Quantifying infection risks in incompatible living donor kidney transplant recipients.

Desensitization has enabled incompatible living donor kidney transplantation (ILDKT) across HLA/ABO barriers, but added immunomodulation might put patients at increased risk of infections. We studied 475 recipients from our center from 2010 to 2015, categorized by desensitization intensity: none/compatible (n = 260), low (0-4 plasmaphereses, n = 47), moderate (5-9, n = 74), and high (≥10, n = 94). The 1-year cumulative incidence of infection was 50.1%, 49.8%, 66.0%, and 73.5% for recipients who received none, low, moderate, and high-intensity desensitization (P < .001). The most common infections were UTI (33.5% of ILDKT vs. 21.5% compatible), opportunistic (21.9% vs. 10.8%), and bloodstream (19.1% vs. 5.4%) (P < .001). In weighted models, a trend toward increased risk was seen in low (wIRR = 0.77 1.402.56 ,P = .3) and moderately (wIRR = 0.88 1.352.06 ,P = .2) desensitized recipients, with a statistically significant 2.22-fold (wIRR = 1.33 2.223.72 ,P = .002) increased risk in highly desensitized recipients. Recipients with ≥4 infections were at higher risk of prolonged hospitalization (wIRR = 2.62 3.574.88 , P < .001) and death-censored graft loss (wHR = 1.15 4.0113.95 ,P = .03). Post-KT infections are more common in desensitized ILDKT recipients. A subset of highly desensitized patients is at ultra-high risk for infections. Strategies should be designed to protect patients from the morbidity of recurrent infections, and to extend the survival benefit of ILDKT across the spectrum of recipients.

ABO blood group incompatible

adjusted hazard ratio

antibody‐mediated rejection

adjusted odds ratio

BK virus

BK virus allograft nephropathy

body mass index

compatible living donor kidney transplant

calculated panel reactive antibody

cytomegalovirus

donor‐specific antibody

end‐stage renal disease

human leukocyte antigen incompatible

Health Resources and Services Administration

incompatible living donor kidney transplant

incidence rate ratio

inverse probability weights

intravenous immunoglobulin

kidney paired donation

kidney transplant

living donor kidney transplant

Organ Procurement and Transplantation Network

polymerase chain reaction

Scientific Registry of Transplant Recipients

urinary tract infection

INTRODUCTION

HLA‐ and/or ABO‐incompatible living donor kidney transplantation (ILDKT) confers a survival benefit for kidney transplant candidates who have a willing, but incompatible donor. , , Alternatives include waiting as many as 10 years on the deceased donor waitlist for a compatible deceased donor transplant, or entering a kidney paired donation (KPD) program, although those with high panel reactive antibody are less likely to find a donor through KPD. , Since ILDKT recipients are at risk of antibody‐mediated rejection (AMR), they undergo modulation of the B cell compartment for desensitization, classically with either plasmapheresis plus low‐dose intravenous immunoglobulin (IVIg), or high‐dose IVIg. , , , , Anti‐B cell agents such as rituximab, and other agents such as bortezomib, eculizumab, and C1 esterase inhibitor have also been used, as well as rescue splenectomy in occasional patients with refractory AMR.

Since these interventions are administered to ILDKT recipients in addition to standard posttransplant immunosuppressive medications, there is potentially an increased risk for infectious complications after ILDKT. Moreover, the incidence and severity of infections may differ within the ILDKT group itself, since some desensitization protocols are more intensive than others. Such information is not only essential for risk prediction and informed consent, but also as a foundation for devising more effective strategies for infection prevention in this vulnerable population. Unfortunately, transplant registry data lack details of ILDKT treatment regimens and posttransplant infections, so studying this has been thus far challenging.

To investigate this further, we collected detailed treatment, infection, and outcomes data on our ILDKT recipients to understand the landscape and impact of infections after ILDKT. Specifically, we sought to (a) quantify the post–KT incidence of a variety of infection types by desensitization intensity; (b) estimate the adverse impact of infections on post–KT hospitalization, acute cellular rejection, death‐censored graft failure (DCGF), and mortality by number of infections developed during the first year post–KT; (c) determine whether ILDKT confers additional risk compared with compatible living donor kidney transplantation (CLDKT); and (d) characterize the outcomes of an ultra‐high‐risk group of ILDKT recipients who had high numbers of recurrent infections during the first year post–KT.

