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Complement-activating donor-specific anti-HLA antibodies and solid organ transplant survival: A systematic review and meta-analysis


In a systematic review and meta-analysis, Alexandre Loupy and colleagues study antibody biomarkers of solid organ transplantation outcomes.


Published in the journal: . PLoS Med 15(5): e32767. doi:10.1371/journal.pmed.1002572
Category: Research Article
doi: https://doi.org/10.1371/journal.pmed.1002572

Summary

In a systematic review and meta-analysis, Alexandre Loupy and colleagues study antibody biomarkers of solid organ transplantation outcomes.

Introduction

Organ transplantation is the treatment of choice for many patients with end-stage chronic disease, which is an increasing burden on industrialized and newly industrialized countries [1,2]. Despite substantial progress in the development of effective immunosuppressive regimens, thousands of allografts fail every year worldwide due to rejection, with immediate consequences in terms of mortality, morbidity, and billions in extra costs to healthcare systems [3,4]. In the past decade, the role of circulating anti-human leukocyte antigen donor-specific antibodies (anti-HLA DSAs) has been increasingly recognized as a major contributing factor to allograft rejection [5] and long-term allograft failure [69] in kidney transplantation [10], with the same important associations more recently appreciated in lung [11], heart [712], liver [13], intestinal [14], and pancreas transplants [15].

However, not all antibodies are equal in terms of pathogenicity, and they exert a heterogeneous influence on organ allograft outcomes, ranging from acute forms of rejection leading to immediate allograft dysfunction and early allograft loss to more indolent or subclinical forms leading to progressive allograft deterioration.

The inconsistent effects of anti-HLA antibodies on allograft outcomes, which limit their prognostic value, has recently led to attempts to refine their assessment on the basis of pathogenic characteristics to determine which anti-HLA DSAs carry the highest risk for adverse transplant outcomes. Among the notable characteristics of HLA antibodies, their capacity to activate complement has been suggested as a potential factor directing their pathogenicity in the rejection process [16]. Data support that circulating anti-HLA DSAs have the ability to activate complement by their complement component 1q (C1q), C3d, and C4d complement fraction-binding capacities or by their immunoglobulin G3 (IgG3) subclass component, which are associated with an increased risk of antibody-mediated rejection (ABMR) and allograft loss in solid organ transplant recipients [1625]. However, prior studies have reported different magnitudes of effect for these antibodies, ranging from strong effects to the absence of associations with allograft outcomes [18,19,2630], limiting their implementation in clinical practice. Greater precision in predicting allograft outcomes using a mechanistically informed, noninvasive biomarker generalizable to diverse solid organ transplants has been identified as a major goal by professional societies (e.g., the European Society of Organ Transplantation, the American Society for Transplantation, and the American Society of Transplant Surgeons), agencies (e.g., the European Medicine Agency and the Food and Drug Administration) [31], and consortia [32]. These groups have pointed to the need for such biomarkers as vital both to optimizing allocation policy and to better stratifying the risk of long-term allograft failure for individual patients. This meta-analysis aims to evaluate the role of complement-activating anti-HLA DSAs on graft survival and graft rejection across the entire spectrum of solid organ transplants.

Methods

This meta-analysis is reported in adherence with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) and the reporting Meta-Analyses of Observational Studies in Epidemiology (MOOSE) [33,34].

Data sources and searches

A comprehensive search was designed and conducted by an experienced librarian with input from the study investigators. The complete protocol of the research strategy was prespecified and the analysis plan prospectively written (S1 Text). Controlled vocabulary supplemented with keywords was used to search for complement-activating anti-HLA DSAs in human solid organ transplantation in any language. The following databases were included: Ovid MEDLINE In-Process & Other Non-Indexed Citations, Ovid MEDLINE, Ovid EMBASE, Ovid Cochrane Central Register of Controlled Trials, Ovid Cochrane Database of Systematic Reviews, and Scopus. The research was conducted from database inception to January 31, 2018. Complement-activating anti-HLA DSAs were defined by their capacity to activate complement cascade at different levels—C1q [23], C3d [35], C4d [26], or presence of IgG3 subtype [36].

The following keywords were used for the research: “solid organ transplantation,” “kidney transplantation,” “liver transplantation,” “lung transplantation,” “heart transplantation,” “intestines transplantation,” “donor specific anti-HLA antibodies,” “solid-phase assay,” “complement-activating DSA,” “C1q,” “C3d,” “C4d,” “IgG3 subclass,” “outcome,” “graft loss,” “graft survival,” “ABMR,” and “rejection.” For comprehensiveness, we also reviewed all references listed in the full-text publications and reviews on the subject that were not identified by our search criteria. An example of the research strategy in the Ovid database is described in S2 Text.

Study selection

Studies of any relevant design and in any language on the impact of complement-activating anti-HLA DSAs on long-term graft survival and/or the risk of rejection were initially selected. The eligible studies included all solid organ transplant patients (kidney, liver, lung, heart, and intestinal transplantation), both adult or pediatric patients. Anti-HLA DSAs detected by the Luminex single-antigen bead (SAB) technique were required for the DSA detection technique. Complement-activating anti-HLA DSAs were defined according to their ability to bind C1q, C3d, C4d or their IgG3 subclass. The endpoints of interest for inclusion were either allograft loss for the primary endpoint and/or biopsy-proven rejection as a secondary endpoint. Allograft rejection was labelled either antibody-mediated or mixed-rejection as defined by the Banff international classification for kidney and liver transplants [37,38] or the International Society for Heart and Lung Transplantation (ISHLT) classification for heart and lung transplants [39]. Data on graft loss (hazard ratio [HR]) and/or allograft rejection (HR or odds ratio [OR]) were extracted when available and defined as effect sizes with their 95% confidence intervals (CIs).

The corresponding author of each eligible study was contacted and asked to provide HRs and/or ORs when these were not available in the manuscript. All initial communications with authors were based on a template explaining the study and the data required. Two separate reminders were sent unless we received a definitive response. When no answer was obtained, the study was excluded from the analysis.

We excluded unrelated articles, including those without information on complement-activating anti-HLA DSAs, duplicates, those with nonhuman results or non–solid-organ transplant data, case reports, abstract-only articles, and reviews.

Two reviewers (C Loheac and A Bouquegneau) independently assessed the potential eligibility of each of the titles and abstracts that resulted from the search and then reviewed the full texts of all potentially eligible studies. Chance-adjusted inter-reviewer agreement (kappa statistic) was calculated. All disagreements were resolved by consensus between reviewers and principal investigators (C Lefaucheur and A Loupy).

Data extraction and quality assessment

The collected data included author name, year of publication, study size, mean or median follow-up time, mean age of population, type of complement-activating anti-HLA DSA, comparison used (patients with complement-activating anti-HLA DSAs were either compared to patients without complement-activating anti-HLA DSAs, patients with non-complement activating anti-HLA DSAs detected, or a mixed group of patients without anti-HLA DSAs and with non-complement activating anti-HLA DSAs), effect sizes (HR and/or OR) and their 95% CIs, potential confounding factors, and unadjusted and adjusted estimated risks of graft loss or graft rejection. Adjusted HRs and ORs were used when available; otherwise, univariate effect sizes were used.

