Special Feature

Medical Risks in Living Kidney Donors: Absence of Proof Is
Not Proof of Absence

Elizabeth S. Ommen, Jonathan A. Winston, and Barbara Murphy
Mount Sinai Medical Center, Division of Nephrology, New York, New York

Living-kidney donation has become increasingly widespread, yet there has been little critical analysis of existing studies of
long-term medical outcomes in living donors. This review analyzes issues in study design that affect the quality of the
evidence and summarizes possible risk factors in living donors. Virtually all studies of long-term outcomes in donors are
retrospective, many with large losses to follow-up, and therefore are subject to selection bias. Most studies have small sample
sizes and are underpowered to detect clinically meaningful differences between donors and comparison groups. Many studies
compare donors with the general population, but donors are screened to be healthier than the general population and this may
not be a valid comparison group. Difficulties in measurement of BP and renal function may underestimate the impact of
donation on these outcomes. Several studies have identified possible risk factors for development of hypertension, protein-
uria, and ESRD, but potential vulnerability factors in donors have not been well explored and there is a paucity of data on
cardiovascular risk factors in donors. Prospective registration of living kidney donors and prospective studies of diverse
populations of donors are essential to protect living donors and preserve living-kidney donation.

Clin J Am Soc Nephrol 1: 885– 895, 2006. doi: 10.2215/CJN.00840306

I
n 1954, the first successful kidney transplantation was
performed using a kidney from a living donor: the iden-
tical twin of the recipient. Living kidney donation contin-

ued to be performed because of a good-faith belief that it would
do no harm to the donor. Enthusiasm for living donation
waned somewhat in the early 1980s with experimental reports
of hyperfiltration after uninephrectomy and fear that living
kidney donation would cause proteinuria, hypertension, and
eventual glomerulosclerosis. However, these data were not
borne out in human studies, and living kidney donation has
steadily increased in the past several years. The number of
living donors has more than doubled, from 3009 in 1994 to 6467
in 2003, and in 2001 surpassed the number of cadaveric donors
(1). In addition, data showing that living-unrelated transplants
have similar graft and patient survival to living-related trans-
plants (2) have increased the number of unrelated donors,
including emotionally unrelated donors. Emotionally unrelated
donors have increased from 2.5% of all living donors in 1994 to
21.4% in 2004 (1).

All involved in the area of transplantation acknowledge the
great contribution of living donors, and there are many safe-
guards in place to protect donors. However, medical exclusion
criteria are variable from center to center, reflecting the uncer-
tainty of the importance of these criteria on donor outcomes (3).
In the past few years, there has been a trend in some centers to
expand the eligible donor pool beyond traditional limits, mo-

tivated by and explained as a response to the increased demand
for kidneys (4 – 8). Short-term studies have found no data con-
traindicating these policies, and indeed there are few specific
data for many of the existing exclusion criteria for donation.
However, evidence-based policies must be based on appropri-
ate and valid studies. There has been little critical analysis of
existing studies of long-term medical outcomes in living kidney
donors and little examination of whether these studies meet
current methodologic, epidemiologic, and statistical standards.
In this review, we analyze the existing data in the context of five
major issues in study design that affect the quality of the
evidence—retrospective studies, power and sample size, choice
of appropriate controls, inclusion of racial and ethnic minori-
ties, and measurement limitations—summarize possible risk
factors in living donors, and make recommendations for future
directions.

Retrospective Nature of Existing Studies
Virtually all studies that report medical outcomes of living

kidney donors at �1 yr from donation are retrospective. Al-
though practical for evaluation of long-term outcomes, retro-
spective studies are vulnerable to certain methodologic pitfalls
and biases that may limit their interpretability. Most important
is the potential for selection bias, which may alter findings if
there is a difference between included and nonincluded donors
either as a result of nonparticipation or because the study
investigators are unable to locate the subject. In studies that
follow living kidney donors, donors in good health may be
more likely to participate because of greater survival or greater
ability to meet the requirements of participation. Selection bias
is of greatest concern when the percentage of eligible subjects
who are included is small. Table 1 illustrates the low inclusion

Published online ahead of print. Publication date available at www.cjasn.org.

Address correspondence to: Dr. Elizabeth S. Ommen, Mount Sinai Medical
Center, Division of Nephrology, 1 Gustave Levy Place, Box 1243, New York, NY
10029. Phone: 212-241-3549; Fax: 212-987-0389; E-mail: elizabeth.ommen@
mssm.edu

Copyright © 2006 by the American Society of Nephrology ISSN: 1555-9041/104-0885



Table 1. Studies of living kidney donor outcomesa

Author, Year Years of Follow-Up, Mean(Range)
Postnephrectomy Findings versus Comparison (Statistical

Significance) N
b Participation

Rate (%)b

Bertolatus et al., 1985 (50) 1.2 (0.1 to 3) SBP: 130 versus 118 predonation (P � 0.05)c
DBP: 87 versus 76 predonation (P � 0.05)c
Urinary albumin excretion (24-h urine collection): 9.9 versus

6.3 mg predonation (NS)
Urinary protein excretion (24-h urine collection): 64 versus

78 mg predonation (NS)

21 N/A

Siebels et al., 2003 (83) 3 (0.04 to 5) Serum creatinine: 1.2 versus 1.2 mg/dl 1 yr postdonation
(NS)

Hypertension (not defined): 7 versus 5% predonation (N/A)
Proteinuria (positive urine dipstick): 6 versus 0%

predonation (N/A)

100 63

Rizvi et al., 2005 (47) 3 (0.5 to 18) CrCl (24-h urine collection): 87 versus 101 mg predonation
(P � 0.0001)c

Serum creatinine: 1.0 versus 0.8 mg/dl predonation (P �
0.0001)c

Hypertension (�140/90): 10 versus 0% predonation (N/A)
Proteinuria (�150 mg/24 h): 24 versus 0% predonation

(N/A)

736 57

Dunn et al., 1986 (13) 4.4 (0.5 to 15) Serum creatinine: 1.18 versus 1.01 mg/dl predonation (P �
0.001)c

180 57

CrCl: 85.2 versus 128.2 ml/min predonation (P � 0.001)c 98 31
Hypertension (�150/90 by questionnaire): 14.4 versus 0%

predonation (N/A)
250 80

Proteinuria (positive urine dipstick): 4 versus 0%
predonation (N/A)

137 44

Serum creatinine: 1.16 versus 1.02 mg/dl in age/gender-
matched potential donors (P � 0.001)c

CrCl (24-h urine collection): 87.7 versus 131.6 ml/min in
age/gender-matched potential donors (P � 0.001)c

SBP: 122 versus 123 in age/gender-matched potential
donors (P � 0.50)

DBP: 77 versus 78 in age/gender-matched potential donors
(P � 0.63)

71 23

Tapson et al., 1984 (64) Short-term:
4.7 (1 to 10)

Serum creatinine: 104.0 versus 88.4 �mol/L predonation
(P � 0.001)c

CrCl (24-h urine collection): 78.3 versus 105.1 ml/min
predonation (P � 0.001)c

SBP: 133 versus 128 predonation (P � 0.05)c
DBP: 84 versus 78 predonation (P � 0.01)c
Hypertension (not defined): 13 versus 0% predonation

(N/A)
Proteinuria (not defined, based on 24-h urine collection):

3 versus 0% predonation (NS)

38 N/A

Long-term:
13.5 (10 to 21)

