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  • Title: Protein malnutrition and decreased protein turnover in chronic renal allograft failure.
    Author: Baltzan MA, Shoker AS, Baltzan RB.
    Journal: Clin Nephrol; 1997 Feb; 47(2):112-6. PubMed ID: 9049459.
    Abstract:
    OBJECT: To define the longitudinal relationship of declining renal function to protein consumption and turnover in the failing renal allograft model of chronic renal failure. METHOD: The study group is our first eight consecutive cadaveric renal graft recipients who after attaining a normal creatinine clearance, then developed chronic renal failure. We analysed their urea and creatinine clearances (Cur, Ccr), serum urea (SU), urinary urea and creatinine (Ur, Ucr), serum albumin (SA), urinary protein (Upr), body weight (BW), and steroid dose. Steady state Uur is also dietary protein intake (DPI) and protein catabolic rate (PCR). Ucr measures body protein mass. Ucr/Uur measures the ratio of body protein mass to urea excretion. Mean follow-up 4.7 years, range 1.5-8.7 years. RESULTS: Mean changes: (1) Body weight (BW) rose from 56 to 65 and then fell to 61 kgms. (2) Cur fell 65 to 5 and Ccr 92 to 12 ml/min/70 kg. (3) Uur fell from 369 to 107 and Ucr from 16.8 to 9.5 mmols/day/70 kg. (4) Uur/Ucr indexed at 1:1 fell to 0.49. (5) SU rose from 8.8 to 34.9 mmol/1; SA fell from 36.1 to 31.0 gms/1; Upr rose from 1.4 to 2.3 gms/day. (6) Prednisone rose from 26 to 66 and then fell to 33 mgms/day. Correlations: (1) Cur and Uur(r = 0.99, p < 0.001). (2) Ccr and Uur (r = 0.99, p < 0.001). (3) Cur and Uur/Ucr (r = 0.88, p < 0.01) with a decelerating breakpoint at Cur 18 and Ccr 32 ml/min/70 kg (p < 0.01). (4) SU and Uur negatively (r = 0.90, p < 0.01. (5) Cur and SA albumin (r = 0.82, p < 0.05). (6) Cur and prednisone, Upr and SA do not correlate. CONCLUSIONS: In this model of chronic renal failure: (1) Renal function controls protein intake. (2) Body protein mass is relatively well preserved despite the decreased protein intake implying a decrease in the protein turnover rate and a consequent increase in body protein average age. (3) Protein malnutrition, protein ageing, and decreased protein turnover are likely pathophysiological reactions to chronic renal failure and may be part of the pathogenesis of chronic uremia.
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