We used the Newcastle–Ottawa Scale (NOS) to assess the methodological quality (i.e., risk of bias) of nonrandomized studies [40]. NOS score was calculated on the basis of the following 3 major components: the selection of the study groups and ascertainment of exposure (0 to 4 points), quality of the adjustment for confounding variables (0 to 2 points), and ascertainment of outcomes (0 to 3 points). A high NOS score represents high methodological quality. The only randomized controlled trial was assessed using the Cochrane Risk of Bias tool. Details regarding the NOS scoring system are provided in S3 Text.

Data synthesis and analysis

Meta-analysis was performed using a random-effects model [41] because of the anticipated heterogeneity across studies. In a random-effects meta-analysis model, the effect sizes from the studies that actually were performed are assumed to represent a random sample from a particular distribution of these effect sizes and take into account both within-study variability (expressed by the CI in each study’s effect sizes) and between-study variability (heterogeneity).

The index group for comparison was patients with complement-activating anti-HLA DSAs, and they were either compared to patients with non–complement-activating anti-HLA DSAs, patients without anti-HLA DSAs detected, or a mixed group of patients without anti-HLA DSAs and with non-complement activating anti-HLA DSAs.

Statistical heterogeneity and publication bias

Statistical heterogeneity across the studies was tested with the I2 index [42]. The I2 index describes the percentage of total variation across studies due to heterogeneity rather than chance. A value of 0% indicates no observed heterogeneity; values exceeding 50% may elicit considerable caution and warrant further analysis through subgroup analyses [43]. A low P value of the I2 test (below 0.05) provides evidence of heterogeneity of intervention effects (variation in effect estimates beyond chance). Publication bias was visually assessed using funnel plots and statistically assessed by the Egger’s bias coefficient, which weighted the regression of the intervention effect on its standard error (SE), with weights inversely proportional to the variance of the intervention effect [44]. P < 0.05 (2-sided) was considered statistically significant for the presence of a publication bias.

We investigated the extent to which statistical heterogeneity between results of multiple studies can be related to one or more characteristics of the studies by using metaregression [45]. Metaregression merges meta-analytic techniques with linear regression principles (predicting treatment effects using covariates). Metaregression could also explore possible causes of heterogeneity and ascertain stability of results between subgroup analyses. In the present study, we decided to adjust effect sizes on the following covariates if available: date of publication, mean fluorescence intensity (MFI) for anti-HLA DSAs, number of HLA mismatches, period of inclusion, and mean recipient age. We used the overall model P value to assess whether there is evidence for an association of any of the covariates with the outcome [46].

Subgroup and sensitivity analyses

These analyses were performed to explore potential sources of heterogeneity regarding the primary outcome and to assess the consistency of our results, and the choice of the different subgroup analyses was prespecified prior to any analysis. The following subgroup analyses were considered.

Comparator group used

Considering the index group (complement-activating anti-HLA DSA), we analyzed separately the studies comparing patients with non–complement-activating anti-HLA DSAs or control consisting of a mixed group of patients with non–complement-activating anti-HLA DSAs and without anti-HLA DSAs.

Studies that used multivariable models

Studies using multivariable models for addressing the independent associations of complement activation with allograft failure were analyzed separately.

High versus low methodological quality studies

Articles with NOS scores ≥6 (versus lower scores) were selected as high-quality studies [47] and analyzed separately.

Type of organ transplanted

Kidney allograft versus all other types of transplanted organs (heart, lung, and liver allografts). We decided to gather together the groups of liver, lung, and heart transplantation because of their low number. Indeed, with a low number of studies (3 or fewer), the risk of increasing the heterogeneity is important.

Timing of antibody detection

Preexisting anti-HLA DSAs (defined as antibodies present before or at the time of transplantation), de novo anti-HLA DSAs (defined as antibodies present only after transplantation), or a combined group of preexisting and de novo DSAs.

Type of assay used for characterizing the complement-activating capacity of antibodies

Assays were characterized as anti-HLA DSA IgG subclass, C1q-binding anti-HLA DSAs, C4d-binding anti-HLA DSAs, or C3d-binding anti-HLA DSAs. Because IgG subclass and complement-binding tests may not provide the exact same information and biological properties, we performed a post hoc supplemental analysis on the impact of complement-binding anti-HLA DSAs (C1q, C3d, and C4d) and the IgG3 subclass studies and their respective associations with allograft outcome.

Center effect

This subgroup analysis excluded the largest cohorts (in terms of the number of patients included) [16,48,49]. We performed this analysis because larger studies could be a main driving factor for the associations found in primary analyses and could also modify overall heterogeneity.

Analyses were conducted using STATA (version 14.1; StataCorp, College Station, TX).

Results

Study identification and characteristics

The electronic search identified 5,861 potentially relevant citations. A schematic diagram of the literature search procedure used in the present study is shown in Fig 1. The kappa statistic for study eligibility was 0.9941 between the two reviewers (SE = 0.0949). Finally, 37 studies and 7,936 patients were included in the final meta-analysis, including 24 studies with data on allograft loss, 8 studies with data on rejection, and 5 studies with both primary- and secondary-outcome data. Table 1 summarizes characteristics of the included studies. S1 Table provides a detailed characteristic of included studies.

Fig. 1. Flow chart summarizing the research strategy for study identification and selection.
Flow chart summarizing the research strategy for study identification and selection.
DSA, donor-specific antibody; SAB, single-antigen bead.

Tab. 1. Characteristics of the 37 included studies.
Characteristics of the 37 included studies.
Effect sizes refer to HR for graft survival and OR for rejection appearance.

Overall, 22 (59.5%) studies originated from Europe, 9 (24.3%) originated from North America, 4 (10.8%) originated from the United Kingdom, and 2 (5.4%) originated from Asia. The patients included were kidney recipients (n = 5,991; 75.5%), liver recipients (n = 1,459; 18.4%), heart recipients (n = 370; 4.7%), and lung recipients (n = 116; 1.4%). None of the studies included patients with intestine or pancreas transplantation. Complement-activating anti-HLA DSAs were assessed by their capacity to bind C1q (19 studies), C4d (6 studies), or C3d (4 studies) or by their IgG subclass composition (8 studies). Six studies simultaneously analyzed 2 complement-activating anti-HLA DSA assays [17,20,24,48,49,56]. The mean patient follow-up time post transplantation was 71.2 ± 32.3 months. None of the studies included were sponsored or conducted by diagnostic companies involved in the manufacture or sale of complement-activating antibody assays. Nineteen authors were contacted and asked for supplementary data, and 63% of them provided with the requested information.

The funnel plot presented in Fig 2 demonstrates the absence of a publication bias (Egger’s test P = 0.224). The randomized controlled trial was of moderate quality [70]. The NOS scores for quality assessments of the included studies are presented in S2 Table. The median NOS score was 6 (minimum 3, maximum 9), with 2.8%, 2.8%, 19.4%, 38.9%, 22.2%, 11.1%, and 2.8% of studies having a NOS score of 3, 4, 5, 6, 7, 8, and 9, respectively.

Fig. 2. Funnel plot representing the analysis for publication bias with Egger’s test for bias.
Funnel plot representing the analysis for publication bias with Egger’s test for bias.
Each dot represents a study; the y-axis represents study precision (95% CIs), and the x-axis shows the SE of the HR. CI, confidence interval; HR, hazard ratio; SE: standard error.