Serum creatinine: 98.6 versus 87.2 �mol/L predonation
(P � 0.01)c

Cr l (24-h urine collection): 83.3 versus 101.4 ml/min
predonation (P � 0.01)c

SBP: 144 versus 130 predonation (P � 0.01)c
DBP: 90 versus 80 predonation (P � 0.01)c
Hypertension (not defined): 38 versus 0% predonation (P �

0.05)c
Proteinuria (not defined, based on 24-h urine collection):

0 versus 0% predonation (NS)

37 N/A

Miller et al., 1985 (18) 6 Hypertension (�160/90 or on antihypertensives): 31 versus
0% predonation (N/A)

29 14

Hypertension (�160/90 or on antihypertensives): 40 versus
13% in race/age/gender-matched controls (P � 0.11)

15 7

Serum creatinine: 1.2 versus 1.0 mg/dl predonation (P �
0.001)c; 1.19 versus 1.05 in race/age/gender-matched
controls (P � 0.001)c

45 22

Borchardt et al., 1996 (21) 6.4 (0.7 to 24) Hypertension (SBP �140 or on antihypertensives): 23 versus
42% in age-matched general Austrian population (N/A)

22 19

Chavers et al., 1985 (10) 7 (1 to 22) Urinary albumin excretion (24-h urine collection): 6 versus
7.7 mg in potential donors (NS)

129 80

Fehrman-Ekholm and
Thiel, 2005 (84)

7 Hypertension (DBP � 90): 34 versus 13% predonation
(N/A)

Albuminuria (�5 mg albumin/mmol creatinine): 9 versus
3% predonation (N/A)

91 70

886 Clinical Journal of the American Society of Nephrology Clin J Am Soc Nephrol 1: 885– 895, 2006



Table 1. Continued

Author, Year Years of Follow-Up,Mean (Range)
Postnephrectomy Findings versus Comparison (Statistical

Significance) N
b Participation

Rate (%)b

Wiesel et al., 1997 (42) 8 Serum creatinine: 1.3 versus 1.0 mg/dl predonation (N/A)
Hypertension (not defined): 27 versus 0% predonation (N/A)
Proteinuria (not defined): 19 versus 0% predonation (N/A)

67 57

Toronyi et al., 1998 (63) 8.9 Hypertension (not defined): 17 versus 0% predonation (N/A) 30 38

Bahous et al., 2005 (15) 9.3 (4 to 18) CrCl (calculated by Cockroft-Gault equation): 86.2 versus 107.6
ml/min per 1.73 m2 predonation (P � 0.0001)c

SBP: 130 versus 114 predonation (P � 0.0001)c
DBP: 82 versus 69 predonation (P � 0.0001)c
Hypertension (140/90): 18.8 versus 0% predonation (P � 0.0001)c

101 41

Hakim et al., 1984 (11) �10 Urinary protein excretion (24-h urine collection): 188 versus
�50 mg in age/gender-matched potential donors (P �
0.01)c; men: 212 versus 63 mg in outpatient controls (P �
0.01)c; women: no difference versus outpatient controls,
means not given

52 87

Hypertension (DBP �90): Men: 60 versus 18% predonation (P �
0.003)c versus 28% in age/gender-matched potential donors (P �
0.02)c versus 17% in normal controls (N/A); women: 30 versus 10%
predonation (NS) versus 14% in age/gender-matched potential
donors (NS) versus 20% in normal controls (NS)

51 87

Torres et al., 1987 (26) �10 Hypertension (combined “borderline” �140/90 and “definite”
�160/95): 35 versus 26% predonation (N/A)

90 63

Talseth et al., 1986 (12) 11 (10 to 12) CrCl (24-h urine collection): 87 versus 108 ml/min per 1.73 m2
predonation (N/A)

SBP: 140 versus 132 predonation (P � 0.003)c
DBP: 90 versus 82 predonation (P � 0.001)c
Proteinuria (urine dipstick positive for albumin): 13 versus 0%

predonation (N/A)

68 92

SBP: 140 versus 132 in controls (NS)
DBP: 90 versus 85 in controls (P � 0.05)c
Urinary protein excretion (24-h urine): 105 versus 94 mg in

controls (NS)
Urinary albumin excretion (24-h urine): 7.7 versus 4.7 mg in

controls (P � 0.002)c
Albumin excretion rate: 4 versus 3.3 �g/min in controls (P � 0.002)c

32 43

Gossman et al., 2005 (9) 11.7 (1 to 28) Serum creatinine: 85.7 versus 72.5 mmol/L predonation (P � 0.001)c
CrCl (24 h urine): 99 versus 119 ml/min per 1.73 m2 predonationc
Estimated GFR (modified MDRD equation): 71 versus 92 ml/min

per 1.73 m2 predonation
SBP: 134 versus 125 mmHg predonation (P � 0.001)c
DBP: 81 versus 79 mmHg predonation (NS)
Hypertension (�140/90 or on antihypertensives): 30 versus 7%

predonation

135 93

Proteinuria (�150 mg on 24-h urine collection): 56 versus 0%
predonationc

Albuminuria (�50 mg/L on 24-h urine collection): 10 versus
0% predonationc

115 79

Fehrman-Ekholm et al.,
2001 (14)

12 (2 to 33) Hypertension (DBP �90 or on antihypertensives): 38%, similar to
age/gender-matched general population (NS)

348 87

Mild proteinuria (�1.0 g/L on urine dipstick): 9 versus 0%
predonation (N/A)

Significant proteinuria (�1.0 g/L on urine dipstick): 3 versus
0% predonation (N/A)

331 82

Anderson et al., 1985 (23) 12.6 Hypertension (�160/95 or on antihypertensives): 19 versus 21 to
27% in general Minnesota population (NS)

89 61

Watnick et al., 1988 (24) (9 to 18) Serum creatinine: 1.06 versus 0.86 mg/dl in race/age/gender-
matched controls (P � 0.025)c

CrCl (24 h urine): 85 versus 109 ml/min per 1.73 m2 in race/
age/gender-matched controls (P � 0.025)c

Inulin Cl: 66 versus 78 ml/min per 1.73 m2 in race/age/
gender-matched controls (P � 0.025)c

Hypertension (�140/90 or on antihypertensives): 62 versus 42%
in adults �50 yr old in Connecticut (P � 0.05)c versus 32% in
race/age/gender-matched controls (P � 0.05)c

Urinary albumin excretion (24-h urine): 61 versus 4 mg in race/
age/gender-matched controls (P � 0.05)c

29 71

Clin J Am Soc Nephrol 1: 885– 895, 2006 Medical Risks of Living-Kidney Donation 887



rate of most studies: the majority have a participation rate of
�80%, and seven have lower than a 50% participation rate
(9 –21). The results of these studies must be accepted with
caution.

