Standardized Kt/V

Standardized Kt/V, also std Kt/V, is a way of measuring (renal) dialysis adequacy. It was developed by Frank Gotch and is used in the USA to measure dialysis. Despite the name, it is quite different from Kt/V. In theory, both peritoneal dialysis and hemodialysis can be quantified with std Kt/V.

Derivation

Standardized Kt/V is motivated by the steady state solution of the mass transfer equation often used to approximate kidney function (equation 1), which is also used to define clearance.

V \frac{dC}{dt} = -K \cdot C + \dot{m} \qquad(1)

where

From the above definitions it follows that \frac{dC}{dt} is the first derivative of concentration with respect to time, i.e. the change in concentration with time.

Derivation equation 1 is described in the article clearance (medicine).

The solution of the above differential equation (equation 1) is

C = \frac{\dot{m}}{K} + \left(C_{o}-\frac{\dot{m}}{K}\right) e^{-\frac{K \cdot t}{V}} \qquad(2)

where

The steady state solution is

 C_{\infty} = \frac {\dot{m}}{K} \qquad(3a)

This can be written as

 K = \frac {\dot{m}}{C_{\infty}} \qquad(3b)

Equation 3b is the equation that defines clearance. It is the motivation for K' (the equivalent clearance):

 {K'}  = \frac {\dot{m}}{C_o} \qquad(4)

where

Equation 4 is normalized by the volume of distribution to form equation 5:

 \frac {K'}{V}  = \frac {\dot{m}}{C_o \cdot V} \qquad(5)

Equation 5 is multiplied by an arbitrary constant to form equation 6:

 \mbox{const} \cdot \frac {K'}{V}  = \mbox{const} \cdot \frac {\dot{m}}{C_o \cdot V} \qquad(6)

Equation 6 is then defined as standardized Kt/V (std Kt/V):

\mbox{std} \frac{K \cdot t}{V} \ \stackrel{\mathrm{def}}{=}\   \mbox{const} \cdot \frac {\dot{m}}{C_o \cdot V} \qquad(7)[1][2]

where

Interpretation of std Kt/V

Standardized Kt/V can be interpreted as a concentration normalized by the mass generation per unit volume of body water.

Equation 7 can be written in the following way:

\mbox{std} \frac{K \cdot t}{V} \ \stackrel{\mathrm{def}}{=}\mbox{ const} \cdot \frac {\dot{m}}{V} \frac{1}{C_o} \qquad(8)

If one takes the inverse of Equation 8 it can be observed that the inverse of std Kt/V is proportional to the concentration of urea (in the body) divided by the production of urea per time per unit volume of body water.

\left[ std \frac{K \cdot t}{V} \right]^{-1} \propto \frac{C_o}{\dot{m}/V} \qquad(9)

Comparison to Kt/V

Kt/V and standardized Kt/V are not the same. Kt/V is a ratio of the pre- and post-dialysis urea concentrations. Standardized Kt/V is an equivalent clearance defined by the initial urea concentration (compare equation 8 and equation 10).

Kt/V is defined as (see article on Kt/V for derivation):

 \frac{K \cdot t}{V} = \ln \frac{C_o}{C} \qquad(10)[3]

Since Kt/V and std Kt/V are defined differently, Kt/V and std Kt/V values cannot be compared.

Advantages of std Kt/V

Criticism/disadvantages of std Kt/V

Calculating stdKt/V from treatment Kt/V and number of sessions per week

The various ways of computing standardized Kt/V by Gotch,[5] Leypoldt,[6] and the FHN trial network [7] are all a bit different, as assumptions differ on equal spacing of treatments, use of a fixed or variable volume model, and whether or not urea rebound is taken into effect.[8] One equation, proposed by Leypoldt and modified by Depner that is cited in the KDOQI 2006 Hemodialysis Adequacy Guidelines and which is the basis for a web calculator for stdKt/V is as follows:

stdKt/V = \frac { \frac {10080 \cdot (1 - e^{-eKt/V})}{t} }{ \frac {1 - e^{-eKtV}}{spKt/V} + \frac{10080}{N \cdot t} - 1}