Complement-activating anti-HLA DSA status and outcomes

Risk of allograft loss according to complement-activating anti-HLA DSA status

Patients with complement-activating anti-HLA DSAs had a 3.09-fold increased risk of long-term allograft loss compared to patients without anti-HLA DSAs, patients with non–complement-activating anti-HLA DSAs, and a mixed group including patients without anti-HLA DSAs and with non–complement-activating anti-HLA DSAs (HR 3.09; 95% CI 2.55–3.74, P = 0.001; I2 = 29.3%) (Fig 3).

Fig. 3. Association between circulating complement-activating anti-HLA DSAs and the risk of allograft loss.
Association between circulating complement-activating anti-HLA DSAs and the risk of allograft loss.
Fig 3 shows the forest plot of the association between complement-activating anti-HLA DSAs and the risk of allograft loss for each study and overall (n = 29). Studies are listed by date of publication. Number of patients are listed in the 3 cohort columns. The black diamond-shaped boxes represent the HR for each individual study. The grey boxes around the black diamond represent the weight of the study, and lines represent the 95% CI for individual studies. The blue diamond at the end represents the pooled HR. The number of patients in the overall population does not correspond to the sum of the different groups for the studies of Kaneku et al. (2012) (3 patients), Sicard et al. (2015) (4 patients), and Moktefi et al. (2017) (3 patients) either because the data for these patients were missing or because they were not involved in the analysis. CI, confidence interval; DSA, donor-specific antibody; HLA, human leukocyte antigen; HR, hazard ratio.

Risk of allograft rejection according to complement-activating anti-HLA status

Patients with complement-activating anti-HLA DSAs had a 3.75-fold increased risk of allograft rejection compared to patients without anti-HLA DSAs, patients with non–complement-activating anti-HLA DSAs, and a mixed group including patients without anti-HLA DSAs and with non–complement-activating anti-HLA DSAs (HR 3.75; 95% CI 2.05–6.87, P = 0.001; I2 = 69.8%) (Fig 4).

Fig. 4. Association between complement-activating anti-HLA DSAs and the risk of rejection.
Association between complement-activating anti-HLA DSAs and the risk of rejection.
Fig 4 shows the forest plot of the association between complement-activating anti-HLA DSAs and the risk of rejection for each study and overall (n = 13). Studies are listed by date of publication. The black diamond-shaped boxes represent the HR for each individual study. The grey boxes around the black diamond represent the weight of the study, and lines represent the 95% CI for individual studies. The blue diamond at the end represents the overall HR. CI, confidence interval; DSA, donor-specific antibody; HLA, human leukocyte antigen; HR, hazard ratio.

Subgroup and sensitivity analyses

Subgroup and sensitivity analyses were performed on the outcome of graft loss to confirm the consistency of the results and explain some of the heterogeneity found in the overall results. Table 2 summarizes the different effect sizes for the different subgroup analyses.

Tab. 2. Effect sizes related to the different subgroup analyses.
Effect sizes related to the different subgroup analyses.
Table 2 summarizes the effect sizes observed in the different subgroup analyses described in the Materials and methods. Effect sizes refer to HR for graft survival and OR for rejection appearance. Index group refers to patients with complement-activating anti-HLA DSAs.

Effect of the complement-activating anti-HLA DSAs in studies with different comparators used

Sensitivity analysis restricted to studies with different comparators used demonstrated consistent results regarding the association between complement-activating anti-HLA DSAs and risk of allograft loss, with a pooled HR of 2.94 for patients with complement-activating anti-HLA DSAs compared to patients with non–complement-activating anti-HLA DSAs (95% CI 2.04–4.23, P = 0.001; I2 = 41.1%) (S1 Fig). The pooled HR for patients with complement-activating anti-HLA DSAs compared to patients with a mixed group of patients without DSAs and with non–complement-activating DSAs was 3.60 (95% CI 2.74–4.73, P = 0.001; I2 = 0.0%) (S2 Fig).

Regarding the risk of rejection, the pooled HR for patients with complement-activating anti-HLA DSAs compared to patients with non–complement-activating anti-HLA DSAs was 4.24 (95% CI 2.23–8.06, P = 0.001; I2 = 55.0%) (S3 Fig).

Multivariable models: Independent prognostic value of complement-activating anti-HLA DSA

When selecting studies that performed multivariable models, adjusting complement-activating anti-HLA DSA status on pan-IgG anti-HLA DSA level defined by the MFI, the presence of complement-activating anti-HLA DSAs remained significantly and independently associated with an increased risk of allograft loss (HR 3.01; 95% CI 2.26–4.0, P = 0.001), and the heterogeneity across studies decreased from 29.3% to 17.4% (Fig 5).

Fig. 5. Association of circulating complement-activating anti-HLA DSAs with the risk of allograft loss in selected studies with multivariable models including MFI and complement-activating anti-HLA DSA.
Association of circulating complement-activating anti-HLA DSAs with the risk of allograft loss in selected studies with multivariable models including MFI and complement-activating anti-HLA DSA.
Fig 5 shows the forest plot of the association between complement-activating anti-HLA DSAs and the risk of allograft loss in studies with multivariable models including MFI and complement-activating anti-HLA DSA (n = 8). Studies are listed by date of publication. The black diamond-shaped boxes represent the HR for each individual study. The grey boxes around the black diamond represent the weight of the study, and lines represent the 95% CI for individual studies. The blue diamond at the end represents the overall HR. The number of patients in the overall population does not correspond to the sum in the different groups for the studies of Kaneku et al. (2012) (3 patients) and Sicard et al. (2015) (4 patients) either because the data for these patients were missing or because they were not involved in the analysis. CI, confidence interval; DSA, donor-specific antibody; HLA, human leukocyte antigen; HR, hazard ratio; MFI, mean fluorescence intensity.

Effect of complement-activating anti-HLA DSAs in studies with high methodological quality

Sensitivity analysis restricted to studies with high methodological quality (NOS score ≥6) demonstrated consistent results regarding the association between complement-activating anti-HLA DSAs and the risk of long-term allograft loss, with a pooled HR of 2.87 (95% CI 2.42–3.39, P = 0.001; I2 = 3.1%) (S4 Fig). Sensitivity analysis restricted to studies with lower methodological quality (NOS score ≤5) demonstrated that complement-activating anti-HLA DSAs were associated with the risk of long-term allograft loss, with a pooled HR of 3.82 (95% CI 1.75–8.33, P = 0.001; I2 = 67.8%).

Effect of complement-activating anti-HLA DSAs according to the type of solid organ transplant

Sensitivity analysis restricted to kidney allograft recipients demonstrated an increased risk of allograft loss associated with the presence of complement-activating anti-HLA DSAs, with a pooled HR of 3.26 (95% CI 2.58–4.11, P = 0.001; I2 = 26.6%) (S5 Fig). The analysis including heart, lung, and liver recipients showed a pooled HR of 2.71 (95% CI 1.98–3.72, P = 0.001; I2 = 29.3%) (S5 Fig).

Effect of complement-activating anti-HLA DSAs according to the timing of antibody detection

We performed a stratified analysis according to the time of antibody detection. We confirmed that in patients with either preexisting (HR 2.67; 95% CI 1.79–4.00, P = 0.001; I2 = 52.7%) anti-HLA DSAs or de novo (HR 3.65; 95% CI 2.45–5.44, P = 0.001; I2 = 38.0%) anti-HLA DSAs, complement-activating anti-HLA DSAs remained significantly associated with an increased risk of allograft loss (S6 Fig).