METHODS

Data sources

Data collection from electronic medical record

Using our center's electronic medical record, for each individual patient, we collected induction immunosuppression, number of pretransplant plasmapheresis treatments, number of posttransplant plasmapheresis treatments over the first 6 months post–KT, and any use of rituximab, bortezomib, eculizumab, C1 esterase inhibitor, and splenectomy. Episodes of biopsy‐proven cellular rejection were recorded, including histologic grade and treatment. Other outcomes recorded included hospitalization days during the first year post–KT, and the last date of follow‐up at this center. This study was approved by the Johns Hopkins University Institutional Review Board.

OPTN/SRTR

Additional risk factors and outcomes, including graft failure and death, augmented through linkage to the Centers for Medicare and Medicaid Services and the Social Security Death Master File, were ascertained through linkage with the Scientific Registry of Transplant Recipients (SRTR). The SRTR data system includes data on all donor, waitlisted candidates, and transplant recipients in the United States, submitted by the members of the Organ Procurement and Transplantation Network (OPTN), and has been described elsewhere. The Health Resources and Services Administration (HRSA), U.S. Department of Health and Human Services provides oversight to the activities of the OPTN and SRTR contractors.

Study population

In this retrospective study, we identified all adult (≥18 years or ≥17 years and followed by our adult team) who underwent CLDKT and ILDKT at Johns Hopkins Hospital between January 1, 2010 and December 31, 2015. ILDKT recipients were defined as patients who had detectable donor‐specific antibody of any strength (single‐bead, flow cytometric crossmatch, or cytotoxic crossmatch) that was deemed to require perioperative desensitization therapy to receive a kidney from an HLA‐ or ABO‐incompatible living donor. , At our institution, desensitized recipients underwent plasmapheresis with low‐dose IVIg (except one who received high‐dose IVIg), with or without rituximab, as previously described elsewhere. , ILDKT recipients who did not receive any desensitization (n = 6, 1.2%) and CLDKT recipients who received plasmapheresis for reasons other than desensitization (n = 13, 2.6%) were excluded from the main analyses.

ILDKT intensity

In the present study, we categorized ILDKT recipients into three groups according to total intensity of desensitization: low (total plasmaphereses: 0‐4; median pre‐ vs. posttransplant treatments: 1 vs. 2), moderate (total: 5‐9; median: 2 vs. 4), and high (total: ≥10; median: 4 vs. 11.5). The number of plasmaphereses was determined according to the strength of the initial donor anti‐HLA antibody, response to initial plasmapheresis treatments, real‐time measurements of posttransplant donor anti‐HLA antibody levels, and occurrence of posttransplant antibody‐mediated rejection. , , Additional interventions such as rituximab, bortezomib, eculizumab, and rescue splenectomy were per transplant clinician choice, guided by the above considerations, , and administration of C1 esterase inhibitor was in the setting of a clinical trial for antibody‐mediated rejection.

Infection prophylaxis

All kidney transplant recipients received Pneumocystis prophylaxis for 6 months post–KT (trimethoprim‐sulfamethoxazole unless allergic, otherwise atovaquone or dapsone), and antiviral prophylaxis according to CMV status (valganciclovir for 6 months for CMV donor seropositive/recipient seronegative, valganciclovir for 3 months for recipient seropositive, and acyclovir for donor seronegative/recipient seronegative patients). All patients received nystatin oral suspension post–KT and no routine systemic antifungal prophylaxis.

Patients who received eculizumab had received prior meningococcal vaccination, and received prophylactic amoxicillin until 1 month after completion of eculizumab. Patients who received rescue splenectomy generally had received pneumococcal, meningococcal, and Hemophilus influenzae vaccines prior to transplant (as they were judged antecedently high risk, so the possibility of splenectomy was foreseen and these immunizations administered pretransplant), or received these vaccinations posttransplant if not received prior to transplant.

In addition, it has been part of our standard of care for all transplant candidates to receive pneumococcal vaccination pretransplant (most recently, both pneumococcal polysaccharide vaccine and conjugated pneumococcal vaccine).

Infection ascertainment and definitions

Using our center's electronic medical record, for each individual patient, we collected data on all infections of clinical significance occurring within the first 3 years post–KT, or until the date of death or the last date of follow‐up at this center (if either of these events occurred earlier than 3 years posttransplant). All infection data were reviewed by a transplant infectious disease physician. We used a rigorous system of infection data collection that incorporates published consensus definitions of specific infections, , , , , , , and includes microbiologic, syndromic, and histopathologic data. We reviewed all hospital discharge summaries for the first 3 post–KT years; all pathology biopsy results, and all CMV PCR and BKV PCR results as well as other microbiologic results and clinical notes as needed for additional details on particular infections.

