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 United States 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.

where

From the above definitions it follows that 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

where

The steady state solution is

This can be written as

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

where

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

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

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

[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:

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.

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):

[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:

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]

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. PMID 9719197. doi:10.1093/ndt/13.suppl_6.10.
  2. 1 2 Gotch FA, Sargent JA, Keen ML (August 2000). "Whither goest Kt/V?". Kidney Int. Suppl. 76: S3–18. PMID 10936795. doi:10.1046/j.1523-1755.2000.07602.x.
  3. Gotch FA, Sargent JA (September 1985). "A mechanistic analysis of the National Cooperative Dialysis Study (NCDS)". Kidney Int. 28 (3): 526–34. PMID 3934452. doi:10.1038/ki.1985.160.
  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. PMID 9719197. doi:10.1093/ndt/13.suppl_6.10.
  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. PMID 15043617. doi:10.1111/j.0894-0959.2004.17212.x.
  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. PMID 17164834. doi:10.1038/sj.ki.5002032.
  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. PMID 16480392. doi:10.1111/j.1525-1594.2006.00204.x.
  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. PMID 8943495. doi:10.1038/ki.1996.534.
  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. PMID 14694173. doi:10.1097/01.ASN.0000103871.20736.0C.
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