Power and Statistical Significance
Studies that fail to demonstrate statistical significance may

do so because they are underpowered to reveal a true differ-
ence between groups. As can be seen in Table 1, the majority of

Table 1. Continued

Author, Year Years of Follow-Up,Mean (Range)
Postnephrectomy Findings versus Comparison

(Statistical Significance) N
b Participation

Rate (%)b

Williams et al., 1986 (25) 12.6 (10 to 18) Serum creatinine: 20% higher versus siblings, age-
adjustedc

CrCl: 20% lower versus siblings, age-adjustedc
Hypertension (�140/90 or on antihypertensives):

47 versus 35% siblings (P � 0.41); men: 42 versus
42% in age/race/gender-matched control group
(P � 0.50); women: 50 versus 31% in age/race/
gender-matched control group (P � 0.16)

38 68

Urinary protein excretion (24-h urine collection): mean
increase of 100 mg versus predonationc

19 34

Urinary protein excretion (24-h urine collection):
men: 190 versus 40 mg in siblings (P � 0.001)c;
women: 80 versus 20 mg in siblings (P � 0.08)

38 68

Vincenti et al., 1983 (20) 16 (15 to 19) BP: 122/77 versus 124/78 predonation (NS)
Urinary protein excretion (24-h urine collection):

141 versus 74 mg in age/gender-matched controls
(P � 0.005)c

20 31

Iglesias-Marquez et al.,
2001 (41)

�20 Serum creatinine: 1.01 versus 0.87 mg predonation
(P � 0.10)

CrCl (24-h urine): 98.2 versus 125.3 ml/min
predonation (P � 0.10)

Prevalence of hypertension (not defined): 25 versus
22% in general population (N/A)

MAP: 104.7 versus 89.8 predonation (P � 0.003)c
Proteinuria by urinalysis: 5 versus 0% predonation

(N/A)

20 N/A

Saran et al., 1997 (49) 20 (12.5 to 31) Prevalence of hypertension (�140/90 or on
antihypertensives): 74.5 versus 51% in age/gender-
stratified population controls (P � 0.001)c

Albumin excretion rate �20 �g/min (timed overnight
collection): 34 versus 0% in age/gender-stratified
population controls (P � 0.0003)c

Albumin excretion rate: median increase of 2.7 mg
versus early postdonation (P � 0.001)c

47 62

Najarian et al., 1992 (19) 24 (21 to 29) Serum creatinine: 1.1 versus 1.1 mg/dl in siblings (NS)
CrCl (24 h urine): 82 versus 89 ml/min in siblings (NS)

57 42

Prevalence of antihypertensive medication (by
questionnaire): 32 versus 44% in siblings (NS)

SBP of those not on antihypertensives: 130 versus 116
predonation (P � 0.01)c versus 122 in siblings (NS)

DBP of those not on antihypertensives: 79 versus 74
predonation (NS) versus 79 in siblings (NS)

63 47

Proteinuria (�150 mg on 24-h collection): 23 versus
22% in siblings (NS)

Abnormal albumin excretion (not defined): 6 versus
7% in siblings (NS)

52 38

Goldfarb et al., 2001 (17) 25 (�20) Serum creatinine: 1.2 versus 1.0 mg/dl predonation
(P � 0.001)c

CrCl (24-h urine): 73 versus 102 mg/ml per 1.73 m2
predonation (P � 0.001)c

Prevalence of hypertension (�140/90 or on
antihypertensives): 48 versus 0% predonation
(P � 0.001)c

Urinary protein excretion (24-h urine collection):
230 versus 80 mg predonation (P � 0.05)

70 39

aCrCl, creatinine clearance; DBP, diastolic BP; MAP, mean arterial pressure; MDRD, Modification of Diet in Renal Disease;
N/A, data not available; SBP, systolic BP.

bNumbers may vary for different comparisons within a study.
cSignificant at P � 0.05.

888 Clinical Journal of the American Society of Nephrology Clin J Am Soc Nephrol 1: 885– 895, 2006



studies of long-term outcomes of living donors have relatively
small sample sizes; therefore, studies with “negative” results
may simply be underpowered.

One way to evaluate the adequacy of the sample size in a
study is to determine the minimum detectable difference,
which is the smallest difference in outcomes between two
groups that could be statistically significant given the magni-
tude of the outcome and the number of subjects in the study. If
the minimum detectable difference is larger than what would
constitute a clinically important difference in outcomes, then
the study is underpowered to detect clinically important dif-
ferences.

Table 2 applies this approach to those living donor cohort
studies with negative results. Only studies that compared do-
nors with a control group were included, to eliminate the
confounding effect of increasing BP and proteinuria with age.
(Outcomes that evaluated kidney function were not included,
because it is expected that function will be lower in donors than
nondonors.) Minimal detectable differences were calculated
using the Power Calculator offered on the UCLA Depart-
ment of Statistics’ web site (http://calculators.stat.ucla.edu/
powercalc/). By convention, � was set to 0.05 and power was
set to 80%. As is shown in Table 2, with only two exceptions,
the negative studies evaluated had minimum detectable differ-
ences that were larger than the differences that were seen
between donors and control subjects. This suggests insufficient
power in these studies. More striking, the minimum detectable

difference in most studies is far greater than what would be
deemed clinically important.

Underpowered studies may provide invalid information to
physicians and potential donors and undercut the need for
future study. It is not possible, of course, to know whether the
negative studies in Table 2 would find differences in BP or
proteinuria outcomes if a larger sample of donors were in-
cluded. The purpose of this analysis is simply to demonstrate
that many of the “negative” studies of living donor outcomes
do not rule out a true and meaningful effect of living donation
on these outcomes.

Comparisons and Controls
Studies that measure outcomes without providing a compar-

ison value for context may contribute to the body of knowledge
on living donor outcomes, but they cannot be used to evaluate
changes or associations in a meaningful way. The majority of
studies in living donors compare postdonation to predonation
values. Those that compare renal function postdonation with
predonation provide little information, given the expected de-
crease in function with donation. Studies that compare early
and late postdonation function also may be limited because of
an expected age-related decline in GFR (22). Similarly, the
prevalence of hypertension increases with age, making com-
parisons over time less informative. A separate control group
may provide a more meaningful comparison, but to be valid, a

Table 2. Minimum detectable differencea

Study Finding of No Difference Minimum DetectableDifference

Dunn et al., 1986 (13) SBP: 122 versus 123 in age/gender-matched potential donors 7 mmHg
DBP: 77 versus 78 in age/gender-matched potential donors 5 mmHg

Miller et al., 1985 (18) Prevalence of hypertension (�160/90): 40 versus 13% in race/
gender/age-matched controls

54%

Chavers, 1985 (10) 24-h urinary albumin excretion: 6 versus 7.7 mg in potential
donor controls

3.5 mg

Hakim et al., 1984 (11) Prevalence of hypertension (DBP �90):
Women: 30 versus 20% in outpatient controls 44%
Women: 30 versus 14% in matched potential donors 43%

Anderson et al., 1985 (23) Prevalence of hypertension (>160/95 or on medication): 19 versus
21 to 27% in general Minnesota population

12 to 13%

Williams et al., 1986 (25) Prevalence of hypertension (�140/90 or on medication): 47 versus
35% in siblings

34%

47 versus 34% in age/race/gender-matched general population 34%
Men: 42 versus 42% in age/race/gender-matched control group 57%
Women: 50 versus 31% in age/race/gender-matched control group 42%

Najarian, 1992 (19) Prevalence of antihypertensive medication: 32 versus 44% in
siblings

26%

SBP of those not on antihypertensives: 130 versus 122 in siblings 10 mmHg
DBP of those not on antihypertensives: 79 versus 79 in siblings 4 mmHg
Proteinuria (�150 mg on 24-h collection): 23 versus 22% in siblings 28%
Abnormal albumin excretion (not defined): 6 versus 7% in siblings 23%

aThe smallest difference in outcomes between donors and comparison group that could be statistically significant in studies
with negative findings. Studies whose minimum detectable difference is within the difference found are in bold.

Clin J Am Soc Nephrol 1: 885– 895, 2006 Medical Risks of Living-Kidney Donation 889



control group should be as similar as possible to the donor
group in other characteristics that may influence outcomes.
Unfortunately, several studies compare donor outcomes with
those in the general population (9,21,23,24); because donors are
screened carefully, they are expected to be healthier than the
general population and therefore have a lower risk for devel-
oping other health problems. Studies that find outcomes in
living donors to be similar to or even better than those in the
general population, then, cannot be used to show that living
donation does not increase medical risk among donors.