Infections of clinical significance included: (a) all infections which required a hospital admission, (b) all infections which occurred during a hospital admission, (c) all instances of cytomegalovirus (CMV) infection, and (d) all instances of BK virus (BKV) infection. For each infection, the infection type (e.g., pneumonia), date of diagnosis, and organism (if known) were recorded. Infections were categorized according to standard definitions. , , , , CMV infection episodes were classified as CMV viremia (DNAemia) versus tissue‐invasive CMV disease (end‐organ disease), according to standard definitions. BK virus infection episodes were classified as BKV viremia (DNAemia) versus BK virus allograft nephropathy (BKVAN), according to standard definitions. Mild infections in outpatients such as upper respiratory tract infections, sinusitis, bronchitis, asymptomatic bacteriuria, mildly symptomatic urinary tract infections, and minor skin/soft tissue infections were not considered to be clinically significant infections for purposes of this study.

For purposes of this analysis, opportunistic infections were classified as those infections that would be unlikely to develop in immunocompetent patients, including invasive fungal infections, Pneumocystis jiroveci pneumonia, nocardiosis, disseminated zoster, disseminated adenovirus infection, severe chronic norovirus infection, BKVAN, and tissue‐invasive CMV disease.

BKV viremia (DNAemia) was defined as any positive quantitative BKV PCR above the laboratory‐specific lower limit of quantitation of the assay. “Recurrence” of BKV or CMV was defined as a reappearance of BKV or CMV viremia/DNAemia after at least 2 consecutive undetectable PCR results obtained at least 1 week apart.

Time to first post–KT infection

We first used the Kaplan‐Meier method to compare the cumulative incidence of infection 1‐year post–KT by intensity of desensitization. As ILDKT is carefully considered for a specific recipient population, they may differ considerably across baseline characteristics (e.g., calculated panel reactive antibody [cPRA], sex, years on dialysis, etc.) compared to their CLDKT counterparts. Taken with our smaller sample size, estimating the impact of ILDKT, and thus intensity of desensitization, on infection risk may not be meaningful if we were to use conventional regression adjustment methodology. In an effort to correctly quantify this association, we used doubly robust Cox regression. Briefly, this two‐step approach combines the use of inverse probability weights (IPWs) with regression adjustment to obtain unbiased estimates of risk. To start, we generated the IPWs. We used multinomial logistic regression to obtain the propensity score which estimated the likelihood of receiving no, low, moderate, or high levels of desensitization after adjusting for age, sex, race, blood group, cPRA, number of previous kidney transplants, diabetes status, time on dialysis, percentage of time with a functioning kidney transplant during renal‐replacement therapy, and year of transplant. We took the reciprocal of the predicted probabilities generated by the propensity score to calculate the IPWs. Weights were stabilized to limit the influence of outliers. We quantified the standardized mean differences in measured covariates to compare balance, and those that remained unbalanced were included in the final model. We followed recipients until date of first infection, death, last day evaluated at Johns Hopkins Hospital, or administrative censorship 1 year after transplant.

Incidence rate of infection

We first used negative binomial regression to calculate the crude incidence rate of the number of infections developed during the first year post–KT by intensity of desensitization. We then used doubly robust negative binomial regression to obtain the incidence rate ratio (IRR) of infection comparing recipients who were desensitized to those who did not receive any desensitization. Model specification for doubly robust estimation of the IRR was the same as that used to evaluate time to first post–KT infection analysis. Person time was calculated from date of transplant until death, last day evaluated at Johns Hopkins Hospital, or administrative censorship 1 year after transplant.

Adverse impact of infections

Number of infections developed within 1‐year post–KT

We used regression to estimate whether the number of infections developed within the first year of transplant was associated with adverse posttransplant outcomes, including number of hospitalization days within the first year post–KT, biopsy‐proven acute cellular rejection, death‐censored graft survival (DCGF), and death. Specifically, we used doubly robust negative binomial regression for the outcome of hospitalization days, logistic regression for the outcome of acute cellular rejection, and Cox regression for the outcomes of DCGF and death. For our analysis of DCGF and death, we started following recipients 1‐year post–KT given the time‐varying nature of our exposure.

To define our exposure, we created clinically meaningful categories that were sufficient for well‐powered comparisons by dividing the number of infections during the first posttransplant year into the following strata: 0, 1‐3, and ≥4 infections. We then used the same two‐step approach as previously described to create the IPWs. We used multinomial logistic regression to derive the propensity score which estimated the likelihood of developing 0, 1‐3, or ≥4 infections during the first post–KT year, adjusting for the aforementioned characteristics in addition to intensity of desensitization. Weights were stabilized to limit the influence of outliers. We quantified the standardized mean differences in measured covariates to compare balance, and those that remained unbalanced were included in the final model.

