PMID-sentid Pub_year Sent_text comp_official_name comp_offsetprotein_name organism prot_offset 19721904-10 2009 Among the patients who presented lower concentrations of CRP it was found higher beta-carotene inadequacy (64.8%) and 50% of retinol inadequacy. beta Carotene 81-94 C-reactive protein Homo sapiens 57-60 12324296-9 2002 C-reactive protein concentrations were inversely related to beta-carotene (P < 0.001), lutein and zeaxanthin (P < 0.001), and lycopene (P = 0.023) concentrations. beta Carotene 60-73 C-reactive protein Homo sapiens 0-18 15345737-6 2004 RESULTS: The serum beta-carotene concentration was inversely associated with C-reactive protein and interleukin-6 levels. beta Carotene 19-32 C-reactive protein Homo sapiens 77-95 15575349-8 2004 beta-Carotene was inverse related to leukocytes (-0.23+/-0.07; p = 0.007) and CRP (-1.09+/-0.30; p = 0.0003) per 1 micromol/l. beta Carotene 0-13 C-reactive protein Homo sapiens 78-81 12947436-5 2003 RESULTS: C-reactive protein concentration (dichotomized at the sex-specific 85th percentile) was inversely and significantly associated with concentrations of retinol, retinyl esters, vitamin C, alpha-carotene, beta-carotene, cryptoxanthin, lutein/zeaxanthin, lycopene, and selenium after adjustment for age, sex, race or ethnicity, education, cotinine concentration, body mass index, leisure-time physical activity, and aspirin use. beta Carotene 211-224 C-reactive protein Homo sapiens 9-27 17852073-6 2008 Plasma beta-carotene inversely correlated with IL-6 (r = -0.46, p=0.0002) and CRP (r = -0.41, p = 0.001). beta Carotene 7-20 C-reactive protein Homo sapiens 78-81 16835597-6 2007 RESULTS: We observe a negative trend across quartiles of plasma beta-carotene for most biological variables clustering in the insulin resistance syndrome, as well as for traditional and new risk factors for type II diabetes and cardiovascular disease (CVD), including C-reactive protein and gamma-glutamyltranspeptidase (P<0.05). beta Carotene 64-77 C-reactive protein Homo sapiens 268-286 15536598-8 2004 Stratified factor analyses in smoking subgroups, obese, and in under-reporters of energy, largely confirmed the results although in male never-smokers a combination of high fiber vitamin C/beta carotene intake was associated with low CRP levels. beta Carotene 189-202 C-reactive protein Homo sapiens 234-237 15133321-8 2004 There were significant negative correlations between CRP levels and serum beta-carotene and retinol concentrations. beta Carotene 74-87 C-reactive protein Homo sapiens 53-56 15133321-11 2004 The inverse correlations between CRP and beta-carotene or retinol indicate either decreased synthesis or increased utilization of these antioxidants. beta Carotene 41-54 C-reactive protein Homo sapiens 33-36 14743546-7 2003 Using a limit of 0.6 mg/L (75th percentile), significantly lower levels were observed for transthyretin, iron, retinol, and beta-carotene in the group with the higher CRP levels. beta Carotene 124-137 C-reactive protein Homo sapiens 167-170 12741936-7 2003 There were significant inverse linear relationships between concentrations of CRP and plasma concentrations of the antioxidants lycopene, beta-carotene, cryptoxanthin and retinol. beta Carotene 138-151 C-reactive protein Homo sapiens 78-81 34916884-0 2021 Rising Plasma Beta-Carotene Is Associated With Diminishing C-Reactive Protein in Patients Consuming a Dark Green Leafy Vegetable-Rich, Low Inflammatory Foods Everyday (LIFE) Diet. beta Carotene 14-27 C-reactive protein Homo sapiens 59-77 12056790-7 2002 In normal subjects and cancer patients, C-reactive protein concentrations were inversely correlated with circulating concentrations of retinol (r(2)=0.162), alpha-tocopherol (r(2)=0.297), lutein (r(2)=0.256), lycopene (r(2)=-0.171), alpha-(r(2)=0.140) and beta-carotene (r(2)=0.254): (all P<0.001). beta Carotene 256-269 C-reactive protein Homo sapiens 40-58 11493133-7 2001 CONCLUSIONS: The strong and inverse association of serum beta-carotene level with C-reactive protein level and white blood cell count suggests that the relationship between