Analysis according to the type of test used for detecting complement-activating antibodies

Primary analyses were stratified according to the type of test used for detecting complement-activating antibodies. We found consistent associations across the different methods to detect complement-activating anti-HLA antibodies: (i) C1q-binding capacity (HR 2.80, 95% CI 2.11–3.71, I2 = 42.1%), (ii) IgG3 subclass (HR 3.11, 95% CI 2.29–4.22, I2 = 0.0%), (iii) C3d-binding capacity (HR 5.04, 95% CI 2.10–12.07, I2 = 51.2%), and (iv) C4d-binding capacity (HR 3.82, 95% CI 2.05–7.11, I2 = 29.8%). Because IgG3 subclass DSA may not provide the exact same information as complement-binding tests (C1q, C3d, C4d), we performed additional post hoc analyses and found similar associations when stratified according to complement-activating anti-HLA DSAs (C1q-, C3d-, and C4d-binding ability) and IgG subclass, with a pooled HR of 3.11 (95% CI 2.42–4.0, P = 0.001) and 3.11 (95% CI 2.29–4.22, P = 0.001), respectively (S7 Fig).

Center effect

After removing the 3 largest studies from the analysis [16,48,49], the presence of complement-activating anti-HLA DSAs remained significantly associated with an increased risk of allograft loss (HR 2.90; 95% CI 2.33–3.60, P = 0.001), and the heterogeneity across studies remained stable at 31.8% (S8 Fig).

In order to identify additional factors explaining residual heterogeneity, we performed metaregression and did not find any significant association between date of publication (P = 0.664), mean MFI for anti-HLA DSA (P = 0.632), number of HLA mismatch (P = 0.582), period of inclusion (P = 0.109), mean population age (P = 0.078), and the risk of allograft loss.

Discussion

In the present meta-analysis including 7,936 solid organ transplant patients, we established that complement-activating anti-HLA DSAs represent an important determinant of allograft loss across multiple types of organ transplants without a significant publication bias and with acceptable heterogeneity. Patients with complement-activating anti-HLA DSAs have a 3-fold–increased risk of allograft loss compared with patients without anti-HLA DSAs and/or patients with non–complement-activating anti-HLA DSAs. These associations were consistent regarding long-term allograft loss in high-quality studies, across different solid organ transplant populations (kidney, heart, lung, and liver transplant recipients), across different types of tests used for detecting complement-activating anti-HLA DSAs, and at different times of evaluation for complement-activating anti-HLA DSA status (before and after transplantation). Moreover, beyond the effect on allograft survival, we found that complement-activating anti-HLA DSAs were also strongly associated with an increased risk of allograft rejection. These findings reinforce the robustness of the results and their applicability in different clinical scenarios and transplant programs with different practices and support the possibility of a causal effect between complement-activating antibodies and allograft injury.

One of the major hurdles in the quest to develop personalized medicine in transplantation and improve overall transplant patient outcomes is the lack of valid, mechanistically-informed noninvasive biomarkers for predicting allograft outcomes that can be used for patient risk stratification, clinical trial design, and as surrogate endpoints. The recognition of the dominant role of anti-HLA antibodies in rejection and late failure of kidney [10], heart [12], liver [13], lung [11], or intestinal [14] transplants has been a turning point for transplant medicine in the past decade. However, not all anti-HLA DSAs are equal in terms of pathogenicity and therefore may not be consistently associated with adverse allograft outcomes. Because activation of the complement cascade is an important component of the ABMR process, new approaches have been developed to better characterize anti-HLA DSAs and link their capacity to activate complement to the pathophysiology of transplant rejection. The complement-activating ability of anti-HLA antibodies and/or complement-activating IgG subclasses have been shown to be associated with more severe rejection episodes and diminished long-term graft survival [17,49,50]. However, some groups have reported different results, with varying magnitudes of effects ranging from strong to marginal associations between complement-activating anti-HLA DSAs and allograft loss [19,27].

The results of this meta-analysis were robust across diverse subgroup analyses. First, although kidney transplant patients represented the highest number of patients included in the present meta-analysis, the effects of complement-activating anti-HLA DSAs on allograft loss remained significant in heart, lung, and liver transplant patients. Grouping non-kidney transplant studies together (liver, lung, and heart transplantation) as opposed to kidney transplant studies was based on the larger volume of studies focusing on kidney transplant patients. This mirrors the distribution of solid organ transplants worldwide (84,347 kidney transplantations among the 126,670 total organs transplanted) [72].

Second, the same effect was observed regardless of whether the antibody was preexisting or de novo. Third, we found similar associations regardless of the type of test used for assessing complement-activating anti-HLA DSAs.

In most of the studies included in this meta-analysis, a correlation existed between complement-activating antibody status and anti-HLA DSA level (assessed by MFI). Despite this correlation, 8 studies included in the present meta-analysis with sufficient statistical power to perform multivariable models demonstrated that the association between C1q-, C3d-binding tests or IgG3 test and allograft outcomes was independent of the level of anti-HLA DSA MFI (Fig 5). Moreover, the SAB assays can be falsely low, while the C1q assay is more accurate. Therefore, the SAB assay has limitations that mislead the interpretation in comparing MFI versus C1q, C3d, or C4d assays [73]. In contrast to MFI that was reported in most of the studies in this meta-analysis, anti-HLA DSA level determined by titer of antibody correlated with complement-fixing ability [22,74]. In addition to the requirement of minimum titer of DSAs (>1:16) to be complement fixing, the composition of IgG subtypes may also influence the complement-binding capacity [48,75]. Therefore, C1q, C3d and IgG3 assays provide additional insights beyond the DSA strength/titer. Finally, the cutoffs used for antibody detection and for complement-activating anti-HLA DSAs in the different studies was variable. These different cutoffs and technical issues in anti-HLA DSA detection, such as avoidance of the prozone effect, are beyond the scope of the present study.

The heterogeneity (I2) found in the present study may be explained by (i) different tests and protocols used for screening complement-activating antibodies (C1q, C4d, C3d, and IgG subclass), (ii) different types of transplant cohorts and clinical management, including risk-taking strategies (high versus low immunological risk transplant populations), (iii) the timing of antibody detection before and after transplantation, and (iv) nonoptimal statistical power and statistical methodologies used in some studies. Despite this overall heterogeneity, when subgroup analyses were performed including studies with high methodological quality, the heterogeneity decreased from 29.3% to 3.1%. When patients with kidney transplantation were analyzed, the heterogeneity remained stable. Also, when studies using multivariable models were selected in the main analysis, the heterogeneity dropped to 17.4%. Last, despite the overall heterogeneity, the association between complement-activating antibodies and allograft loss remained highly significant in many different clinical scenarios, transplant populations, and relative to the timing of antibody detection, thereby reinforcing the study conclusions.