ILDKT versus CLDKT

We included an interaction term in each model to test whether ILDKT recipients had the same risk of the aforementioned posttransplant outcomes as CLDKT recipients with the same number of infections post–KT. For these models, we used adjusted negative binomial regression for the outcome of hospitalization days, logistic regression for the outcome of acute cellular rejection, and Cox regression for the outcomes of DCGF and death. Models were adjusted for the same characteristics as those in prior analyses.

Statistical analysis

Baseline characteristics of ILDKT and CLDKT recipients were compared using ANOVA for normally distributed continuous variables, Kruskal‐Wallis rank sum test for non‐normally distributed continuous variables, or the chi‐squared test for binary or categorical variables. For all weighted analyses, a robust, sandwich estimator was used to prevent overestimation of the variance given that the weights were estimated. , Confidence intervals are reported as per the method of Louis and Zeger. All analyses were performed using Stata 16.0/MP for Linux (College Station, TX).

RESULTS

We studied 475 LDKT recipients; 215 were incompatible, of whom 47 received low intensity, 74 received moderate intensity, and 94 received high‐intensity desensitization. Compared to CLDKT (i.e., no desensitization) recipients, ILDKT recipients spent longer time on dialysis prior to transplant (median none = 0.4 years, low = 1.1, moderate = 2.3, high = 2.6, P < .001), were more likely to have had two or more previous transplants (none = 1.2%, low = 10.7%, moderate = 13.5%, high = 12.8%, P < .001), were more likely to have a cPRA≥80% (none = 0.8%, low = 29.8%, moderate = 32.4%, high = 45.7%, P < .001), and were less likely to receive a kidney from a related donor (none = 47.3%, low = 36.2%, moderate = 29.7%, high = 25.5%, P = .001) (Table 1). There were no differences in CMV donor/recipient serostatus for ILDKT and CLDKT recipients (P = .2).

Table 1

Characteristics of living donor kidney transplant recipients, by desensitization intensity (%)

Characteristics	CLDKT	ILDKT a			P value
	None (n = 260)	Low (n = 47)	Moderate (n = 74)	High (n = 94)
Recipient
Type of ILDKT					<.001
ABOi		10.6	12.1	20.2
HLAi		89.4	75.7	56.4
ABOi & HLAi		0.0	12.2	23.4
Age (years), mean (SD)	48.0 (15.3)	49.8 (14.4)	46.7 (15.8)	45.5 (14.1)	.4
Female sex	41.9	46.8	50.0	57.4	.07
Race/ethnicity					1.0
White	70.4	76.6	73.0	70.2
Black	22.7	17.0	20.2	21.3
Other	6.9	6.4	6.8	8.5
BMI (kg/m2), mean (SD)	27.2 (6.2)	27.1 (5.3)	26.9 (5.4)	26.9 (6.4)	1.0
Cause of ESRD					.3
Glomerular diseases	21.9	23.4	29.7	23.4
FSGS	10.8	6.4	12.2	14.9
Diabetes	12.3	8.5	8.1	12.8
Hypertension	24.6	25.5	17.6	21.3
Polycystic kidney disease	13.5	6.4	5.4	8.5
Other	16.9	29.8	27.0	19.1
Years on dialysis, median (IQR)	0.4 (0.0, 1.6)	1.1 (0.0, 3.7)	2.3 (0.2, 4.4)	2.6 (1.0, 5.0)	<.001
Number of previous transplants					<.001
0	91.1	48.9	47.3	54.2
1	7.7	40.4	39.2	33.0
≥2	1.2	10.7	13.5	12.8
cPRA (%)					<.001
0	90.3	40.4	41.9	29.8
1‐20	3.1	4.3	2.7	5.3
21‐79	5.8	25.5	23.0	19.2
≥80	0.8	29.8	32.4	45.7
CMV					.2
D+/R‐	14.6	14.9	13.5	10.6
D+/R+	29.2	38.3	40.5	43.6
Other	56.2	46.8	46.0	45.8
Donor
Age, mean (SD)	44.0 (12.6)	43.9 (14.0)	44.7 (11.2)	44.9 (13.1)	.9
Race/ethnicity					.2
White	76.5	78.7	68.9	66.0
Black	16.2	17.0	16.2	23.4
Other	7.3	4.3	14.9	10.6
Related donor	47.3	36.2	29.7	25.5	.001
Immunosuppression
Desensitization regimen
Rituximab	—	44.7	58.1	84.0	<.001
Eculizumab	—	10.6	6.8	21.3	.02
Bortezomib	—	0.0	0.0	4.3	.2
C1 esterase inhibitor	—	0.0	0.0	9.6	.002
Splenectomy					.002
Yes	—	0.0	0.0	10.6
Previous history	—	0.0	1.4	2.1
High‐dose IVIg	—	0.0	0.0	1.1	1.0
Number of desensitization agents received					<.001
0	—	44.7	39.2	10.7
1	—	55.3	55.4	58.5
2	—	0.0	5.4	20.2
3	—	0.0	0.0	8.5
4	—	0.0	0.0	2.1
Induction immunosuppression					<.001
No induction	3.5	0.0	0.0	0.0
Thymoglobulin only	91.9	87.2	86.5	81.9
Basiliximab only	4.6	12.8	10.8	8.5
Both	0.0	0.0	2.7	9.6