where stdKt/V is the standardized Kt/V
spKt/V is the single-pool Kt/V, computed as described in Kt/V section using a simplified equation or ideally, using urea modeling, and
eKt/V is the equilibrated Kt/V, computed from the single-pool Kt/V (spKt/V) and session length (t) using, for example, the Tattersall equation:[9]

ekt/V = spKt/V \cdot \frac {t}{t+C}

where t is session duration in minutes, and C is a time constant, which is specific for type of access and type solute being removed. For urea, C should be 35 minutes for arterial access and 22 min for a venous access.

The regular "rate equation" [10] also can be used to determine equilibrated Kt/V from the spKt/V, as long as session length is 120 min or longer.

Plot showing std Kt/V depending on regular Kt/V for different treatment regimens

Plot relating standardized Kt/V, Kt/V and treatment frequency per week.

One can create a plot to relate the three grouping (standardized Kt/V, Kt/V, treatment frequency per week), sufficient to define a dialysis schedule. The equations are strongly dependent on session length; the numbers will change substantially between two sessions given at the same schedule, but with different session lengths. For the present plot, a session length of 0.4 Kt/V units per hour was assumed, with a minimum dialysis session length of 2.0 hours.

References

  1. Gotch FA (1998). "The current place of urea kinetic modelling with respect to different dialysis modalities". Nephrol Dial Transplant. 13 Suppl 6 (90006): 10–4. doi:10.1093/ndt/13.suppl_6.10. PMID 9719197.
  2. 1 2 Gotch FA, Sargent JA, Keen ML (August 2000). "Whither goest Kt/V?". Kidney Int. Suppl. 76: S3–18. doi:10.1046/j.1523-1755.2000.07602.x. PMID 10936795.
  3. Gotch FA, Sargent JA (September 1985). "A mechanistic analysis of the National Cooperative Dialysis Study (NCDS)". Kidney Int. 28 (3): 526–34. doi:10.1038/ki.1985.160. PMID 3934452.
  4. Johnson WJ, Hagge WW, Wagoner RD, Dinapoli RP, Rosevear JW (January 1972). "Effects of urea loading in patients with far-advanced renal failure". Mayo Clinic Proc. 47 (1): 21–9. PMID 5008253.
  5. Gotch FA (1998). "The current place of urea kinetic modelling with respect to different dialysis modalities". Nephrol Dial Transplant. 13 Suppl 6 (90006): 10–4. doi:10.1093/ndt/13.suppl_6.10. PMID 9719197.
  6. Leypoldt JK, Jaber BL, Zimmerman DL (2004). "Predicting treatment dose for novel therapies using urea standard Kt/V". Seminars in Dialysis 17 (2): 142–5. doi:10.1111/j.0894-0959.2004.17212.x. PMID 15043617.
  7. Suri RS, Garg AX, Chertow GM, et al. (February 2007). "Frequent Hemodialysis Network (FHN) randomized trials: study design". Kidney Int. 71 (4): 349–59. doi:10.1038/sj.ki.5002032. PMID 17164834.
  8. Diaz-Buxo JA, Loredo JP (March 2006). "Standard Kt/V: comparison of calculation methods". Artificial Organs 30 (3): 178–85 Erratum in 30(6):490. doi:10.1111/j.1525-1594.2006.00204.x. PMID 16480392.
  9. Tattersall JE, DeTakats D, Chamney P, Greenwood RN, Farrington K (December 1996). "The post-hemodialysis rebound: predicting and quantifying its effect on Kt/V". Kidney Int. 50 (6): 2094–102. doi:10.1038/ki.1996.534. PMID 8943495.
  10. Daugirdas JT, Greene T, Depner TA, et al. (January 2004). "Factors that affect postdialysis rebound in serum urea concentration, including the rate of dialysis: results from the HEMO Study". J Am Soc Nephrol. 15 (1): 194–203. doi:10.1097/01.ASN.0000103871.20736.0C. PMID 14694173.

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