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10.1093/ndt/gfn473 http://scihub22266oqcxt.onion/10.1093/ndt/gfn473 18772177!ä!18772177 Warning: imagejpeg(C:\Inetpub\vhosts\kidney.de\httpdocs\phplern\18772177.jpg): Failed to open stream: No such file or directory in C:\Inetpub\vhosts\kidney.de\httpdocs\pget.php on line 117       Nephrol+Dial+Transplant 2009 ; 24 (1): 97-103 Nephropedia Template TP {{tp|p=18772177|t=2009. Impact of age on glomerular filtration estimates |pdf=|usr=}}{{18772177}} gab.com Text Impact of age on glomerular filtration estimates JO: Nephrol Dial Transplant http://www.kidney.de/pget.php?&tw=1&pmid=18772177 #FOAvip BACKGROUND: Glomerular filtration decreases progressively with age in adults. Predictive equation should have proper modelling to adequately account for normal senescence. METHODS: Corrected 24-h creatinine clearances (CCLs) were measured in a cohort of 773 outpatients from 18 to 90 years old. Multiple linear regression was used to model the effect of age on glomerular filtration. Comparisons were made with the simplified MDRD and the MAYO equations. Impact of the derived equation was tested in a second cohort of 7551 patients with normal serum creatinine. RESULTS: While all equations show declining function with age, our results suggest that the GFR reduction is progressive after the age of 30 and continue to decline steadily after the age of 60. This leads to a convex curve in the multiple regression analysis that is best fitted by an equation including the quadratic term (age(2)). In contrast, the MDRD equation produces a faster decrease in early adulthood and a flatter curve after the age of 60 while the MAYO equation produces a more linear effect. MDRD results in the normal range are lower than those estimated by the MAYO equation. These equations, as applied on an independent cohort of 7551 normal outpatients from 18 to 102 years, produce different profile of evolution of GFR with age. CONCLUSIONS: Inclusion of a quadratic term for age in the formula estimating GFR results in better modelling of the natural decline of renal function associated with ageing. Furthermore, as GFR steadily declines after the age of 30, a single cut-off value of GFR normality for all ages leads to underdiagnosis of young adults and over diagnosis of elderly individuals. Guidelines should take into account the observed reduction of kidney function with age in normal population for optimal evaluation of eGFR. Twit Text FOAVip Impact of age on glomerular filtration estimates ????Nephrol Dial Transplant http://www.kidney.de/pget.php?&tw=1&pmid=18772177 #FOAvip Twit Text # Free Paper on # # # # # LINK http://www.kidney.de/pget.php?&tw=1&pmid=18772177 #FOAvip English Wikipedia <ref>{{Cite pmid|18772177}}</ref> Impact of age on glomerular filtration estimates #MMPMID18772177 Douville P; Martel AR; Talbot J; Desmeules S; Langlois S; Agharazii M Nephrol Dial Transplant 2009[Jan]; 24 (1): 97-103 PMID18772177show ga BACKGROUND: Glomerular filtration decreases progressively with age in adults. Predictive equation should have proper modelling to adequately account for normal senescence. METHODS: Corrected 24-h creatinine clearances (CCLs) were measured in a cohort of 773 outpatients from 18 to 90 years old. Multiple linear regression was used to model the effect of age on glomerular filtration. Comparisons were made with the simplified MDRD and the MAYO equations. Impact of the derived equation was tested in a second cohort of 7551 patients with normal serum creatinine. RESULTS: While all equations show declining function with age, our results suggest that the GFR reduction is progressive after the age of 30 and continue to decline steadily after the age of 60. This leads to a convex curve in the multiple regression analysis that is best fitted by an equation including the quadratic term (age(2)). In contrast, the MDRD equation produces a faster decrease in early adulthood and a flatter curve after the age of 60 while the MAYO equation produces a more linear effect. MDRD results in the normal range are lower than those estimated by the MAYO equation. These equations, as applied on an independent cohort of 7551 normal outpatients from 18 to 102 years, produce different profile of evolution of GFR with age. CONCLUSIONS: Inclusion of a quadratic term for age in the formula estimating GFR results in better modelling of the natural decline of renal function associated with ageing. Furthermore, as GFR steadily declines after the age of 30, a single cut-off value of GFR normality for all ages leads to underdiagnosis of young adults and over diagnosis of elderly individuals. Guidelines should take into account the observed reduction of kidney function with age in normal population for optimal evaluation of eGFR. |*Glomerular Filtration Rate[MESH] |Adolescent[MESH] |Adult[MESH] |Aged[MESH] |Aged, 80 and over[MESH] |Aging/*physiology[MESH] |Cohort Studies[MESH] |Creatinine/blood/metabolism[MESH] |Female[MESH] |Humans[MESH] |Linear Models[MESH] |Male[MESH] |Middle Aged[MESH] |Models, Biological[MESH] |Reference Values[MESH] |Regression Analysis[MESH] |Reproducibility of Results[MESH]Impact of age on glomerular filtration estimates (epmc).pdf DeepDyve Pubget Overpricing