A user-friendly tool for incremental haemodialysis prescription

A user-friendly tool for incremental haemodialysis prescription Nephrol Dial Transplant 2018; doi: 10.1093/ndt/gfx343 In the above article there were errors in Tables 2 and 4 and Figure 5. The corrected versions can be seen below: Table 2 Formulae to be copied into the associated cells in column B of sheet 1 (Figure 1) B16 Eq.1 = (B3 − B4) × 1000/B5 B17 Eq. 2 = 0.537 × B11 × (1+ 0.0549 × (B9 − 500)/300) B18 Eq. 3 = 0.894 × B6 + B7 B19 Eq. 4 = EXP(B17/B18 × (1 − B18/B9)) B20 Eq. 5 = B18 × (B19 − 1)/(B19 − B18/B9) B21 Eq. 6 = (B18 − B20)/B18 × (B7+ B8 + B16) B22 Eq. 7 = 0.894 × B6/B18 B23 Eq. 8 = (B20 + B21) × B22 B24 Eq. 9 = − LN(B13/B12 − 0.0174/B2 × B5/60) + (4 − 3.5 × B13/B12) × (B3 − B4)/B4 B25 Eq. 10 = (B23+B32) × B5/B24/1000 B26 Eq. 11 = B24 × (B5/(B5 + 30.7)) B27 Eq. 12 = B13/(EXP(LN(B12) − B26/(B24/LN(B12/B13)))) B28 Eq. 13 = LN(B27 × B12/B13)/(B27 × LN(B12/B13)) B29 Eq. 14 = B25/B28 B30 Eq. 15 = B29/B4 B31 Eq. 16 = B12 × (1.075 − (0.38 × (1 − B13/B12)+0.059) × 1440/(B2 × 1440 − B5)) B32 Eq. 17 = B14 × B15/B31/1440 B33 Eq. 18 = B32 × 35/B29 B34 Eq. 19 = 0.1532 × B332− 2.225 × B33 + 7.9006 B35 Eq. 20 = 0.0221 × B332− 0.4979 × B33 + 2.24 B36 Eq. 21 = 0.0068 × B332− 0.2514 × B33 + 1.2979 B37 Eq. 22 = 0.1755 × B332− 2.7563 × B33 + 10.999 B38 Eq. 23 = 0.0776 × B332− 0.9091 × B33 + 3.157 B39 Eq. 24 = 0.0145 × B332− 0.2549 × B33 + 1.2496 B16 Eq.1 = (B3 − B4) × 1000/B5 B17 Eq. 2 = 0.537 × B11 × (1+ 0.0549 × (B9 − 500)/300) B18 Eq. 3 = 0.894 × B6 + B7 B19 Eq. 4 = EXP(B17/B18 × (1 − B18/B9)) B20 Eq. 5 = B18 × (B19 − 1)/(B19 − B18/B9) B21 Eq. 6 = (B18 − B20)/B18 × (B7+ B8 + B16) B22 Eq. 7 = 0.894 × B6/B18 B23 Eq. 8 = (B20 + B21) × B22 B24 Eq. 9 = − LN(B13/B12 − 0.0174/B2 × B5/60) + (4 − 3.5 × B13/B12) × (B3 − B4)/B4 B25 Eq. 10 = (B23+B32) × B5/B24/1000 B26 Eq. 11 = B24 × (B5/(B5 + 30.7)) B27 Eq. 12 = B13/(EXP(LN(B12) − B26/(B24/LN(B12/B13)))) B28 Eq. 13 = LN(B27 × B12/B13)/(B27 × LN(B12/B13)) B29 Eq. 14 = B25/B28 B30 Eq. 15 = B29/B4 B31 Eq. 16 = B12 × (1.075 − (0.38 × (1 − B13/B12)+0.059) × 1440/(B2 × 1440 − B5)) B32 Eq. 17 = B14 × B15/B31/1440 B33 Eq. 18 = B32 × 35/B29 B34 Eq. 19 = 0.1532 × B332− 2.225 × B33 + 7.9006 B35 Eq. 20 = 0.0221 × B332− 0.4979 × B33 + 2.24 B36 Eq. 21 = 0.0068 × B332− 0.2514 × B33 + 1.2979 B37 Eq. 22 = 0.1755 × B332− 2.7563 × B33 + 10.999 B38 Eq. 23 = 0.0776 × B332− 0.9091 × B33 + 3.157 B39 Eq. 24 = 0.0145 × B332− 0.2549 × B33 + 1.2496 The key formulae are