The most valid control group in studies of living donors
would be composed of siblings or potential donors who are
excluded for nonmedical reasons. Either of these groups would
be expected to have age, race, and family history of renal
disease similar to that in donors. Five studies have compared
donors with siblings or potential kidney donors, and these have
shown conflicting results for the impact of donation on BP,
renal function, and proteinuria outcomes (10,11,13,19,25). The
sum of the results of these five studies can be interpreted as
showing that there is likely an increase in hypertension and
proteinuria in male donors and, not unexpected, a loss of renal
function of at least 20% in both genders. However, given small
sample sizes and low participation rates, it cannot be deter-
mined from these studies whether similar hypertension and
proteinuria risks apply to women as well or more subtle dif-
ferences in BP exist in donors.

Race and Ethnicity
There is a paucity of data regarding long-term outcomes in

living donors from minority populations. In 2003, 14.3% of
living donors were black and 12.6% were Hispanic (1), yet few
studies that evaluate medical outcomes of donors describe race
or ethnicity of the study participants, and US studies that do
reveal that their donors are almost exclusively white (8,24 –26).
There are clear racial and ethnic disparities in the development,
progression, and control of disease, including those that may be
especially relevant to living kidney donors.

The incidence rate of ESRD in black individuals is four times
higher than in white individuals (27) and in Hispanic individ-
uals is 1.5 times higher than in non-Hispanic individuals (28).
The prevalence of hypertension in black individuals is 41%
compared with 28% in white individuals (29), and black indi-
viduals with hypertension show a six-fold greater progression
to ESRD than hypertensive white individuals (30). Although
hypertension in Hispanic individuals is lower than that in other
groups, the prevalence may be increasing (31), and Hispanic
individuals have the lowest rates of controlled hypertension
(32). In women, who constitute the majority of living donors,
the prevalence of overweight and obesity is �50% in black and
Hispanic women, compared with 34% in white women (33);
obesity increases the risks for proteinuria, hypertension, car-
diovascular (CV) events, and ESRD (34). Black individuals in
general have a 50% higher rate of abnormal microalbumin
excretion than white individuals (35) and are particularly prone
to certain renal diseases, including focal segmental glomerulo-
sclerosis and HIV nephropathy, a variant of focal segmental
glomerulosclerosis that affects black individuals almost exclu-

sively. There also are several reports of familial clustering of
renal disease in black individuals with a family history of ESRD
as a result of diabetes, hypertension, HIV, and systemic lupus
erythematous (27,36 –38).

It is possible, then, that living donors, especially living-
related donors, from minority populations form a group at
increased risk for developing hypertension or renal disease.
Given the limited inclusion of minorities in studies of living
donors and given the increased rates of renal disease in these
populations in general, basing risk assessments in black and
Hispanic potential donors on existing studies may be mis-
leading.

Limitations in Measurement
Measurement difficulties limit our ability to interpret studies

of BP outcomes. In several studies, measurement was not stan-
dardized, or results were determined by patient self-report
(13,17,19,24,39,40), thereby increasing chances of measurement
errors and decreasing the chance of detecting a true difference
in BP or hypertension in donors. The definition of hypertension
has changed over time, and early studies (11,12,14,18,23) used
cutoff points for hypertension that would not be considered
acceptable today, whereas other studies (14,41,42) provided no
definition of hypertension. Further complicating these studies
is a prevalence of white-coat hypertension of 20 to 43% in
potential kidney donors (4,43,44). BP that is measured during
donor evaluation, which may be a time of considerable stress,
may not reflect a donor’s true BP, and BP that is measured long
after donation may underestimate changes in true BP. This may
explain the finding in some studies that donors who were
hypertensive at the time of donation were normotensive on
follow-up (11,45).

The majority of transplant centers use creatinine clearance as
determined by 24-h urine collection to estimate GFR. However,
24-h urine samples are vulnerable to under- or overcollection,
and prediction equations using body weight to determine the
adequacy of a collection may not be useful (46). Furthermore,
because of tubular secretion of creatinine, both serum creati-
nine and creatinine clearance will overestimate GFR to a greater
degree as renal function declines. This may lead to underesti-
mation of decreases in renal function and the degree of renal
dysfunction after donation in studies that rely on these mea-
surements, as the majority do (11,12,17–20,23,25,40,45,47). This
is demonstrated in a study by Watnick et al. (24), in which
postdonation creatinine clearance was only modestly decreased
at 85 ml/min per 1.73 m2, whereas inulin clearance was 44%
lower at 66 ml/min per 1.73 m2.

Summary of Risk Factors
Several risk factors for bad outcomes have been identified in

the existing literature and deserve special emphasis

Hypertension
BP does tend to increase after donation, and pretransplanta-

tion BP may be a determining factor. Despite the possibility of
white-coat effect in potential donors, higher values of BP before
donation have been shown to be associated with a greater rate

890 Clinical Journal of the American Society of Nephrology Clin J Am Soc Nephrol 1: 885– 895, 2006



of hypertension after donation, even when BP is within normal
limits (12,23,47). In one study, donors who were hypertensive
at follow-up had a predonation mean BP of 133/82 mmHg, as
compared with 123/79 mmHg in those who were normotensive
at follow-up (12,23,47). There are few studies of the effects of
donation on established hypertensive donors, but the few data
that do exist suggest that it is associated with worse BP control
(8,10 –12,26,48).

Renal Failure
Studies that have compared early with late postdonation

function have found no difference in mean function in the
sample of donors (49,50). In fact, a study by Saran et al. (49),
which compared 51Cr EDTA early postdonation and then 10 yr
later, found that the mean GFR had actually improved slightly
at a follow-up of 20 yr. However, there is evidence that some
donors may be at risk for renal failure. Studies by Talseth et al.
(12) and Hakim et al. (11) identified a small group of donors, 9
and 12% respectively, whose renal function declined by �50%
at least 10 yr after donation. In a study by Ramcharan and
Matas (40), 2% of donors who responded to a questionnaire had
advanced renal disease or had required kidney transplantation.
Ellison et al. (51) used the Organ Procurement and Transplan-
tation Network database to identify former living donors who
had received or were awaiting kidney transplant. This analysis
revealed an incidence of ESRD of 0.04% as compared with a
0.03% incidence in the general US population (52); this study
likely underestimates the true rate of renal failure in donors
because it does not include donors with less advanced renal
failure or those who had ESRD and were not listed for trans-
plant. These studies suggest an increased risk for important
renal dysfunction after donation in certain donors.

Particular donor characteristics that confer vulnerability to
renal failure in the general population have been examined in a
few studies of living donors. Talseth et al. (12) found that the
degree of renal decline after donation was inversely and inde-
pendently associated with predonation systolic and diastolic
BP, suggesting that higher levels of BP either interfere with
compensatory hyperfiltration or promote decline in renal func-
tion. However, a recent study that evaluated renal function
after donation in donors with established hypertension found
no difference in serum creatinine compared with normotensive
donors at a mean follow-up of 11 mo (8), although most hy-
pertensive donors were taking an angiotensin receptor blocker,
which may have offered renal protection. Najarian et al. (19)
reported that donors with “below normal” (not defined) creat-
inine clearance were more likely to have siblings with “below
normal” clearance than were donors with “normal” creatinine
clearance, indicating a familial propensity to renal disease in
these donors.