Abbreviations: BMI, body mass index; CLDKT, compatible living donor kidney transplantation; cPRA, calculated panel reactive antibody; CMV; cytomegalovirus; D, donor; ESRD, end‐stage renal disease; FSGS; focal segmental glomerulosclerosis; IQR, interquartile range; ILDKT, incompatible living donor kidney transplantation; LDKT living donor kidney transplantation; R, recipient; SD, standard deviation.

Low (0‐4 plasmaphereses), moderate (5‐9 plasmaphereses), and high (≥10 plasmaphereses).

Desensitization and induction immunosuppression regimens

Among ILDKT recipients, the number of desensitization agents received increased with increasing intensity of desensitization (Table 1). Recipients who received high‐intensity desensitization were more likely to receive rituximab (low = 44.7%, moderate = 58.1%, high = 84.0%, P < .001), eculizumab (low = 10.6%, moderate = 6.8%, high = 21.3%, P = .02), C1 esterase inhibitor (low = 0.0%, moderate = 0.0%, high = 9.6%, P = .002), and rescue splenectomy (low = 0.0%, moderate = 0.0%, high = 10.6%, P = .002) (Table 1). The only use of bortezomib, C1 esterase inhibitor, and rescue splenectomy was in the high‐intensity desensitization group. ILDKT recipients were less likely to receive thymoglobulin alone for induction compared to CLDKT recipients (none = 91.9%, low = 87.2%, moderate = 86.5%, high = 81.9%, P < .001).

Time to first post–kidney transplant infection

At 1 month, the post–KT incidence of infection was 19.2%, 25.5%, 28.4%, and 45.9% for recipients who received no desensitization (i.e., CLDKT), low, moderate, and high‐intensity desensitization (P < .001) (Figure 1). At 1 year, the cumulative incidence of a post–KT infection rose to 50.1%, 49.8%, 66.0%, and 73.5%, respectively (P < .001). In weighted models, a trend toward increased risk was seen in patients who received low (weighted hazard ratio [wHR] =0.551.112.23, P = .8) and moderate intensity desensitization (wHR = 0.901.482.44, P = .1), and a statistically significant 1.71‐fold increased risk of developing an infection during the first year post–KT was seen for those who received high‐intensity desensitization (wHR = 1.101.712.66, P = .02) (Table 2).

Figure 1

Time to first infection within 1‐year posttransplant, by intensity of desensitization. Compared to recipients who received no desensitization (i.e., CLDKT), ILDKT recipients had a faster time to infection. At 1 month, the post–KT incidence was 19.2%, 25.5%, 28.4%, and 45.9% for recipients who received none, low, moderate, and high levels of desensitization, respectively (P < .001). At 6 months, the post–KT incidence was 37.2%, 43.0%, 54.6%, and 70.1% for recipients who received none, low, moderate, and high levels of desensitization (P < .001). At 1 year, the post–KT incidence was 50.1%, 49.8%, 66.0%, and 73.5% for recipients who received none, low, moderate, and high levels of desensitization (P < .001)

Table 2

Incidence of infection at 1‐year posttransplant, by intensity of desensitization (%)

	CLDKT	ILDKTa
	None	Low	Moderate	High
Time to first infection, wHR	ref	0.551.112.23	0.901.482.44	1.101.712.66
Rate of infection, wIRR	ref	0.771.402.56	0.881.352.06	1.332.223.72

Abbreviations: wHR, weighted hazard ratio; wIRR, weighted incidence rate ratio; CLDKT, compatible living donor kidney transplantation; ILDKT, incompatible living donor kidney transplantation.

Bold indicates P < .05.

Low (0‐4 plasmaphereses), moderate (5‐9 plasmaphereses), and high (≥10 plasmaphereses).

At 1 year, the crude post–KT infection rate was 96.2 per 100 person‐years, 141.0 per 100 person‐years, 142.1 per 100 person‐years, and 292.9 per 100 person‐years for those who received no desensitization (i.e., CLDKT), low, moderate, and high‐intensity desensitization. In weighted models, a trend toward increased risk was seen in recipients who received low (weighted incidence rate ratio [wIRR]  = 0.771.402.56, P = .3) or moderate (wIRR = 0.881.352.06, P = .2) intensity desensitization, and a statistically significant 2.22‐fold (wIRR = 1.332.223.72, P = .002) increase in the number of infection cases was seen for those who received high‐intensity desensitization, compared to recipients who received none during the first year post–KT (Table 2).