written in bold. Table 2 Formulae to be copied into the associated cells in column B of sheet 1 (Figure 1) B16 Eq.1 = (B3 − B4) × 1000/B5 B17 Eq. 2 = 0.537 × B11 × (1+ 0.0549 × (B9 − 500)/300) B18 Eq. 3 = 0.894 × B6 + B7 B19 Eq. 4 = EXP(B17/B18 × (1 − B18/B9)) B20 Eq. 5 = B18 × (B19 − 1)/(B19 − B18/B9) B21 Eq. 6 = (B18 − B20)/B18 × (B7+ B8 + B16) B22 Eq. 7 = 0.894 × B6/B18 B23 Eq. 8 = (B20 + B21) × B22 B24 Eq. 9 = − LN(B13/B12 − 0.0174/B2 × B5/60) + (4 − 3.5 × B13/B12) × (B3 − B4)/B4 B25 Eq. 10 = (B23+B32) × B5/B24/1000 B26 Eq. 11 = B24 × (B5/(B5 + 30.7)) B27 Eq. 12 = B13/(EXP(LN(B12) − B26/(B24/LN(B12/B13)))) B28 Eq. 13 = LN(B27 × B12/B13)/(B27 × LN(B12/B13)) B29 Eq. 14 = B25/B28 B30 Eq. 15 = B29/B4 B31 Eq. 16 = B12 × (1.075 − (0.38 × (1 − B13/B12)+0.059) × 1440/(B2 × 1440 − B5)) B32 Eq. 17 = B14 × B15/B31/1440 B33 Eq. 18 = B32 × 35/B29 B34 Eq. 19 = 0.1532 × B332− 2.225 × B33 + 7.9006 B35 Eq. 20 = 0.0221 × B332− 0.4979 × B33 + 2.24 B36 Eq. 21 = 0.0068 × B332− 0.2514 × B33 + 1.2979 B37 Eq. 22 = 0.1755 × B332− 2.7563 × B33 + 10.999 B38 Eq. 23 = 0.0776 × B332− 0.9091 × B33 + 3.157 B39 Eq. 24 = 0.0145 × B332− 0.2549 × B33 + 1.2496 B16 Eq.1 = (B3 − B4) × 1000/B5 B17 Eq. 2 = 0.537 × B11 × (1+ 0.0549 × (B9 − 500)/300) B18 Eq. 3 = 0.894 × B6 + B7 B19 Eq. 4 = EXP(B17/B18 × (1 − B18/B9)) B20 Eq. 5 = B18 × (B19 − 1)/(B19 − B18/B9) B21 Eq. 6 = (B18 − B20)/B18 × (B7+ B8 + B16) B22 Eq. 7 = 0.894 × B6/B18 B23 Eq. 8 = (B20 + B21) × B22 B24 Eq. 9 = − LN(B13/B12 − 0.0174/B2 × B5/60) + (4 − 3.5 × B13/B12) × (B3 − B4)/B4 B25 Eq. 10 = (B23+B32) × B5/B24/1000 B26 Eq. 11 = B24 × (B5/(B5 + 30.7)) B27 Eq. 12 = B13/(EXP(LN(B12) − B26/(B24/LN(B12/B13)))) B28 Eq. 13 = LN(B27 × B12/B13)/(B27 × LN(B12/B13)) B29 Eq. 14 = B25/B28 B30 Eq. 15 = B29/B4 B31 Eq. 16 = B12 × (1.075 − (0.38 × (1 − B13/B12)+0.059) × 1440/(B2 × 1440 − B5)) B32 Eq. 17 = B14 × B15/B31/1440 B33 Eq. 18 = B32 × 35/B29 B34 Eq. 19 = 0.1532 × B332− 2.225 × B33 + 7.9006 B35 Eq. 20 = 0.0221 × B332− 0.4979 × B33 + 2.24 B36 Eq. 21 = 0.0068 × B332− 0.2514 × B33 + 1.2979 B37 Eq. 22 = 0.1755 × B332− 2.7563 × B33 + 10.999 B38 Eq. 23 = 0.0776 × B332− 0.9091 × B33 + 3.157 B39 Eq. 24 = 0.0145 × B332− 0.2549 × B33 + 1.2496 The key formulae are written in bold. Table 4 Formulae to be copied into the associated cells in column B of Sheet 2 (Figure 2) Cell Equations Spreadsheet formula B6 Eq. 25 = B4 × (B5 + 30.7)/B5 B7 Eq. 26 = EXP(− B6/1.18) B8 Eq. 27 = 1 − 0.44 × B6/(B5/60) B9 Eq. 28 = LN(B8/B7)/(B8 × LN(1/B7)) B10 