The findings of the present study have important clinical implications. The magnitude of the overall association found in the present study further reinforces the possibility of using circulating complement-activating anti-HLA DSAs as a potential prognostic factor for allograft loss in transplant patients. Relative to studies from other medical fields such as oncology or cardiology, well-recognized prognostic biomarkers did not always provide associations as high as the one observed in the present medical scenario [7679]. Beyond their prognostic ability, the characterization of complement-activating anti-HLA DSA properties may influence the allocation system. The consolidation of the SAB–pan-IgG assay in the detection of preformed anti-HLA antibodies has improved transplantation success. However, its high sensitivity has limited the allograft allocation for sensitized patients. The result from this meta-analysis reveals that not all anti-HLA DSAs detected by SAB–pan-IgG assays are equally pathogenic, supporting that, overall, the neat-serum MFI value alone—which only offers a semiquantitative measurement of antibody level—is not entirely reliable for predicting transplant outcome. While the clinical use of SAB–C1q assay for the identification of unacceptable mismatches would improve wait-listed patient stratification regarding their risk of allograft loss, it might also increase the limited allograft allocation of highly sensitized patients—predefined by the standard SAB–pan-IgG assay but restratified as non–C1q-binding DSAs by the SAB–C1q assay—thereby shortening their waiting time.

Characterization of complement-activating anti-HLA DSAs may also have therapeutic significance, providing opportunities for the prevention and/or treatment of ABMR given the availability of specific drugs targeting complement or inhibiting complement-dependent cytotoxicity [8082]. The present study provides an important step toward a pathogenesis-based approach for preventing and/or treating ABMR. Compared with the current approach to treatment, which only considers the presence of circulating anti-HLA DSAs, a risk-stratified approach on the basis of the complement-activating capacity of anti-HLA DSAs might significantly improve the response rate to complement-inhibitor drugs. The validity of this approach has recently been suggested in a clinical trial [83] in addition to post hoc analyses of 2 clinical trials (NCT01567085 and NCT01399593) including kidney transplant recipients with preformed anti-HLA DSAs receiving C5 inhibitor (eculizumab) for rejection prophylaxis, showing that the effect of eculizumab on allograft function depends on the complement-activating capacity of anti-HLA DSAs [84]. Further studies are needed for defining whether complement-activating anti-HLA DSAs have the potential to inform therapeutic decision-making for timely intervention and to streamline the use of expensive complement inhibitors in kidney transplantation.

We recognize the following limitations. We first acknowledge the higher proportion of kidney recipients compared to heart, liver, and lung transplant recipients. We also acknowledge that fewer studies regarding allograft rejection are included, which is partly due to the lack of histological phenotyping provided by the allograft biopsy in certain studies. Further studies are required to quantify the magnitude of the effect of complement-activating anti-HLA antibodies on the risk of allograft rejection and the efficacy of ABMR therapies. Third, the timing of anti-HLA detection is also a limitation, and because of the number of studies in the different groups of DSA detection, a comparison between groups was not reliable. Fourth, no data were available from Australian or South American transplant populations or from intestines or pancreas transplantation, limiting the extrapolation of our results to these patient populations. Finally, almost all of the included studies were observational and retrospective. Confounding factors from unknown origin may explain part of the residual heterogeneity observed.

In conclusion, circulating complement-activating anti-HLA DSAs represent a significant determinant of long-term allograft survival and solid organ transplant rejection and may be considered a potential valuable prognostic biomarker for improving the risk stratification for allograft loss.

Supporting Information

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Zdroje

1. Port FK, Wolfe RA, Mauger EA, Berling DP, Jiang K. Comparison of survival probabilities for dialysis patients vs cadaveric renal transplant recipients. JAMA. 1993;270: 1339–1343. 8360969

2. Stehlik J, Edwards LB, Kucheryavaya AY, Benden C, Christie JD, Dobbels F, et al. The Registry of the International Society for Heart and Lung Transplantation: Twenty–eighth Adult Heart Transplant Report––2011. J Heart Lung Transplant. 2011;30: 1078–1094. doi: 10.1016/j.healun.2011.08.003 21962016

3. Organ Procurement and Transplantation Network: Scientific registry of transplant recipients. [Cited 1 January 2018]. Available from: http://optn.transplant.hrsa.gov/data/.

4. Eurotransplant Annual Report. [Cited 1 January 2018]. Available from: https://www.eurotransplant.org/cms/index.php?page=annual_reports.

5. Nankivell BJ, Alexander SI. Rejection of the kidney allograft. N Engl J Med. 2010;363: 1451–1462. doi: 10.1056/NEJMra0902927 20925547

6. Mohan S, Palanisamy A, Tsapepas D, Tanriover B, Crew RJ, Dube G, et al. Donor-specific antibodies adversely affect kidney allograft outcomes. J Am Soc Nephrol. 2012;23: 2061–2071. doi: 10.1681/ASN.2012070664 23160511

7. Smith JD, Banner NR, Hamour IM, Ozawa M, Goh A, Robinson D, et al. De novo donor HLA–specific antibodies after heart transplantation are an independent predictor of poor patient survival. Am J Transplant. 2011;11: 312–319. doi: 10.1111/j.1600-6143.2010.03383.x 21219570

8. Kulkarni HS, Bemiss BC, Hachem RR. Antibody–mediated Rejection in Lung Transplantation. Curr Transplant Rep. 2015;2: 316–323. doi: 10.1007/s40472-015-0074-5 27896040

9. Kaneku H, O’Leary JG, Banuelos N, Jennings LW, Susskind BM, Klintmalm GB, et al. De novo donor-specific HLA antibodies decrease patient and graft survival in liver transplant recipients. Am J Transplant. 2013;13: 1541–1548. doi: 10.1111/ajt.12212 23721554

10. Lefaucheur C, Loupy A, Hill GS, Andrade J, Nochy D, Antoine C, et al. Preexisting donor-specific HLA antibodies predict outcome in kidney transplantation. J Am Soc Nephrol. 2010;21: 1398–1406. doi: 10.1681/ASN.2009101065 20634297

11. Morrell MR, Pilewski JM, Gries CJ, Pipeling MR, Crespo MM, Ensor CR, et al. De novo donor-specific HLA antibodies are associated with early and high–grade bronchiolitis obliterans syndrome and death after lung transplantation. J Heart Lung Transplant. 2014;33: 1288–1294. doi: 10.1016/j.healun.2014.07.018 25443870

12. Ho EK, Vlad G, Vasilescu ER, de la Torre L, Colovai AI, Burke E, et al. Pre–and posttransplantation allosensitization in heart allograft recipients: major impact of de novo alloantibody production on allograft survival. Hum Immunol. 2011;72: 5–10. doi: 10.1016/j.humimm.2010.10.013 20971146

13. O’Leary JG, Kaneku H, Susskind BM, Jennings LW, Neri MA, Davis GL, et al. High mean fluorescence intensity donor-specific anti-HLA antibodies associated with chronic rejection post liver transplant. Am J Transplant. 2011;11: 1868–1876. doi: 10.1111/j.1600-6143.2011.03593.x 21672151

14. Cheng EY, Everly MJ, Kaneku H, Banuelos N, Wozniak LJ, Venick RS, et al. Prevalence and clinical impact of donor-specific alloantibody among intestinal transplant recipients. Transplantation. 2017;101: 873–882. doi: 10.1097/TP.0000000000001391 27490417

15. Mittal S, Page SL, Friend PJ, Sharples EJ, Fuggle SV. De novo donor-specific HLA antibodies: Biomarkers of pancreas transplant failure. Am J Transplant. 2014;14: 1664–1671. doi: 10.1111/ajt.12750 24866735