Types of infection

There was wide variation in the types of infections experienced by ILDKT and CLDKT recipients in the first year posttransplant (Table 3; Figure 2). The most common infections overall were urinary tract infections (UTI) (27.0%), opportunistic infections (15.8%), and BK DNAmia (15.8%) (Figure 2; Table 3).

Table 3

Incidence of infection at 1‐year posttransplant, by intensity of desensitization (%)

Infection	CLDKT	P‐value a	ILDKT b				P‐value c
	None (n = 260)		Overall (n = 215)	Low (n = 47)	Moderate (n = 74)	High (n = 94)
Median number, (IQR)	1 (0, 2)	<.001	1 (0, 3)	1 (0, 3)	1 (1, 3)	2 (1, 4)	<.001
Type
Urinary tract	21.5	.004	33.5	31.9	25.7	40.4	.005
Opportunistic	10.8	<.001	21.9	21.3	20.3	23.4	.008
BK virus
DNAemia	18.5	.1	12.6	14.9	14.9	9.6	.2
BKVAN	3.1	.005	9.3	10.6	9.5	8.5	.02
Bloodstream	5.4	<.001	19.1	14.9	14.9	24.5	<.001
CMV
DNAemia	10.0	.6	12.1	6.4	8.1	18.1	.1
Tissue invasive	0.8	.3	2.3	0.0	2.7	3.2	.2
Pneumonia	4.6	.002	12.1	8.5	10.8	16.0	.005
C. difficile	3.8	<.001	13.5	8.5	9.5	19.1	<.001
Other viral	3.5	.007	9.8	6.4	10.8	10.6	.02
Surgical site	3.8	.2	6.5	0.0	5.4	10.6	.03
Gastroenteritis	4.6	.8	5.1	8.5	1.4	6.4	.2
Invasive fungal	2.3	.02	7.0	2.1	2.7	12.8	.001
Skin/soft tissue	2.3	.1	5.1	2.1	4.1	7.4	.1

Abbreviations: BKVAN, BK virus‐associated nephropathy; C. difficile, C lostridium difficile; CMV, cytomegalovirus; IQR, interquartile range.

p‐value tests difference between overall ILDKT vs. CLDKT.

Low (0‐4 plasmaphereses), moderate (5‐9 plasmaphereses), and high (≥10 plasmaphereses).

p‐value tests difference between intensity of desensitization vs. CLDKT.

Figure 2

Incidence of infection at 1‐year posttransplant, by transplant type. There was wide variation in the types of infections developed between ILDKT and CLDKT recipients during the first year posttransplant. The most common infections were UTIs (overall: 27.0%; ILDKT: 15.2%), opportunistic infections (overall: 15.8%; ILDKT: 9.9%), and BK DNAemia (overall: 15.8%; ILDKT: 5.8%). The least common infections were gastroenteritis (overall: 4.8%; ILDKT: 2.3%), invasive fungal (overall: 4.5%; ILDKT: 3.2%), skin/soft tissue infections (overall: 3.6%; ILDKT: 2.3%), and tissue‐invasive CMV (overall: 1.5%; ILDKT: 1.1%). BKVAN, BK virus‐associated nephropathy; CMV, cytomegalovirus; C. difficile, Clostridium difficile; UTI, urinary tract infection

Risks for specific types of infections within the first year differed by intensity of desensitization, generally with highest risks in those who received highest intensity desensitization (Table 3). Specific infections that followed this pattern included urinary tract infections, opportunistic infections, bloodstream infections, pneumonias, C.difficile diarrhea, surgical site infections, and invasive fungal infections (Table 3). Regarding viral infections, there was no significant difference in risk for tissue‐invasive CMV between desensitization groups, but BKVAN and other viral infections were more likely to occur in ILDKT compared to CLDKT recipients (Table 3).

Infection recurrence after the first post–KT year

In the second year post–KT, 23.2% of recipients developed an infection; of these, 66.4% were recurrent infections. ILDKT recipients were more likely to develop recurrent infections compared to CLDKT recipients (none = 12.7%, low = 19.1%, moderate = 13.5%, high = 22.3%) (Figure 3). In the third year post–KT, 16.6% of recipients developed an infection; of these, 84.8% were recurrent infections. ILDKT recipients were more likely to develop recurrent infections compared to CLDKT recipients (none = 12.7%, low = 10.6%, moderate = 14.9%, high = 19.1%) (Figure 3).