Proteinuria
Most studies that compare urinary protein with values pre-

donation or in a control group reveal an increased amount of
urinary protein or increased frequency of abnormal excretion
(9,11,12,17,20,24,25,49), although the amount of urinary protein
usually is small. However, studies use varying definitions of

“abnormal,” and rates vary widely among studies (9 –12,16,17,
19 –21,24,25,42,45,49,50,53). One recent study that included 18
donors with established hypertension found that none had
developed proteinuria at a median follow-up of 30 mo (48).
However, studies with at least 7 yr of follow-up have shown
greater levels of protein excretion in donors with higher BP or
established hypertension (9 –11). Four studies of donors, in-
cluding a meta-analysis by Kasiske et al. (53), have shown a
greater rate of proteinuria in men as compared with women
(11,25,49,53).

CV Events
Living kidney donors live longer than the general popula-

tion, as shown in an often-cited study by Fehrman-Ekholm et al.
(39). Although, as the authors pointed out, this is because living
donors are healthier than the general population, the study
does demonstrate that donor nephrectomy does not increase
mortality beyond that in the general population. Nonetheless,
uninephrectomy may increase certain CV risk factors and there-
fore raise the risk for CV events in otherwise healthy living
donors. This topic has not been studied specifically and has not
been well explored in the literature on living kidney donation.

Most living donors are left with creatinine clearances of
between 70 and 90 ml/min after donation, whereas older do-
nors or those with other CV risk factors may have a GFR of 60
ml/min or less (4,8,54,55). Given this decreased renal function
in conjunction with the presence of a solitary kidney, many
donors would be considered to meet criteria for chronic kidney
disease (CKD). Several large studies have established that mor-
tality and CV risk rise with even mild CKD and increase in a
graded manner as renal function decreases (56 –59). In the
Second National Health and Nutrition Examination Survey,
people with an estimated GFR of �70 ml/min had a 64%
greater risk for CV death than those with a GFR of �90 ml/min
(56).

Risk for CV events increases with increasing BP, even when
BP is below hypertensive levels (60 – 62). In a study of the
Framingham cohort, women and men with high-normal BP
(130 to 139/85 to 89) had a 60 and 150% greater rate, respec-
tively, of CV events than those with BP �120/80 (61). Several
studies have found that BP not only increases after donation
but also increases with time after donation; in several of these
studies, increases in BP were independent of age (13,14,
47,63,64).

Most living donor studies have shown a small increase in
urinary protein or albumin. Even low levels of proteinuria and
microalbuminuria have been shown to be important risk factors
for CV events, independent of BP, diabetes, or other cardiac risk
factors (65– 68). In one population study, an increase in the risk
for death was seen beginning at an albumin-to-creatinine ratio
of 6.7 �g/mg (68).

Abnormal serum lipid profile is a long-established marker of
CV risk. Elevations in LDL and triglycerides (TG) and declines
in HDL each increase CV risk by approximately two-fold in
healthy adults (69). LDL and TG typically increase and HDL
typically decreases as renal function declines, although it is
unclear whether there is a threshold GFR below which the lipid

Clin J Am Soc Nephrol 1: 885– 895, 2006 Medical Risks of Living-Kidney Donation 891



profile significantly worsens (70). Animal models may suggest
an increase in lipids as a result of nephrectomy itself: apoli-
poprotein E– deficient hyperlipidemic mice that underwent
uninephrectomy were found to have significantly increased
total cholesterol despite similar serum creatinines (71). Al-
though most transplant centers include serum lipid profile in
their donor evaluation, there has been little study of risks that
are associated with abnormal lipid levels in donors.

Obesity is an important modifiable risk factor for CV events
and death (72–74). As the prevalence of obesity in the US
population continues to increase (75) and more transplant cen-
ters accept obese living donors, the number of donors who face
this health risk has increased. Individual risk for developing
obesity increases with time (76), and this holds true for living
donors as well (15,23,26,77). In a study that followed donors for
at least 10 yr, there was a significant weight gain, and the mean
weight at follow-up was in the obese range. The greatest weight
gain was seen in donors who were already overweight at the
time of donation (26). Although consensus statements encour-
age weight loss and healthy lifestyle education in obese donors
(78), there is no evidence that this lowers obesity risks in living
donors. In one prospective study of living donors, there was no
change in body mas index among overweight, obese, or ex-
tremely obese donors at 1 yr after donation (5).

The effects of donor nephrectomy may impart an increase in
relative risk for CV events in living donors. Although this may
translate into slight increases in absolute risk in most donors, it
nonetheless necessitates careful follow-up of living donors for
identification of the development of risk factors and timely
initiation of risk factor modification.

Discussion
The Council on Ethical and Judicial Affairs of the American

Medical Association issued a report on the transplantation of
organs from living donors that stated, “The risks to a kidney
donor . . . are fairly well understood, have a relatively low in-
cidence, and are considered minimal beyond the regular risks
of surgery” (79). This sense of understanding, at first glance,
may seem justifiable given the number of studies on living
donor outcomes and the long duration of follow-up of several
of these studies. When we examine many studies closely, how-
ever, we find limitations that weaken our confidence. Early in
the history of living donation, it was necessary and appropriate
to obtain fairly quickly data that would provide us with pre-
liminary reassurance that donation posed no great harm. Ret-
rospective study designs that included small numbers of sub-
jects and comparisons with the general population were
reasonable approaches at that time and have advanced the
field. We should be reassured that there have been no consis-
tent increases in BP or large decreases in GFR. However, we
have not considered adequately small changes in GFR, protein-
uria, and hypertension and the evidence that risk in certain
donors may be enhanced by nephrectomy. We also must con-
sider the potential long-term CV risk that is associated with
such changes. Moreover, we have not evaluated these issues in
donors from minority populations. The history of clinical re-
search has taught us that extrapolation of results in white

individuals to other racial and ethnic groups may underesti-
mate the risks in a more diverse group of donors.

Moving forward, it no longer seems sufficient to base prac-
tices and consensus statements on the existing studies and the
existing methods. It is time for the transplant community to call
for prospective registration of living kidney donors and pro-
spective studies of diverse populations of donors that may be
compared with groups with similar compositions of race, eth-
nicity, and family history.

The United Network for Organ Sharing maintains a database
on outcomes of living kidney donors. However, an analysis of
the completeness of these data found that only 60% of 6-mo
follow-up forms were returned to the United Network for
Organ Sharing from transplant centers, and those forms that
were returned revealed that 36% of donors already were lost to
follow-up (51). It is understandably difficult to maintain a
relationship with donors who wish to think of themselves as
healthy individuals. However, the South-Eastern Organ Pro-
curement Foundation reported on efforts to follow living do-
nors with questionnaires and found an overall response rate of
90% (80). The authors attributed the maintenance of a high
response rate to the fact that donors were enrolled prospec-
tively and knew that participation was a part of their follow-up
care. It is likely that registries or programs that involve hospital
visits and blood tests, which are necessary to ensure adequate
and accurate data, would have a lower rate of donor participa-
tion than seen in this study. However, it also is likely that if
donors understand that the risks of donation are not completely
clear and understand from the outset that follow-up of their
health is part of the donation process, then we will be able to
obtain sufficient information to gain a better understanding of
risks of living donation.