16. Loupy A, Lefaucheur C, Vernerey D, Prugger C, Duong van Huyen J–P, Mooney N, et al. Complement–binding anti-HLA antibodies and kidney–allograft survival. N Engl J Med. 2013;369: 1215–1226. doi: 10.1056/NEJMoa1302506 24066742

17. Sicard A, Ducreux S, Rabeyrin M, Couzi L, McGregor B, Badet L, et al. Detection of C3d–binding donor-specific anti-HLA antibodies at diagnosis of humoral rejection predicts renal graft loss. J Am Soc Nephrol. 2015;26: 457–467. doi: 10.1681/ASN.2013101144 25125383

18. Calp–Inal S, Ajaimy M, Melamed ML, Savchik C, Masiakos P, Colovai A, et al. The prevalence and clinical significance of C1q–binding donor-specific anti-HLA antibodies early and late after kidney transplantation. Kidney Int. 2016;89: 209–216. doi: 10.1038/ki.2015.275 26535999

19. Guidicelli G, Guerville F, Lepreux S, Wiebe C, Thaunat O, Dubois V, et al. Non–Complement–Binding De Novo Donor-specific Anti-HLA Antibodies and Kidney Allograft Survival. J Am Soc Nephrol. 2016;27: 615–625. doi: 10.1681/ASN.2014040326 26047793

20. Comoli P, Cioni M, Tagliamacco A, Quartuccio G, Innocente A, Fontana I, et al. Acquisition of C3d–Binding Activity by De Novo Donor-specific HLA Antibodies Correlates With Graft Loss in Nonsensitized Pediatric Kidney Recipients. Am J Transplant. 2016;16: 2106–2116. doi: 10.1111/ajt.13700 26725780

21. Fichtner A, Süsal C, Höcker B, Rieger S, Waldherr R, Westhoff JH, et al. Association of C1q–fixing DSA with late graft failure in pediatric renal transplant recipients. Pediatr Nephrol. 2016;31: 1157–1166. doi: 10.1007/s00467-016-3322-8 26928311

22. Zeevi A, Lunz J, Feingold B, Shullo M, Bermudez C, Teuteberg J, et al. Persistent strong anti-HLA antibody at high titer is complement binding and associated with increased risk of antibody–mediated rejection in heart transplant recipients. J Heart Lung Transplant. 2013;32: 98–105. doi: 10.1016/j.healun.2012.09.021 23142561

23. Chin C, Chen G, Sequeria F, Berry G, Siehr S, Bernstein D, et al. Clinical usefulness of a novel C1q assay to detect immunoglobulin G antibodies capable of fixing complement in sensitized pediatric heart transplant patients. J Heart Lung Transplant. 2011;30: 158–163. doi: 10.1016/j.healun.2010.08.020 20951058

24. O’Leary JG, Kaneku H, Banuelos N, Jennings LW, Klintmalm GB, Terasaki PI. Impact of IgG3 subclass and C1q–fixing donor-specific HLA alloantibodies on rejection and survival in liver transplantation. Am J Transplant. 2015;15: 1003–1013. doi: 10.1111/ajt.13153 25772599

25. Smith JD, Ibrahim MW, Newell H, Danskine AJ, Soresi S, Burke MM, et al. Pre–transplant donor HLA–specific antibodies: characteristics causing detrimental effects on survival after lung transplantation. J Heart Lung Transplant. 2014;33: 1074–1082. doi: 10.1016/j.healun.2014.02.033 24954882

26. Wahrmann M, Bartel G, Exner M, Regele H, Körmöczi GF, Fischer GF, et al. Clinical relevance of preformed C4d–fixing and non–C4d–fixing HLA single antigen reactivity in renal allograft recipients. Transpl Int. 2009;22: 982–989. doi: 10.1111/j.1432-2277.2009.00912.x 19619171

27. Wiebe C, Gareau AJ, Pochinco D, Gibson IW, Ho J, Birk PE, et al. Evaluation of C1q Status and Titer of De Novo Donor-specific Antibodies as Predictors of Allograft Survival. Am J Transplant. 2017;17: 703–711. doi: 10.1111/ajt.14015 27539748

28. Hönger G, Wahrmann M, Amico P, Hopfer H, Böhmig GA, Schaub S. C4d–fixing capability of low–level donor-specific HLA antibodies is not predictive for early antibody–mediated rejection. Transplantation. 2010;89: 1471–1475. doi: 10.1097/TP.0b013e3181dc13e7 20395886

29. Yell M, Muth BL, Kaufman DB, Djamali A, Ellis TM. C1q Binding Activity of De Novo Donor-specific HLA Antibodies in Renal Transplant Recipients With and Without Antibody–mediated Rejection: Transplantation. 2015;99: 1151–1155. doi: 10.1097/TP.0000000000000699 25839705

30. Kauke T, Oberhauser C, Lin V, Coenen M, Fischereder M, Dick A, et al. De novo donorspecific anti-HLA antibodies after kidney transplantation are associated with impaired graft outcome independently of their C1q–binding ability. Transpl Int. 2017;30: 360–370. doi: 10.1111/tri.12887 27862352

31. Capital Reporting Company from the Food and Drug Administration. Surrogate Endpoints for Clinical Trials in Kidney Transplantation 28 September 2015. [Cited 1 January 2018]. Available from: https://www.fda.gov/downloads/Drugs/NewsEvents/UCM470429.pdf.

32. Transplant Therapeutics Consortium. [Cited 1 January 2018]. Available from: https://c-path.org/programs/ttc/.

33. Moher D, Liberati A, Tetzlaff J, Altman DG, PRISMA Group. Preferred reporting items for systematic reviews and meta–analyses: the PRISMA statement. BMJ. 2009;339: b2535. doi: 10.1136/bmj.b2535 19622551

34. Stroup DF, Berlin JA, Morton SC, Olkin I, Williamson GD, Rennie D, et al. Meta-analysis of observational studies in epidemiology: a proposal for reporting. Meta-analysis Of Observational Studies in Epidemiology (MOOSE) group. JAMA. 2000;283: 2008–2012. 10789670

35. Guidicelli G, Anies G, Bachelet T, Dubois V, Moreau J– F, Merville P, et al. The complement interference phenomenon as a cause for sharp fluctuations of serum anti-HLA antibody strength in kidney transplant patients. Transpl Immunol. 2013;29: 17–21. doi: 10.1016/j.trim.2013.09.005 24056164

36. Tao MH, Smith RI, Morrison SL. Structural features of human immunoglobulin G that determine isotype–specific differences in complement activation. J Exp Med. 1993;178: 661–667. 8340761

37. Loupy A, Haas M, Solez K, Racusen L, Glotz D, Seron D, et al. The Banff 2015 Kidney Meeting Report: Current Challenges in Rejection Classification and Prospects for Adopting Molecular Pathology. Am J Transplant. 2017;17: 28–41. doi: 10.1111/ajt.14107 27862883

38. Demetris A, Adams D, Bellamy C, Blakolmer K, Clouston A, Dhillon AP, et al. Update of the International Banff Schema for Liver Allograft Rejection: working recommendations for the histopathologic staging and reporting of chronic rejection. An International Panel. Hepatology. 2000;31: 792–799. doi: 10.1002/hep.510310337 10706577

39. Berry GJ, Angelini A, Burke MM, Bruneval P, Fishbein MC, Hammond E, et al. The ISHLT working formulation for pathologic diagnosis of antibody–mediated rejection in heart transplantation: evolution and current status (2005–2011). J Heart Lung Transplant. 2011;30: 601–611. doi: 10.1016/j.healun.2011.02.015 21555100

40. Wells GA, Shea B, O’Connell D, Peterson J, Welch V, Losos M, et al. The Newcastle–Ottawa Scale (NOS) for assessing the quality of non–randomised studies in meta–analyses. [Cited 1 January 2018]. Available from: http://www.ohri.ca/programs/clinical_epidemiology/oxford.asp.