Figure 3

Frequency of incident and recurrent infections from years 1‐3 posttransplant, by intensity of desensitization. ILDKT recipients were more likely to develop both incident and recurrent infections, particularly those who were highly desensitized. In the second year post–KT, 23.2% of recipients developed an infection; of these, 66.4% were recurrent infections (none = 12.7%, low = 19.1%, moderate = 13.5%, high = 22.3%). In the third year post–KT, 16.6% of recipients developed an infection; of these, 84.8% were recurrent infections (none = 12.7%, low = 10.6%, moderate = 14.9%, high = 19.1%)

Adverse impact of number of infections within the first year post–KT

Recipients who developed between 1 and 3 infections within the first year post–KT had a higher rate of hospitalization days (wIRR = 1.051.321.66, P = .02), but no difference in the risk of acute cellular rejection, DCGF, and mortality compared to those who did not develop any infection (Table 4). Recipients who developed ≥4 infections within the first year post–KT had a substantially higher rate of hospitalization days (wIRR = 2.623.574.88, P < .001), and increased risk of DCGF (wHR = 1.154.0113.95, P = .03), but no difference in the risk of acute cellular rejection and mortality compared to those who did not develop any infection (Table 4).

Table 4

Adverse impact of infections, according to number of infections developed within 1‐year post–KT and transplant type

	Overall a	CLDKT b	ILDKT b	P for interaction c
Hospitalization days, IRR
0 infections	ref	ref	ref	—
1‐3 infections	1.051.321.66	1.091.331.63	1.141.441.80	.6
≥4 infections	2.623.574.88	2.663.905.71	2.934.005.44	.9
Acute cellular rejection, OR
0 infections	ref	ref	ref	—
1‐3 infections	0.530.941.67	0.621.674.50	0.380.761.52	.2
≥4 infections	0.230.661.92	0.121.1010.01	0.300.932.94	.9
Mortality, HR
0 infections	ref	ref	ref	—
1‐3 infections	0.460.931.88	0.822.135.49	0.340.811.91	.1
≥4 infections	0.431.153.03	0.291.497.63	0.862.255.89	.7
Death‐censored graft failure, HR d
0 infections	ref
1‐3 infections	0.661.825.05	—	—	—
≥4 infections	1.154.0113.95

Abbreviations: HR; hazard ratio; IRR, incidence rate ratio; OR, odds ratio; CLDKT, compatible living donor kidney transplantation; ILDKT, incompatible living donor kidney transplantation.

Bold indicates P < .05.

Overall: weighted analyses (i.e., wIRR, wOR, wHR).

CLDKT/ILDKT: adjusted analyses (i.e., aIRR, aOR, aHR).

p for interaction compares CLDKT vs. ILDKT.

Did not achieve convergence for CLDKT and ILDKT estimates.

Recurrent infections ultra‐high‐risk group

There were 10 recipients (including 7 who had received high‐intensity desensitization) who developed 7–9 infections, and 7 recipients (all of whom had received high‐intensity desensitization) who developed ≥10 infections within the first year post–KT. For those who developed 7–9 infections: 4 recipients received thymoglobulin (2 of whom did not receive plasmapheresis [i.e., CLDKT]); 2 recipients received thymoglobulin and rituximab; 2 recipients received thymoglobulin, basiliximab, and rituximab; 1 recipient received thymoglobulin, basiliximab, and splenectomy; 1 recipient received thymoglobulin, rituximab, eculizumab, splenectomy, and bortezomib. Similarly, for those who developed ≥10 infections: 4 recipients received thymoglobulin and rituximab; 1 recipient received thymoglobulin, rituximab, and eculizumab; 1 recipient received basiliximab, rituximab, and eculizumab; 1 recipient received thymoglobulin, rituximab, eculizumab, and splenectomy.

Although these numbers were too small for stable statistical analysis, the group who developed 7–9 infections had a median of 106 hospitalization days (IQR 98, 117) and mortality of 60%, and the group who developed ≥10 infections had a median of 117 hospitalization days (IQR (95,224) and mortality of 43%.

Effect modification of adverse impact of infections: ILDKT versus CLDKT

To determine if ILDKT status was associated with additional risk beyond that associated with number of infections post–KT, we included an interaction term in each model to test whether ILDKT recipients had the same risk of adverse posttransplant outcomes as CLDKT recipients with the same number of infections post–KT. The risk of hospitalization, acute cellular rejection, or mortality was no higher for ILDKT than for CLDKT recipients, irrespective of the number of infections developed (p for interactions ≥.1) (Table 4).

