on the sea surface with an initial ratio of 0.5.	Radioisotopes	4-17	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	137-140	
18986686-3	2009	However, deep sea sediments have the potential to store and accumulate pollutants, including artificial radionuclides.	Radioisotopes	104-117	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	14-17	
11381753-0	2001	The problem of transfer of radionuclide pollution by sea ice.	Radioisotopes	27-39	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	53-56	
12782473-1	2003	The predictions from MEAD, a model that simulates the transport of radionuclides in the marine environment, are presented for the Irish Sea.	Radioisotopes	67-80	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	136-139	
16197983-4	2006	Coupled with previous observations of higher radionuclide specific activities in some sea ice rafted sediments relative to bottom sediments, these new observations indicate that comparatively high as well as variable radioactive contaminant burdens in ice rafted sediments must be common and geographically independent of proximity to known contaminant sources.	Radioisotopes	45-57	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	86-89	
16376698-3	2006	There are two distinct basins in the western Irish Sea separated by an area of restricted depth and this bathymetry is reflected in the radionuclide concentrations.	Radioisotopes	136-148	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	51-54	
16210328-0	2006	Gamma-emitting radionuclides in the shallow marine sediments off the Sindh coast, Arabian Sea.	Radioisotopes	15-28	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	90-93	
16210328-5	2006	As no data on radioactivity of the coastal environment of Pakistan are available, the data presented here will serve as baseline information on radionuclide concentration in shallow sea sediments off the Sindh coast.	Radioisotopes	144-156	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	182-185	
10568278-1	1999	Sediment cores collected from the deep basins of the East Sea (Sea of Japan) provide an ongoing and historical record of artificial radionuclides contamination into one of the most highly publicized radioactive waste dumping areas in the world ocean.	Radioisotopes	132-145	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	58-61	
11378923-6	2001	These data therefore reveal a continuing significant pollution of the waters of the Baltic Sea resulting from the Chernobyl power plant accident, a pollution compounded by the slow rate of radionuclide self-cleaning and significant probability of sudden regional concentration increase.	Radioisotopes	189-201	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	91-94	
11601529-3	2001	This manuscript describes ongoing research to estimate radionuclide fluxes to the Kara Sea from these river systems.	Radioisotopes	55-67	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	87-90	
10568278-1	1999	Sediment cores collected from the deep basins of the East Sea (Sea of Japan) provide an ongoing and historical record of artificial radionuclides contamination into one of the most highly publicized radioactive waste dumping areas in the world ocean.	Radioisotopes	132-145	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	63-66	
9745701-0	1998	Radionuclide accumulation in near-shore sediments along the Bulgarian Black Sea Coast.	Radioisotopes	0-12	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	76-79	
10376324-2	1999	Kd values for use in modeling radionuclide dispersion in the Kara Sea have been determined as part of several international programs addressing the problem of radioactive debris residing in Arctic Seas.	Radioisotopes	30-42	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	66-69	
9241883-3	1997	The results show that doses for the shorter-lived radionuclides (e.g. 137Cs) are derived mainly from seafood production in the Barents Sea.	Radioisotopes	50-63	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	135-138	
9241886-9	1997	Thus, the general level of radionuclides in waters, sediments and biota in the fjords is, somewhat higher or similar to that of the open Kara Sea, i.e. significantly lower than in other adjacent marine systems (e.g. Irish Sea, Baltic Sea, North Sea).	Radioisotopes	27-40	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	222-225	
9241886-9	1997	Thus, the general level of radionuclides in waters, sediments and biota in the fjords is, somewhat higher or similar to that of the open Kara Sea, i.e. significantly lower than in other adjacent marine systems (e.g. Irish Sea, Baltic Sea, North Sea).	Radioisotopes	27-40	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	222-225	
9241886-9	1997	Thus, the general level of radionuclides in waters, sediments and biota in the fjords is, somewhat higher or similar to that of the open Kara Sea, i.e. significantly lower than in other adjacent marine systems (e.g. Irish Sea, Baltic Sea, North Sea).	Radioisotopes	27-40	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	222-225	
35278910-0	2022	The impact of circulation features on the dispersion of radionuclides after the nuclear submarine accident in Chazhma Bay (Japan Sea) in 1985: A retrospective Lagrangian simulation.	Radioisotopes	56-69	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	129-132	
35278910-3	2022	The spread of radionuclides on the sea surface in the adjacent Ussuri Bay was strongly influenced by two typhoons, which mixed the polluted water in the bay and reduced the concentration of radionuclides in the fallen spot.	Radioisotopes	14-27	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	35-38	
35278910-3	2022	The spread of radionuclides on the sea surface in the adjacent Ussuri Bay was strongly influenced by two typhoons, which mixed the polluted water in the bay and reduced the concentration of radionuclides in the fallen spot.	Radioisotopes	190-203	S13 erythroblastosis (avian) oncogene homolog	Homo sapiens	35-38