41. Nikolakopoulou A, Mavridis D, Salanti G. How to interpret meta-analysis models: fixed effect and random effects meta–analyses. Evid Based Ment Health. 2014;17: 64. doi: 10.1136/eb-2014-101794 24778439

42. Higgins JPT, Thompson SG, Deeks JJ, Altman DG. Measuring inconsistency in meta–analyses. BMJ. 2003;327: 557–560. doi: 10.1136/bmj.327.7414.557 12958120

43. Higgins JPT, Thompson SG. Quantifying heterogeneity in a meta-analysis. Stat Med. 2002;21: 1539–1558. doi: 10.1002/sim.1186 12111919

44. Egger M, Davey Smith G, Schneider M, Minder C. Bias in meta-analysis detected by a simple, graphical test. BMJ. 1997;315: 629–634. 9310563

45. Thompson SG, Higgins JPT. How should meta–regression analyses be undertaken and interpreted? Stat Med. 2002;21: 1559–1573. doi: 10.1002/sim.1187 12111920

46. Harbord RM, Higgins JPT. Meta–regression in Stata. Stata J. 2008;4: 493–519.

47. McPheeters ML, Kripalani S, Peterson NB, Idowu RT, Jerome RN, Potter SA, et al. Closing the quality gap: revisiting the state of the science (vol. 3: quality improvement interventions to address health disparities). Evid ReportTechnology Assess. 2012;208.3: 1–475.

48. Lefaucheur C, Viglietti D, Bentlejewski C, Huyen J–PD van, Vernerey D, Aubert O, et al. IgG Donor-specific Anti–Human HLA Antibody Subclasses and Kidney Allograft Antibody–Mediated Injury. J Am Soc Nephrol. 2016;27: 293–304. doi: 10.1681/ASN.2014111120 26293822

49. Viglietti D, Loupy A, Vernerey D, Bentlejewski C, Gosset C, Aubert O, et al. Value of Donor-specific Anti-HLA Antibody Monitoring and Characterization for Risk Stratification of Kidney Allograft Loss. J Am Soc Nephrol. 2017;28: 702–715. doi: 10.1681/ASN.2016030368 27493255

50. Sutherland SM, Chen G, Sequeira FA, Lou CD, Alexander SR, Tyan DB. Complement–fixing donor-specific antibodies identified by a novel C1q assay are associated with allograft loss. Pediatr Transplant. 2012;16: 12–17. doi: 10.1111/j.1399-3046.2011.01599.x 22093755

51. Hönger G, Hopfer H, Arnold M–L, Spriewald BM, Schaub S, Amico P. Pretransplant IgG subclasses of donor-specific human leukocyte antigen antibodies and development of antibody–mediated rejection. Transplantation. 2011;92: 41–47. doi: 10.1097/TP.0b013e31821cdf0d 21637140

52. Kaneku H, O’Leary JG, Taniguchi M, Susskind BM, Terasaki PI, Klintmalm GB. Donor-specific human leukocyte antigen antibodies of the immunoglobulin G3 subclass are associated with chronic rejection and graft loss after liver transplantation. Liver Transpl. 2012;18: 984–992. doi: 10.1002/lt.23451 22508525

53. Bartel G, Wahrmann M, Schwaiger E, Kikic Z, Winzer C, Horl WH, et al. Solid phase detection of C4d–fixing HLA antibodies to predict rejection in high immunological risk kidney transplant recipients. Transpl Int. 2013;26: 121–30. doi: 10.1111/tri.12000 23145861

54. Lawrence C, Willicombe M, Brookes PA, Santos–Nunez E, Bajaj R, Cook T, et al. Preformed complement-activating low–level donor-specific antibody predicts early antibody–mediated rejection in renal allografts. Transplantation. 2013;95: 341–346. doi: 10.1097/TP.0b013e3182743cfa 23197178

55. Crespo M, Torio A, Mas V, Redondo D, Pérez–Sáez MJ, Mir M, et al. Clinical relevance of pretransplant anti-HLA donor-specific antibodies: does C1q–fixation matter? Transpl Immunol. 2013;29: 28–33. doi: 10.1016/j.trim.2013.07.002 23907088

56. Freitas MCS, Rebellato LM, Ozawa M, Nguyen A, Sasaki N, Everly M, et al. The role of immunoglobulin–G subclasses and C1q in de novo HLA–DQ donor-specific antibody kidney transplantation outcomes. Transplantation. 2013;95: 1113–1119. doi: 10.1097/TP.0b013e3182888db6 23514959

57. Arnold M–L, Ntokou I–S, Doxiadis IIN, Spriewald BM, Boletis JN, Iniotaki AG. Donor-specific HLA antibodies: evaluating the risk for graft loss in renal transplant recipients with isotype switch from complement fixing IgG1/IgG3 to noncomplement fixing IgG2/IgG4 anti-HLA alloantibodies. Transpl Int. 2014;27: 253–61. doi: 10.1111/tri.12206 24118579

58. Everly MJ, Rebellato LM, Haisch CE, Briley KP, Bolin P, Kendrick WT, et al. Impact of IgM and IgG3 anti-HLA alloantibodies in primary renal allograft recipients. Transplantation. 2014;97: 494–501. doi: 10.1097/01.TP.0000441362.11232.48 24487396

59. Wozniak LJ, Hickey MJ, Venick RS, Vargas JH, Farmer DG, Busuttil RW, et al. Donor-specific HLA Antibodies Are Associated With Late Allograft Dysfunction After Pediatric Liver Transplantation. Transplantation. 2015;99: 1416–22. doi: 10.1097/TP.0000000000000796 26038872

60. Khovanova N, Daga S, Shaikhina T, Krishnan N, Jones J, Zehnder D, et al. Subclass analysis of donor HLA–specific IgG in antibody–incompatible renal transplantation reveals a significant association of IgG4 with rejection and graft failure. Transpl Int. 2015;28: 1405–1415. doi: 10.1111/tri.12648 26264744

61. Thammanichanond D, Wiwattanathum P, Mongkolsuk T, Kantachuvesiri S, Worawichawong S, Vallipakorn SA, et al. Role of Pretransplant Complement–fixing Donor-specific Antibodies Identified by C1q Assay in Kidney Transplantation. Transplant Proc. 2016;48: 756–760. doi: 10.1016/j.transproceed.2015.12.116 27234729

62. Yamamoto T, Watarai Y, Takeda A, Tsujita M, Hiramitsu T, Goto N, et al. De Novo Anti-HLA DSA Characteristics and Subclinical Antibody–Mediated Kidney Allograft Injury. Transplantation. 2016;100: 2194–2202. doi: 10.1097/TP.0000000000001012 26636737