serum beta-carotene concentration and disease risk might be confounded by inflammation. beta Carotene 57-70 C-reactive protein Homo sapiens 82-100 11493133-7 2001 CONCLUSIONS: The strong and inverse association of serum beta-carotene level with C-reactive protein level and white blood cell count suggests that the relationship between serum beta-carotene concentration and disease risk might be confounded by inflammation. beta Carotene 179-192 C-reactive protein Homo sapiens 82-100 34916884-2 2021 In this longitudinal retrospective chart review, we investigate whether patients intensively counseled to eat a specific diet high in dark green leafy vegetables, and thus high beta-carotene, have reductions in plasma high-sensitivity CRP (hsCRP). beta Carotene 177-190 C-reactive protein Homo sapiens 235-238 34916884-7 2021 The change in beta-carotene was inversely correlated with change in CRP (r = -0.68, P < .0001). beta Carotene 14-27 C-reactive protein Homo sapiens 68-71 24744306-11 2014 Serum beta-carotene significantly moderated the associations between dietary beta-carotene and CRP (P-interaction < 0.05), and quartile 4 of dietary beta-carotene was associated with lower CRP concentrations only among participants with serum beta-carotene > 0.43 mumol/L. beta Carotene 6-19 C-reactive protein Homo sapiens 77-98 27395328-10 2017 A plant-sourced pattern (beta-carotene, vitamin A, lutein and zeaxanthin) was inversely associated with CRP (p for trend across quartiles 0.005). beta Carotene 25-38 C-reactive protein Homo sapiens 104-107 24744306-11 2014 Serum beta-carotene significantly moderated the associations between dietary beta-carotene and CRP (P-interaction < 0.05), and quartile 4 of dietary beta-carotene was associated with lower CRP concentrations only among participants with serum beta-carotene > 0.43 mumol/L. beta Carotene 6-19 C-reactive protein Homo sapiens 95-98 24744306-11 2014 Serum beta-carotene significantly moderated the associations between dietary beta-carotene and CRP (P-interaction < 0.05), and quartile 4 of dietary beta-carotene was associated with lower CRP concentrations only among participants with serum beta-carotene > 0.43 mumol/L. beta Carotene 77-90 C-reactive protein Homo sapiens 95-98 24744306-11 2014 Serum beta-carotene significantly moderated the associations between dietary beta-carotene and CRP (P-interaction < 0.05), and quartile 4 of dietary beta-carotene was associated with lower CRP concentrations only among participants with serum beta-carotene > 0.43 mumol/L. beta Carotene 77-90 C-reactive protein Homo sapiens 95-98 24744306-13 2014 Serum beta-carotene was also a moderator of the dietary beta-carotene and CRP association. beta Carotene 6-19 C-reactive protein Homo sapiens 74-77 24744306-13 2014 Serum beta-carotene was also a moderator of the dietary beta-carotene and CRP association. beta Carotene 56-69 C-reactive protein Homo sapiens 74-77 21765609-5 2011 Plasma C-reactive protein levels significantly correlated with dietary intakes of vitamin C (r = -0.30, p<0.005), beta-carotene (r = -0.23, p<0.05), and folate (r = -0.31, p<0.005). beta Carotene 117-130 C-reactive protein Homo sapiens 7-25 25377123-3 2014 We investigated long-term associations between the antioxidant nutrient (vitamin C, alpha-tocopherol, beta-carotene) status and C-reactive protein (CRP) in a population-based cohort. beta Carotene 102-115 C-reactive protein Homo sapiens 128-146 25377123-8 2014 The beta-carotene status (n = 2,048) was inversely associated with elevated CRP [adjusted OR quintile 5 vs. 1: OR 0.61 (95% CI 0.38-0.98), p for trend = 0.01]. beta Carotene 4-17 C-reactive protein Homo sapiens 76-79 20580698-5 2010 Serum alpha-carotene and beta-carotene concentrations were significantly associated with serum C-reactive protein (CRP) concentrations in men. beta Carotene 25-38 C-reactive protein Homo sapiens 95-113 20580698-5 2010 Serum alpha-carotene and beta-carotene concentrations were significantly associated with serum C-reactive protein (CRP) concentrations in men. beta Carotene 25-38 C-reactive protein Homo sapiens 115-118