How, then, in the era before the creation of a national donor
registry and before the development of long-term prospective
studies in diverse donor populations should we evaluate and
counsel potential living kidney donors? The transplant commu-
nity continues to revisit this question, most recently at the
international Amsterdam Forum in 2004. The report that was
generated from this meeting was published in 2005, and we
direct the readers to this article for a comprehensive discussion
of the currently accepted guidelines for living donation (81). As
discussed in this article, however, the data on which these
guidelines are based are not complete. Given these circum-
stances, prudence suggests the exclusion of “marginal living
donors”—prospective donors with medical abnormalities that
have been shown to increase overall medical risk in the general
population. We should recognize that the use of marginal living
donors as a response to the growing number of patients who
have ESRD and are dying while awaiting renal transplantation
may be in direct conflict with our responsibility to potential
donors to “do no harm.” A recent multicenter study of potential
living donors in Canada found that acceptance of potential
donors who were excluded for mild hypertension or protein-
uria would have resulted in only a 3% increase in the number
of patients who receive a transplant (82). Liberalization of these
exclusion criteria would have a minimal impact on the waiting
list and would not offset its steady growth. However, the

892 Clinical Journal of the American Society of Nephrology Clin J Am Soc Nephrol 1: 885– 895, 2006



impact would be great for the potential donor who has hyper-
tension and is eager to donate to his or her child. The evaluation
of potential donors therefore must balance our respect for
donor autonomy with our level of comfort with the risk in-
volved. It is not paternalism but protection of our own core
beliefs that prevents us from facilitating a donation that we
have reason to believe may cause substantial harm to the do-
nor. Perhaps the most compelling argument for maintenance of
cautious donor acceptance criteria and for proceeding with
registries and research studies is our dependence on public
trust and goodwill for continuation of living-donor transplan-
tation. If certain donor characteristics, including medical abnor-
malities, confer greater medical risks, then it likely will be
discovered many years in the future. If the transplant commu-
nity has not made appropriate efforts, through registries and
research, to understand potential risks, then living-donor trans-
plantation and the health care system will be irreparably
damaged.

As Henry David Thoreau said, “To know that we know what
we know, and that we do not know what we do not know, that
is true knowledge.” We must acknowledge to ourselves and to
potential donors the limits of our knowledge and request of our
donors another gift: That of continued participation in research
and in registries. It is only by further study that we may truly
protect our living donors and preserve the practice of living
donation.

References
1. 2004 Annual Report of the US Organ Procurement and Trans-

plantation Network and the Scientific Registry of Transplant
Recipients: Transplant Data 1994 –2003, Department of
Health and Human Services, Health Resources and Ser-
vices Administration, Healthcare Systems Bureau, Divi-
sion of Transplantation, Rockville, MD; United Network
for Organ Sharing, Richmond, VA; University Renal Re-
search and Education Association, Ann Arbor, MI

2. Terasaki PI, Cecka JM, Gjertson DW, Takemoto S: High
survival rates of kidney transplants from spousal and liv-
ing unrelated donors. N Engl J Med 333: 333–336, 1995

3. Bia MJ, Ramos EL, Danovitch GM, Gaston RS, Harmon
WE, Leichtman AB, Lundin PA, Neylan J, Kasiske BL:
Evaluation of living renal donors. The current practice of
US transplant centers. Transplantation 60: 322–327, 1995

4. Textor SC, Taler SJ, Larson TS, Prieto M, Griffin M, Gloor
J, Nyberg S, Velosa J, Schwab T, Stegall M: Blood pressure
evaluation among older living kidney donors. J Am Soc
Nephrol 14: 2159 –2167, 2003

5. Heimbach JK, Taler SJ, Prieto M, Cosio FG, Textor SC,
Kudva YC, Chow GK, Ishitani MB, Larson TS, Stegall MD:
Obesity in living kidney donors: Clinical characteristics
and outcomes in the era of laparoscopic donor nephrec-
tomy. Am J Transplant 5: 1057–1064, 2005

6. Nahas WC, Lucon AM, Mazzucchi E, Scafuri AG, Neto ED,
Ianhez LE, Arap S: Kidney transplantation: The use of
living donors with renal artery lesions. J Urol 160: 1244 –
1247, 1998

7. Serrano DP, Flechner SM, Modlin CS, Streem SB, Goldfarb
DA, Novick AC: The use of kidneys from living donors

with renal vascular disease: Expanding the donor pool.
J Urol 157: 1587–1591, 1997

8. Textor SC, Taler SJ, Driscoll N, Larson TS, Gloor J, Griffin
M, Cosio F, Schwab T, Prieto M, Nyberg S, Ishitani M,
Stegall M: Blood pressure and renal function after kidney
donation from hypertensive living donors. Transplantation
78: 276 –282, 2004

9. Gossmann J, Wilhelm A, Kachel HG, Jordan J, Sann U,
Geiger H, Kramer W, Scheuermann EH: Long-term conse-
quences of live kidney donation follow-up in 93% of living
kidney donors in a single transplant center. Am J Transplant
5: 2417–2424, 2005

10. Chavers BM, Michael AF, Weiland D, Najarian JS, Mauer
SM: Urinary albumin excretion in renal transplant donors.
Am J Surg 149: 343–346, 1985

11. Hakim RM, Goldszer RC, Brenner BM: Hypertension and
proteinuria: Long-term sequelae of uninephrectomy in hu-
mans. Kidney Int 25: 930 –936, 1984

12. Talseth T, Fauchald P, Skrede S, Djoseland O, Berg KJ,
Stenstrom J, Heilo A, Brodwall EK, Flatmark A: Long-term
blood pressure and renal function in kidney donors. Kidney
Int 29: 1072–1076, 1986

13. Dunn JF, Nylander WA Jr, Richie RE, Johnson HK, Mac-
Donell RC Jr, Sawyers JL: Living related kidney donors. A
14-year experience. Ann Surg 203: 637– 643, 1986

14. Fehrman-Ekholm I, Duner F, Brink B, Tyden G, Elinder
CG: No evidence of accelerated loss of kidney function in
living kidney donors: Results from a cross-sectional fol-
low-up. Transplantation 72: 444 – 449, 2001

15. Bahous SA, Stephan A, Blacher J, Safar ME: Aortic stiffness,
living donors, and renal transplantation. Hypertension 47:
216 –221, 2006

16. Eberhard OK, Kliem V, Offner G, Oldhafer K, Fangmann J,
Pichlmay R, Koch KM, Brunkhorst R: Assessment of long-
term risks for living related kidney donors by 24-h blood
pressure monitoring and testing for microalbuminuria.
Clin Transplant 11: 415– 419, 1997

17. Goldfarb DA, Matin SF, Braun WE, Schreiber MJ, Mastroi-
anni B, Papajcik D, Rolin HA, Flechner S, Goormastic M,
Novick AC: Renal outcome 25 years after donor nephrec-
tomy. J Urol 166: 2043–2047, 2001

18. Miller IJ, Suthanthiran M, Riggio RR, Williams JJ, Riehle
RA, Vaughan ED, Stubenbord WT, Mouradian J, Cheigh
JS, Stenzel KH: Impact of renal donation. Long-term clin-
ical and biochemical follow-up of living donors in a single
center. Am J Med 79: 201–208, 1985

19. Najarian JS, Chavers BM, McHugh LE, Matas AJ: 20 years
or more of follow-up of living kidney donors. Lancet 340:
807– 810, 1992

20. Vincenti F, Amend WJ Jr, Kaysen G, Feduska N, Birnbaum
J, Duca R, Salvatierra O: Long-term renal function in kid-
ney donors. Sustained compensatory hyperfiltration with
no adverse effects. Transplantation 36: 626 – 629, 1983

21. Borchhardt KA, Yilmaz N, Haas M, Mayer G: Renal func-
tion and glomerular permselectivity late after living re-
lated donor transplantation. Transplantation 62: 47–51, 1996

22. Lindeman RD, Tobin J, Shock NW: Longitudinal studies on
the rate of decline in renal function with age. J Am Geriatr
Soc 33: 278 –285, 1985