Eq. 29 = B3 × B9 B11 Eq. 30 = B6 × B10/B5 × 1000 − B2 Cell Equations Spreadsheet formula B6 Eq. 25 = B4 × (B5 + 30.7)/B5 B7 Eq. 26 = EXP(− B6/1.18) B8 Eq. 27 = 1 − 0.44 × B6/(B5/60) B9 Eq. 28 = LN(B8/B7)/(B8 × LN(1/B7)) B10 Eq. 29 = B3 × B9 B11 Eq. 30 = B6 × B10/B5 × 1000 − B2 The key formulae are written in bold. Table 4 Formulae to be copied into the associated cells in column B of Sheet 2 (Figure 2) Cell Equations Spreadsheet formula B6 Eq. 25 = B4 × (B5 + 30.7)/B5 B7 Eq. 26 = EXP(− B6/1.18) B8 Eq. 27 = 1 − 0.44 × B6/(B5/60) B9 Eq. 28 = LN(B8/B7)/(B8 × LN(1/B7)) B10 Eq. 29 = B3 × B9 B11 Eq. 30 = B6 × B10/B5 × 1000 − B2 Cell Equations Spreadsheet formula B6 Eq. 25 = B4 × (B5 + 30.7)/B5 B7 Eq. 26 = EXP(− B6/1.18) B8 Eq. 27 = 1 − 0.44 × B6/(B5/60) B9 Eq. 28 = LN(B8/B7)/(B8 × LN(1/B7)) B10 Eq. 29 = B3 × B9 B11 Eq. 30 = B6 × B10/B5 × 1000 − B2 The key formulae are written in bold. FIGURE 5 View largeDownload slide Calculation of PCRn for thrice-weekly and twice-weekly HD schedules. The formulae introduced by Depner and Daugirdas [20] were typed on the cells B8B15, for the Patient 0, to be used as template with one column per patient. Of note, the equations described by Depner and Daugirdas [20] were based on spKt/V values. However, our calculations are based on eKt/V and Vdp values, in agreement with very recent data by Daugirdas [21]. In contrast to the Sheet 1, here one has to use only concentrations of serum urea nitrogen in mg/dL. FIGURE 5 View largeDownload slide Calculation of PCRn for thrice-weekly and twice-weekly HD schedules. The formulae introduced by Depner and Daugirdas [20] were typed on the cells B8B15, for the Patient 0, to be used as template with one column per patient. Of note, the equations described by Depner and Daugirdas [20] were based on spKt/V values. However, our calculations are based on eKt/V and Vdp values, in agreement with very recent data by Daugirdas [21]. In contrast to the Sheet 1, here one has to use only concentrations of serum urea nitrogen in mg/dL. The errors have been corrected online and in print. © The Author(s) 2018. Published by Oxford University Press on behalf of ERA-EDTA. All rights reserved. This article is published and distributed under the terms of the Oxford University Press, Standard Journals Publication Model (https://academic.oup.com/journals/pages/about_us/legal/notices) http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Nephrology Dialysis Transplantation Oxford University Press