DISCUSSION

In this single‐center study using systematic, granular ascertainment of posttransplant infections in 475 living donor kidney recipients, ILDKT recipients were at higher risk than CLDKT recipients for many infectious complications during the first year post–KT. At 1 year, the cumulative incidence of a post–KT infection ranged from 50.1% in those who received no desensitization to 73.5% for recipients who received high‐intensity desensitization. We found a comparable incidence rate of infection for recipients who received low or moderate intensity desensitization, but a 2.2‐fold higher incidence rate of infection for those who received high‐intensity desensitization compared to recipients who received none. A higher incidence of urinary tract infections, bloodstream infections, pneumonias, Clostridium difficile, surgical site infections, invasive fungal infections, and opportunistic infections was associated with increasing intensity of desensitization.

Additionally, recipients who developed infections had significantly more hospitalization days than those with no infections during the first post–KT year. Specifically, recipients with 1‐3 infections during the first post–KT year had a 1.3‐fold increase, and those with ≥4 infections had a 3.6‐fold increase in the rate of hospitalization days. Furthermore, recipients with ≥4 infections had a 4.0‐fold higher risk of death‐censored graft failure. A small group of patients, most of whom had undergone high‐intensity desensitization, had extremely high numbers of infections during the first posttransplant year (10 had 7–9 infections, and 7 had ≥10 infections); these patients had a median of 106 and 117 hospitalization days, respectively; 60% of those with 7‐9 infections and 43% of those with ≥10 infections died. There is clearly much to be learned about the heterogeneity within the ILDKT group, and not all of this can be explained by intensity of desensitization, as only 14/94 (15%) of those who had received high‐intensity desensitization were in this ultra‐high‐risk group with 7 or more infections.

Previous studies that have reported infection data in HLAi ILDKT recipients have reported divergent results. , , , , Kahwaji et al found no significant differences in infection risk between ILDKT who received rituximab plus IVIg for desensitization, compared with a nonsensitized, ABO‐compatible group. By contrast, Kamar et al reported increased risk for fungal, and decreased risk for viral infections, with use of rituximab for any indication in KT recipients. The Korean national registry study reported infections in terms of causes of death, but did not include data on incidence of infections or specific infections. Reasons for these heterogeneous results could include differences in patient populations, immunosuppression and desensitization protocols, and infection definitions and ascertainment. This heterogeneity underscores the need for more research to delineate differential risks between ILDKT and CLDKT groups.

Our study has some limitations worthy of mention. First, as with any single‐center investigation, there are always limitations to generalizability. However, our findings are likely generalizable to other centers using PP/IVIG‐based protocols, which represents the majority of HLAi centers worldwide. Additionally, our findings are likely generalizable to other protocols, given that we found a “dose‐response” with intensity of desensitization. Second, infections resulting in admission to other medical centers may not have been reported in our transplant center's electronic medical record; however, particularly in the first post–KT year, our center is vigilant about obtaining outside medical records on our recipients, and most patients hospitalized at outside centers with serious infections are transferred to our center for further management. Therefore, we feel that focusing only on the most serious infections, and on the first posttransplant year, has minimized the likelihood of missing substantial numbers of these infections.

In conclusion, ILDKT recipients are at increased risk for recurrent posttransplant infection, particularly those undergoing high intensity of desensitization (≥10 plasmapheresis treatments, +/‐ rituximab, bortezomib, or other agents). These post–KT infections have a substantial impact on outcomes: development of ≥4 infections in the first year was associated with increased hospitalization days and death‐censored graft failure. With these adverse outcomes in mind, optimizing infection prevention is crucial in this population. Further study is required before firm recommendations can be made, but interventions might include more frequent monitoring of microbiologic and immunologic parameters in high‐risk patients, and/or individualized antimicrobial prophylaxis programs based on each patient's previous patterns of infection. A better understanding of the high‐risk phenotype for infections will enable development of improved protocols for infection prevention in the most vulnerable patients.

DISCLOSURE

The authors of this manuscript have conflicts of interest to disclose as described by the American Journal of Transplantation. R Avery: study grant support from Aicuris, Astellas, Chimerix, Merck, Oxford Immunotec, Qiagen, Takeda/Shire. R. A. Montgomery: study grant support from Hansa Medical AB; consulting income from Immucor kSORT, Biologix LLC, RMEI, Shire, and Vitaeris/CSL Behring. K.A. Marr: consulting / advisory board income from Amplyx, Chimerix, Cidara, Merck, Scynexis, and Sfunga. Equity / licensing review from MycoMed Technologies. D. Segev: consulting/speaking honoraria from Sanofi, Novartis, CSL Behring, and Veloxis.