23. Anderson CF, Velosa JA, Frohnert PP, Torres VE, Offord
KP, Vogel JP, Donadio JV Jr, Wilson DM: The risks of

Clin J Am Soc Nephrol 1: 885– 895, 2006 Medical Risks of Living-Kidney Donation 893



unilateral nephrectomy: Status of kidney donors 10 to 20
years postoperatively. Mayo Clin Proc 60: 367–374, 1985

24. Watnick TJ, Jenkins RR, Rackoff P, Baumgarten A, Bia MJ:
Microalbuminuria and hypertension in long-term renal do-
nors. Transplantation 45: 59 – 65, 1988

25. Williams SL, Oler J, Jorkasky DK: Long-term renal function
in kidney donors: A comparison of donors and their sib-
lings. Ann Intern Med 105: 1– 8, 1986

26. Torres VE, Offord KP, Anderson CF, Velosa JA, Frohnert
PP, Donadio JV Jr, Wilson DM: Blood pressure determi-
nants in living-related renal allograft donors and their
recipients. Kidney Int 31: 1383–1390, 1987

27. Bergman S, Key BO, Kirk KA, Warnock DG, Rostant SG:
Kidney disease in the first-degree relatives of African-
Americans with hypertensive end-stage renal disease. Am J
Kidney Dis 27: 341–346, 1996

28. Benabe JE, Rios EV: Kidney disease in the Hispanic popu-
lation: Facing the growing challenge. J Natl Med Assoc 96:
789 –798, 2004

29. Hertz RP, Unger AN, Cornell JA, Saunders E: Racial dis-
parities in hypertension prevalence, awareness, and man-
agement. Arch Intern Med 165: 2098 –2104, 2005

30. Appel LJ, Middleton J, Miller ER 3rd, Lipkowitz M, Norris
K, Agodoa LY, Bakris G, Douglas JG, Charleston J, Gass-
man J, Greene T, Jamerson K, Kusek JW, Lewis JA, Phillips
RA, Rostand SG, Wright JT: The rationale and design of the
AASK cohort study. J Am Soc Nephrol 14[Suppl 2]: S166 –
S172, 2003

31. Qureshi AI, Suri MF, Kirmani JF, Divani AA: Prevalence
and trends of prehypertension and hypertension in United
States: National Health and Nutrition Examination Sur-
veys 1976 to 2000. Med Sci Monit 11: CR403–CR409, 2005

32. He J, Muntner P, Chen J, Roccella EJ, Streiffer RH, Whelton
PK: Factors associated with hypertension control in the
general population of the United States. Arch Intern Med
162: 1051–1058, 2002

33. Update: Prevalence of overweight among children, adoles-
cents, and adults—United States, 1988 –1994. MMWR Morb
Mortal Wkly Rep 46: 198 –202, 1997

34. Hsu CY, McCulloch CE, Iribarren C, Darbinian J, Go AS:
Body mass index and risk for end-stage renal disease. Ann
Intern Med 144: 21–28, 2006

35. Jones CA, Francis ME, Eberhardt MS, Chavers B, Coresh J,
Engelgau M, Kusek JW, Byrd-Holt D, Narayan KM, Her-
man WH, Jones CP, Salive M, Agodoa LY: Microalbumin-
uria in the US population: Third National Health and
Nutrition Examination Survey. Am J Kidney Dis 39: 445–
459, 2002

36. Freedman BI, Soucie JM, Stone SM, Pegram S: Familial
clustering of end-stage renal disease in blacks with HIV-
associated nephropathy. Am J Kidney Dis 34: 254 –258, 1999

37. Freedman BI, Wilson CH, Spray BJ, Tuttle AB, Olorenshaw
IM, Kammer GM: Familial clustering of end-stage renal
disease in blacks with lupus nephritis. Am J Kidney Dis 29:
729 –732, 1997

38. Satko SG, Freedman BI: The familial clustering of renal
disease and related phenotypes. Med Clin North Am 89:
447– 456, 2005

39. Fehrman-Ekholm I, Elinder CG, Stenbeck M, Tyden G,
Groth CG: Kidney donors live longer. Transplantation 64:
976 –978, 1997

40. Ramcharan T, Matas AJ: Long-term (20 –37 years) follow-up
of living kidney donors. Am J Transplant 2: 959 –964, 2002

41. Iglesias-Marquez RA, Calderon S, Santiago-Delpin EA,
Rive-Mora E, Gonzalez-Caraballo Z, Morales-Otero L: The
health of living kidney donors 20 years after donation.
Transplant Proc 33: 2041–2042, 2001

42. Wiesel M, Carl S, Staehler G: Living donor nephrectomy: A
28-year experience at Heidelberg University. Transplant
Proc 29: 2769, 1997

43. Ommen E, Lipkowitz MT, Murphy B: Impact of Ambula-
tory Blood Pressure Monitoring on Living Kidney Dona-
tion [Abstract]. Presented at the annual meeting of the
American Society of Nephrology; November 12, 2005; Phil-
adelphia

44. Ozdemir FN, Guz G, Sezer S, Arat Z, Haberal M: Ambu-
latory blood pressure monitoring in potential renal trans-
plant donors. Nephrol Dial Transplant 15: 1038 –1040, 2000

45. Thiel G: Living kidney donor transplantation: New dimen-
sions. Transpl Int 11[Suppl 1]: S50 –S56, 1998

46. Bertolatus JA, Goddard L: Evaluation of renal function in
potential living kidney donors. Transplantation 71: 256 –260,
2001

47. Rizvi SA, Naqvi SA, Jawad F, Ahmed E, Asghar A, Zafar
MN, Akhtar F: Living kidney donor follow-up in a dedi-
cated clinic. Transplantation 79: 1247–1251, 2005

48. Srivastava A, Sinha T, Varma PP, Karan SC, Sandhu AS, Sethi
GS, Khanna R, Talwar R, Narang V: Experience with mar-
ginal living related kidney donors: Are they becoming rou-
tine or are there still any doubts? Urology 66: 971–975, 2005

49. Saran R, Marshall SM, Madsen R, Keavey P, Tapson JS:
Long-term follow-up of kidney donors: A longitudinal
study. Nephrol Dial Transplant 12: 1615–1621, 1997

50. Bertolatus JA, Friedlander MA, Scheidt C, Hunsicker LG:
Urinary albumin excretion after donor nephrectomy. Am J
Kidney Dis 5: 165–169, 1985

51. Ellison MD, McBride MA, Taranto SE, Delmonico FL,
Kauffman HM: Living kidney donors in need of kidney
transplants: A report from the organ procurement and
transplantation network. Transplantation 74: 1349 –1351,
2002

52. US Renal Data System: USRDS 2004 Annual Data Report:
Atlas of End-Stage Renal Disease in the United States, Be-
thesda, National Institutes of Health, National Institute of
Diabetes and Digestive and Kidney Diseases, 2004

53. Kasiske BL, Ma JZ, Louis TA, Swan SK: Long-term effects
of reduced renal mass in humans. Kidney Int 48: 814 – 819,
1995

54. Guirado LI, Diaz JM, Facundo C, Alcaraz A, Rosales A,
Garcia-Masset R, Sainz Z, Chuy E, Sola R: Results and
complications of 50 laparoscopic nephrectomies for live
donor renal transplantation. Transplant Proc 37: 3673–3675,
2005

55. Gracida C, Espinoza R, Cedillo U, Cancino J: Kidney trans-
plantation with living donors: Nine years of follow-up of
628 living donors. Transplant Proc 35: 946 –947, 2003