A user-friendly tool for incremental haemodialysis prescription

Loading next page...
 
/lp/ou_press/a-user-friendly-tool-for-incremental-haemodialysis-prescription-tEvGdT7f5i
Publisher
Oxford University Press
Copyright
© The Author(s) 2018. Published by Oxford University Press on behalf of ERA-EDTA. All rights reserved.
ISSN
0931-0509
eISSN
1460-2385
D.O.I.
10.1093/ndt/gfy081
Publisher site
See Article on Publisher Site

Abstract

Nephrol Dial Transplant 2018; doi: 10.1093/ndt/gfx343 In the above article there were errors in Tables 2 and 4 and Figure 5. The corrected versions can be seen below: Table 2 Formulae to be copied into the associated cells in column B of sheet 1 (Figure 1) B16 Eq.1 = (B3 − B4) × 1000/B5 B17 Eq. 2 = 0.537 × B11 × (1+ 0.0549 × (B9 − 500)/300) B18 Eq. 3 = 0.894 × B6 + B7 B19 Eq. 4 = EXP(B17/B18 × (1 − B18/B9)) B20 Eq. 5 = B18 × (B19 − 1)/(B19 − B18/B9) B21 Eq. 6 = (B18 − B20)/B18 × (B7+ B8 + B16) B22 Eq. 7 = 0.894 × B6/B18 B23 Eq. 8 = (B20 + B21) × B22 B24 Eq. 9 = − LN(B13/B12 − 0.0174/B2 × B5/60) + (4 − 3.5 × B13/B12) × (B3 − B4)/B4 B25 Eq. 10 = (B23+B32) × B5/B24/1000 B26 Eq. 11 = B24 × (B5/(B5 + 30.7)) B27 Eq. 12 = B13/(EXP(LN(B12) − B26/(B24/LN(B12/B13)))) B28 Eq. 13 = LN(B27 × B12/B13)/(B27 × LN(B12/B13)) B29 Eq. 14 = B25/B28 B30 Eq. 15 = B29/B4 B31 Eq. 16 = B12 × (1.075 − (0.38 × (1 − B13/B12)+0.059) × 1440/(B2 × 1440 − B5)) B32 Eq. 17 = B14 × B15/B31/1440 B33 Eq. 18 = B32 × 35/B29 B34 Eq. 19 = 0.1532 × B332− 2.225 × B33 + 7.9006 B35 Eq. 20 = 0.0221 × B332− 0.4979 × B33 + 2.24 B36 Eq. 21 = 0.0068 × B332− 0.2514 × B33 + 1.2979 B37 Eq. 22 = 0.1755 × B332− 2.7563 × B33 + 10.999 B38 Eq. 23 = 0.0776 × B332− 0.9091 × B33 + 3.157 B39 Eq. 24 = 0.0145 × B332− 0.2549 × B33 + 1.2496 B16 Eq.1 = (B3 − B4) × 1000/B5 B17 Eq. 2 = 0.537 × B11 × (1+ 0.0549 × (B9 − 500)/300) B18 Eq. 3 = 0.894 × B6 + B7 B19 Eq. 4 = EXP(B17/B18 × (1 − B18/B9)) B20 Eq. 5 = B18 × (B19 − 1)/(B19 − B18/B9) B21 Eq. 6 = (B18 − B20)/B18 × (B7+ B8 + B16) B22 Eq. 7 = 0.894 × B6/B18 B23 Eq. 8 = (B20 + B21) × B22 B24 Eq. 9 = − LN(B13/B12 − 0.0174/B2 × B5/60) + (4 − 3.5 × B13/B12) × (B3 − B4)/B4 B25 Eq. 10 = (B23+B32) × B5/B24/1000 B26 Eq. 11 = B24 × (B5/(B5 + 30.7)) B27 Eq. 12 = B13/(EXP(LN(B12) − B26/(B24/LN(B12/B13)))) B28 Eq. 13 = LN(B27 × B12/B13)/(B27 × LN(B12/B13)) B29 Eq. 14 = B25/B28 B30 Eq. 15 = B29/B4 B31 Eq. 16 = B12 × (1.075 − (0.38 × (1 − B13/B12)+0.059) × 1440/(B2 × 1440 − B5)) B32 Eq. 17 = B14 × B15/B31/1440 B33 Eq. 18 = B32 × 35/B29 B34 Eq. 19 = 0.1532 × B332− 2.225 × B33 + 7.9006 B35 Eq. 20 = 0.0221 × B332− 0.4979 × B33 + 2.24 B36 Eq. 21 = 0.0068 × B332− 0.2514 × B33 + 1.2979 B37 Eq. 22 = 0.1755 × B332− 2.7563 × B33 + 10.999 B38 Eq. 23 = 0.0776 × B332− 0.9091 × B33 + 3.157 B39 Eq. 24 = 0.0145 × B332− 0.2549 × B33 + 1.2496 The key formulae are written in bold. Table 2 Formulae to be copied into the associated cells in column B of sheet 1 (Figure 1) B16 Eq.1 = (B3 − B4) × 1000/B5 B17 Eq. 2 = 0.537 × B11 × (1+ 0.0549 × (B9 − 500)/300) B18 Eq. 3 = 0.894 × B6 + B7 