63. Malheiro J, Tafulo S, Dias L, Martins LS, Fonseca I, Beirão I, et al. Determining donor-specific antibodies C1q–binding ability improves the prediction of antibody–mediated rejection in HLA–incompatible kidney transplantation. Transpl Int. 2017;30: 347–359. doi: 10.1111/tri.12873 27717025

64. Visentin J, Chartier A, Massara L, Linares G, Guidicelli G, Blanchard E, et al. Lung intragraft donor-specific antibodies as a risk factor for graft loss. J Heart Lung Transplant. 2016;35: 1418–1426. doi: 10.1016/j.healun.2016.06.010 27450460

65. Bamoulid J, Roodenburg A, Staeck O, Wu K, Rudolph B, Brakemeier S, et al. Clinical Outcome of Patients with De Novo C1q–Binding Donor-specific HLA Antibodies after Renal Transplantation: Transplantation. 2017;101: 2165–2174. doi: 10.1097/TP.0000000000001487 27653301

66. Moktefi A, Parisot J, Desvaux D, Canoui–Poitrine F, Brocheriou I, Peltier J, et al. C1q binding is not an independent risk factor for kidney allograft loss after an acute antibody–mediated rejection episode: a retrospective cohort study. Transpl Int. 2017;30: 277–287. doi: 10.1111/tri.12905 27992962

67. Sicard A, Meas–Yedid V, Rabeyrin M, Koenig A, Ducreux S, Dijoud F, et al. Computer–assisted topological analysis of renal allograft inflammation adds to risk evaluation at diagnosis of humoral rejection. Kidney Int. 2017;92: 214–226. doi: 10.1016/j.kint.2017.01.011 28318622

68. Das BB, Lacelle C, Zhang S, Gao A, Fixler D. Complement (C1q) Binding De Novo Donor Specific Antibodies and Cardiac–Allograft Vasculopathy in Pediatric Heart Transplant Recipients. Transplantation. 2018;102(3): 502–509. doi: 10.1097/TP.0000000000001944 28885488

69. Couchonnal E, Rivet C, Ducreux S, Dumortier J, Bosch A, Boillot O, et al. Deleterious impact of C3d–binding donor-specific anti-HLA antibodies after pediatric liver transplantation. Transpl Immunol. 2017;45: 8–14. doi: 10.1016/j.trim.2017.08.001 28782692

70. Bailly E, Anglicheau D, Blancho G, Gatault P, Vuiblet V, Chatelet V, et al. Prognostic Value of the Persistence of C1q–Binding Anti-HLA Antibodies in Acute Antibody–Mediated Rejection in Kidney Transplantation. Transplantation. 2018;102: 688–698. doi: 10.1097/TP.0000000000002002 29135832

71. Molina J, Navas A, Agüera M–L, Rodelo–Haad C, Alonso C, Rodríguez–Benot A, et al. Impact of Preformed Donor-specific Anti–Human Leukocyte Antigen Antibody C1q–Binding Ability on Kidney Allograft Outcome. Front Immunol. 2017;8: 1310. doi: 10.3389/fimmu.2017.01310 29163462

72. Global Observatory on Donation and Transplantation. [Cited 1 January 2018]. Available from: http://www.transplant-observatory.org/.

73. Tyan DB. Application, technical issues, and interpretation of C1q for graft outcome. Curr Opin Organ Transplant. 2017;22: 505–510. doi: 10.1097/MOT.0000000000000454 28723698

74. Tambur AR, Herrera ND, Haarberg KMK, Cusick MF, Gordon RA, Leventhal JR, et al. Assessing Antibody Strength: Comparison of MFI, C1q, and Titer Information. Am J Transplant. 2015;15: 2421–2430. doi: 10.1111/ajt.13295 25930984

75. Hönger G, Amico P, Arnold M–L, Spriewald BM, Schaub S. Effects of weak/non–complement–binding HLA antibodies on C1q–binding. HLA. 2017;90: 88–94. doi: 10.1111/tan.13062 28585289

76. Boekholdt SM, Arsenault BJ, Mora S, Pedersen TR, LaRosa JC, Nestel PJ, et al. Association of LDL cholesterol, non–HDL cholesterol, and apolipoprotein B levels with risk of cardiovascular events among patients treated with statins: a meta-analysis. JAMA. 2012;307: 1302–1309. doi: 10.1001/jama.2012.366 22453571

77. Zhang Y, Guan D–H, Bi R–X, Xie J, Yang C–H, Jiang Y–H. Prognostic value of microRNAs in gastric cancer: a meta-analysis. Oncotarget. 2017;6: 2849–2863. doi: 10.18632/oncotarget.18590

78. Kivimäki M, Kuosma E, Ferrie JE, Luukkonen R, Nyberg ST, Alfredsson L, et al. Overweight, obesity, and risk of cardiometabolic multimorbidity: pooled analysis of individual–level data for 120 813 adults from 16 cohort studies from the USA and Europe. Lancet Public Health. 2017;2: e277–e285. doi: 10.1016/S2468-2667(17)30074-9 28626830

79. Emerging Risk Factors Collaboration, Kaptoge S, Di Angelantonio E, Lowe G, Pepys MB, Thompson SG, et al. C–reactive protein concentration and risk of coronary heart disease, stroke, and mortality: an individual participant meta-analysis. Lancet. 2010;375: 132–140. doi: 10.1016/S0140-6736(09)61717-7 20031199

80. Vo AA, Zeevi A, Choi J, Cisneros K, Toyoda M, Kahwaji J, et al. A phase I/II placebo–controlled trial of C1–inhibitor for prevention of antibody–mediated rejection in HLA sensitized patients. Transplantation. 2015;99: 299–308. doi: 10.1097/TP.0000000000000592 25606785

81. Viglietti D, Gosset C, Loupy A, Deville L, Verine J, Zeevi A, et al. C1 Inhibitor in Acute Antibody–Mediated Rejection Nonresponsive to Conventional Therapy in Kidney Transplant Recipients: A Pilot Study. Am J Transplant. 2016;16: 1596–603. doi: 10.1111/ajt.13663 26693703

82. Jordan SC, Lorant T, Choi J, Kjellman C, Winstedt L, Bengtsson M, et al. IgG Endopeptidase in Highly Sensitized Patients Undergoing Transplantation. N Engl J Med. 2017;377: 442–453. doi: 10.1056/NEJMoa1612567 28767349

83. Kulkarni S, Kirkiles–Smith NC, Deng YH, Formica RN, Moeckel G, Broecker V, et al. Eculizumab Therapy for Chronic Antibody–Mediated Injury in Kidney Transplant Recipients: A Pilot Randomized Controlled Trial. Am J Transplant. 2017;17: 682–691. doi: 10.1111/ajt.14001 27501352

84. Lefaucheur C, Viglietti D, Hidalgo LG, Ratner LE, Bagnasco SM, Batal I, et al. Complement-activating Anti-HLA Antibodies in Kidney Transplantation: Allograft Gene Expression Profiling and Response to Treatment. J Am Soc Nephrol. 2018;29: 620–635. doi: 10.1681/ASN.2017050589 29042454

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Autoři: Prof. MUDr. Martin Haluzík, DrSc., prof. MUDr. Vojtěch Melenovský, CSc., prof. MUDr. Vladimír Tesař, DrSc.

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