56. Muntner P, He J, Hamm L, Loria C, Whelton PK: Renal
insufficiency and subsequent death resulting from cardio-
vascular disease in the United States. J Am Soc Nephrol 13:
745–753, 2002

57. Fried LP, Kronmal RA, Newman AB, Bild DE, Mittelmark
MB, Polak JF, Robbins JA, Gardin JM: Risk factors for

894 Clinical Journal of the American Society of Nephrology Clin J Am Soc Nephrol 1: 885– 895, 2006



5-year mortality in older adults: The Cardiovascular
Health Study. JAMA 279: 585–592, 1998

58. Shulman NB, Ford CE, Hall WD, Blaufox MD, Simon D,
Langford HG, Schneider KA: Prognostic value of serum
creatinine and effect of treatment of hypertension on renal
function. Results from the hypertension detection and fol-
low-up program. The Hypertension Detection and Fol-
low-up Program Cooperative Group. Hypertension 13: I80 –
I93, 1989

59. Go AS, Chertow GM, Fan D, McCulloch CE, Hsu CY:
Chronic kidney disease and the risks of death, cardiovas-
cular events, and hospitalization. N Engl J Med 351: 1296 –
1305, 2004

60. Lewington S, Clarke R, Qizilbash N, Peto R, Collins R:
Age-specific relevance of usual blood pressure to vascular
mortality: A meta-analysis of individual data for one mil-
lion adults in 61 prospective studies. Lancet 360: 1903–1913,
2002

61. Vasan RS, Larson MG, Leip EP, Evans JC, O’Donnell CJ,
Kannel WB, Levy D: Impact of high-normal blood pressure
on the risk of cardiovascular disease. N Engl J Med 345:
1291–1297, 2001

62. Staessen JA, Wang JG, Thijs L: Cardiovascular protection
and blood pressure reduction: A meta-analysis. Lancet 358:
1305–1315, 2001

63. Toronyi E, Alfoldy F, Jaray J, Remport A, Hidvegi M,
Dabasi G, Telkes G, Offenbacher E, Perner F: Evaluation of
the state of health of living related kidney transplantation
donors. Transpl Int 11[Suppl 1]: S57–S59, 1998

64. Tapson JS, Marshall SM, Tisdall SR, Wilkinson R, Ward
MK, Kerr DN: Renal function and blood pressure after
donor nephrectomy. Proc Eur Dial Transplant Assoc Eur Ren
Assoc 21: 580 –587, 1985

65. Hillege HL, Fidler V, Diercks GF, van Gilst WH, de Zeeuw
D, van Veldhuisen DJ, Gans RO, Janssen WM, Grobbee DE,
de Jong PE: Urinary albumin excretion predicts cardiovas-
cular and noncardiovascular mortality in general popula-
tion. Circulation 106: 1777–1782, 2002

66. Klausen K, Borch-Johnsen K, Feldt-Rasmussen B, Jensen G,
Clausen P, Scharling H, Appleyard M, Jensen JS: Very low
levels of microalbuminuria are associated with increased
risk of coronary heart disease and death independently of
renal function, hypertension, and diabetes. Circulation 110:
32–35, 2004

67. Roest M, Banga JD, Janssen WM, Grobbee DE, Sixma JJ, de
Jong PE, de Zeeuw D, van Der Schouw YT: Excessive
urinary albumin levels are associated with future cardio-
vascular mortality in postmenopausal women. Circulation
103: 3057–3061, 2001

68. Romundstad S, Holmen J, Kvenild K, Hallan H, Ellekjaer
H: Microalbuminuria and all-cause mortality in 2,089 ap-
parently healthy individuals: A 4.4-year follow-up study.
The Nord-Trondelag Health Study (HUNT), Norway. Am J
Kidney Dis 42: 466 – 473, 2003

69. Ridker PM: High-sensitivity C-reactive protein: Potential
adjunct for global risk assessment in the primary preven-
tion of cardiovascular disease. Circulation 103: 1813–1818,
2001

70. Kasiske BL: Hyperlipidemia in patients with chronic renal
disease. Am J Kidney Dis 32[Suppl 3]: S142–S156, 1998

71. Suganuma E, Zuo Y, Ayabe N, Ma J, Babaev VR, Linton
MF, Fazio S, Ichikawa I, Fogo AB, Kon V: Antiatherogenic
effects of angiotensin receptor antagonism in mild renal
dysfunction. J Am Soc Nephrol 17: 433– 441, 2006

72. Wilson PW, D’Agostino RB, Sullivan L, Parise H, Kannel
WB: Overweight and obesity as determinants of cardiovas-
cular risk: The Framingham experience. Arch Intern Med
162: 1867–1872, 2002

73. Kenchaiah S, Evans JC, Levy D, Wilson PW, Benjamin EJ,
Larson MG, Kannel WB, Vasan RS: Obesity and the risk of
heart failure. N Engl J Med 347: 305–313, 2002

74. Peeters A, Barendregt JJ, Willekens F, Mackenbach JP, Al
Mamun A, Bonneux L: Obesity in adulthood and its con-
sequences for life expectancy: A life-table analysis. Ann
Intern Med 138: 24 –32, 2003

75. Hedley AA, Ogden CL, Johnson CL, Carroll MD, Curtin
LR, Flegal KM: Prevalence of overweight and obesity
among US children, adolescents, and adults, 1999 –2002.
JAMA 291: 2847–2850, 2004

76. Vasan RS, Pencina MJ, Cobain M, Freiberg MS, D’Agostino
RB: Estimated risks for developing obesity in the Framing-
ham Heart Study. Ann Intern Med 143: 473– 480, 2005

77. Thiel G, Nolte C, Tsinalis D: Living kidney donors with
isolated medical abnormalities: The SOL-DHR experience.
In: Living Donor Kidney Transplantation, edited by Gaston
RS, Wadstrom J, London, Taylor & Francis, 2005, pp 55–73

78. The consensus statement of the Amsterdam Forum on the
Care of the Live Kidney Donor. Transplantation 78: 491–
492, 2004

79. Council on Ethical and Judicial Affairs: Report 5-A-05:
Transplantation of organs from living donors. American
Medical Association, House of Delegates Meeting, June
2005, Chicago

80. McCune TR, Armata T, Mendez-Picon G, Yium J, Zabari
GB, Crandall B, Spicer HG, Blanton J, Thacker LR: The
Living Organ Donor Network: A model registry for living
kidney donors. Clin Transplant 18[Suppl 12]: 33–38, 2004

81. Delmonico F; Council of the Transplantation Society: A
report of the Amsterdam Forum on the care of the living
kidney donor: Data and medical guidelines. Transplanta-
tion 79[Suppl]:S53–S66, 2005

82. Karpinski M, Knoll G, Cohn A, Yang R, Garg A, Storsley L:
The impact of accepting living kidney donors with mild
hypertension or proteinuria on transplantation rates. Am J
Kidney Dis 47: 317–323, 2006

83. Siebels M, Theodorakis J, Schmeller N, Corvin S, Mistry-
Burchardi N, Hillebrand G, Frimberger D, Reich O, Land
W, Hofstetter A: Risks and complications in 160 living
kidney donors who underwent nephroureterectomy. Neph-
rol Dial Transplant 18: 2648 –2654, 2003

84. Fehrman-Ekholm I, Thiel GT: Long-term risks after living
kidney donation. In: Living Donor Kidney Transplantation,
edited by RS Gaston, J Wadstrom, London, Taylor & Fran-
cis, 2005, pp 99 –112

Clin J Am Soc Nephrol 1: 885– 895, 2006 Medical Risks of Living-Kidney Donation 895