B19 Eq. 4 = EXP(B17/B18 × (1 − B18/B9)) B20 Eq. 5 = B18 × (B19 − 1)/(B19 − B18/B9) B21 Eq. 6 = (B18 − B20)/B18 × (B7+ B8 + B16) B22 Eq. 7 = 0.894 × B6/B18 B23 Eq. 8 = (B20 + B21) × B22 B24 Eq. 9 = − LN(B13/B12 − 0.0174/B2 × B5/60) + (4 − 3.5 × B13/B12) × (B3 − B4)/B4 B25 Eq. 10 = (B23+B32) × B5/B24/1000 B26 Eq. 11 = B24 × (B5/(B5 + 30.7)) B27 Eq. 12 = B13/(EXP(LN(B12) − B26/(B24/LN(B12/B13)))) B28 Eq. 13 = LN(B27 × B12/B13)/(B27 × LN(B12/B13)) B29 Eq. 14 = B25/B28 B30 Eq. 15 = B29/B4 B31 Eq. 16 = B12 × (1.075 − (0.38 × (1 − B13/B12)+0.059) × 1440/(B2 × 1440 − B5)) B32 Eq. 17 = B14 × B15/B31/1440 B33 Eq. 18 = B32 × 35/B29 B34 Eq. 19 = 0.1532 × B332− 2.225 × B33 + 7.9006 B35 Eq. 20 = 0.0221 × B332− 0.4979 × B33 + 2.24 B36 Eq. 21 = 0.0068 × B332− 0.2514 × B33 + 1.2979 B37 Eq. 22 = 0.1755 × B332− 2.7563 × B33 + 10.999 B38 Eq. 23 = 0.0776 × B332− 0.9091 × B33 + 3.157 B39 Eq. 24 = 0.0145 × B332− 0.2549 × B33 + 1.2496 B16 Eq.1 = (B3 − B4) × 1000/B5 B17 Eq. 2 = 0.537 × B11 × (1+ 0.0549 × (B9 − 500)/300) B18 Eq. 3 = 0.894 × B6 + B7 B19 Eq. 4 = EXP(B17/B18 × (1 − B18/B9)) B20 Eq. 5 = B18 × (B19 − 1)/(B19 − B18/B9) B21 Eq. 6 = (B18 − B20)/B18 × (B7+ B8 + B16) B22 Eq. 7 = 0.894 × B6/B18 B23 Eq. 8 = (B20 + B21) × B22 B24 Eq. 9 = − LN(B13/B12 − 0.0174/B2 × B5/60) + (4 − 3.5 × B13/B12) × (B3 − B4)/B4 B25 Eq. 10 = (B23+B32) × B5/B24/1000 B26 Eq. 11 = B24 × (B5/(B5 + 30.7)) B27 Eq. 12 = B13/(EXP(LN(B12) − B26/(B24/LN(B12/B13)))) B28 Eq. 13 = LN(B27 × B12/B13)/(B27 × LN(B12/B13)) B29 Eq. 14 = B25/B28 B30 Eq. 15 = B29/B4 B31 Eq. 16 = B12 × (1.075 − (0.38 × (1 − B13/B12)+0.059) × 1440/(B2 × 1440 − B5)) B32 Eq. 17 = B14 × B15/B31/1440 B33 Eq. 18 = B32 × 35/B29 B34 Eq. 19 = 0.1532 × B332− 2.225 × B33 + 7.9006 B35 Eq. 20 = 0.0221 × B332− 0.4979 × B33 + 2.24 B36 Eq. 21 = 0.0068 × B332− 0.2514 × B33 + 1.2979 B37 Eq. 22 = 0.1755 × B332− 2.7563 × B33 + 10.999 B38 Eq. 23 = 0.0776 × B332− 0.9091 × B33 + 3.157 B39 Eq. 24 = 0.0145 × B332− 0.2549 × B33 + 1.2496 The key formulae are written in bold. Table 4 Formulae to be copied into the associated cells in column B of Sheet 2 (Figure 2) Cell Equations Spreadsheet formula B6 Eq. 25 = B4 × (B5 + 30.7)/B5 B7 Eq. 26 = EXP(− B6/1.18) B8 Eq. 27 = 1 − 0.44 × B6/(B5/60) B9 Eq. 28 = LN(B8/B7)/(B8 × LN(1/B7)) B10 Eq. 29 = B3 × B9 B11 Eq. 30 = B6 × B10/B5 × 1000 − B2 Cell Equations Spreadsheet formula B6 Eq. 25 = B4 × (B5 + 30.7)/B5 B7 Eq. 26 = EXP(− B6/1.18) B8 Eq. 27 = 1 − 0.44 × B6/(B5/60) B9 Eq. 28 = LN(B8/B7)/(B8 × LN(1/B7)) B10 Eq. 29 = B3 × B9 B11 Eq. 30 = B6 × B10/B5 × 1000 − B2 The key formulae are written in bold. Table 4 Formulae to be copied into the associated cells in column B of Sheet 2 (Figure 2) Cell Equations Spreadsheet formula B6 Eq. 25 = B4 × (B5 + 30.7)/B5 B7 Eq. 26 = EXP(− B6/1.18) B8 Eq. 27 = 1 − 0.44 × B6/(B5/60) B9 Eq. 28 = LN(B8/B7)/(B8 × LN(1/B7)) B10 Eq. 29 = B3 × B9 B11 Eq. 30 = B6 × B10/B5 × 1000 − B2 Cell Equations Spreadsheet formula B6 Eq. 25 = B4 × (B5 + 30.7)/B5 B7 Eq. 26 = EXP(− B6/1.18) B8 Eq. 27 = 1 − 0.44 × B6/(B5/60) B9 Eq. 28 = LN(B8/B7)/(B8 × LN(1/B7)) B10 Eq. 29 = B3 × B9 B11 Eq. 30 = B6 × B10/B5 × 1000 − B2 The key formulae are written in bold. FIGURE 5 View largeDownload slide Calculation of PCRn for thrice-weekly and twice-weekly HD schedules. The formulae introduced by Depner and Daugirdas [20] were typed on the cells B8B15, for the Patient 0, to be used as template with one column per patient. Of note, the equations described by Depner and Daugirdas [20] were based on spKt/V values. However, our calculations are based on eKt/V and Vdp values, in agreement with very recent data by Daugirdas [21]. In contrast to the Sheet 1, here one has to use only concentrations of serum urea nitrogen in mg/dL. FIGURE 5 View largeDownload slide Calculation of PCRn for thrice-weekly and twice-weekly HD schedules. The formulae introduced by Depner and Daugirdas [20] were typed on the cells B8B15, for the Patient 0, to be used as template with one column per patient. Of note, the equations described by Depner and Daugirdas [20] were based on spKt/V values. However, our calculations are based on eKt/V and Vdp values, in agreement with very recent data by Daugirdas [21]. In contrast to the Sheet 1, here one has to use only concentrations of serum urea nitrogen in mg/dL. The errors have been corrected online and in print. © The Author(s) 2018. Published by Oxford University Press on behalf of ERA-EDTA. All rights reserved. This article is published and distributed under the terms of the Oxford University Press, Standard Journals Publication Model (https://academic.oup.com/journals/pages/about_us/legal/notices)

Journal

Nephrology Dialysis TransplantationOxford University Press

Published: Apr 17, 2018

There are no references for this article.

You’re reading a free preview. Subscribe to read the entire article.


DeepDyve is your
personal research library

It’s your single place to instantly
discover and read the research
that matters to you.

Enjoy affordable access to
over 18 million articles from more than
15,000 peer-reviewed journals.

All for just $49/month

Explore the DeepDyve Library

Search

Query the DeepDyve database, plus search all of PubMed and Google Scholar seamlessly

Organize

Save any article or search result from DeepDyve, PubMed, and Google Scholar... all in one place.

Access

Get unlimited, online access to over 18 million full-text articles from more than 15,000 scientific journals.

Your journals are on DeepDyve

Read from thousands of the leading scholarly journals from SpringerNature, Elsevier, Wiley-Blackwell, Oxford University Press and more.

All the latest content is available, no embargo periods.

See the journals in your area

DeepDyve

Freelancer

DeepDyve

Pro

Price

FREE

$49/month
$360/year

Save searches from
Google Scholar,
PubMed

Create lists to
organize your research

Export lists, citations

Read DeepDyve articles

Abstract access only

Unlimited access to over
18 million full-text articles

Print

20 pages / month

PDF Discount

20% off