Long-Term Risk of Cancer in Survivors of Pediatric ESRD

Discussion

This study provides the longest complete follow-up of a cohort of patients with pediatric ESRD to date. We found an incidence of at least one malignancy of 41% in patients who survived and had 30 years of follow-up starting from first transplantation, the majority being NMSC and lymphoproliferative disorders. Malignancies recurred frequently; 31% of patients with cancer developed a second de novo malignancy within 1 year. Compared with the Dutch GP, the risk of developing a malignancy in this cohort was >20-fold higher. Malignancies contributed to a significant proportion of overall mortality (12.6%).

The IRR of all malignancies in our cohort was almost 22 (IRR, 21.7; 95% CI, 17.3 to 27.2) times higher than that in the GP. This number is higher than that seen in earlier adult studies, which consistently report a 3- to 7-fold increased incidence in patients with ESRD (4,5,11,12,14). This could be explained by the fact that our study is on the basis of a nationwide cohort with an exceptionally long period of follow-up. Our cohort was exposed to RRT and immunosuppression from childhood onward, and this may have led to an exponential growth in malignancies. Our results show that, after 20 years of transplantation, the incidence abruptly increases, confirming our hypothesis. However, it is not known how generalizable these results are to other populations, because these patients are mostly older and have a shorter time of follow-up.

Cumulative incidence competing risk analysis showed that the probability of death after 30 years of follow-up from first transplantation is 31% (Figure 1A). It is also showed a cumulative incidence of 41% after 30 years after first transplantation (Figure 1B). Figure 1B can be used to explain the risk of developing a malignancy, because the deceased patients are excluded. Therefore, if a patient is still alive after 30 years of follow-up, the chance of developing a malignancy in those past 30 years is 41%. This increased incidence of malignancies is associated with the use of immunosuppression. The presumed pathophysiology is that such agents impair the ability to locate and destroy cancer cells as well as control viral infections that are potentially oncogenic (6). Consequently, types of cancer with the highest standardized IRRs after organ transplantation with immunosuppression are those that are related to infection. Immunosuppression may enable different viruses to become carcinogenic (i.e., post–transplant lymphoproliferative disorder, Kaposi sarcoma, and anogenital dysplasias) or prevent repair of affected cells in areas exposed to solar radiation (i.e., skin cancer and head and neck cancers).

In a previous study, we showed an early effect on the occurrence of malignancy of cyclophosphamide. This effect had disappeared in 2010. An explanation might be that cyclophosphamide was only given in the early years of starting RRT and most often before the start of RRT. After 1990, cyclophosphamide was no longer used for outpatients.

Another problem that we faced while trying to analyze the effect of specific immunosuppressive therapy was the change over time in immunosuppressive regiments. In the 1970s and early 1980s, patients only received azathioprine and prednisolone as standard surveillance immunosuppressive medication. In the late 1980s, this was switched to cyclosporin and prednisolone, and by the middle 1990s, it was changed to triple therapy of cyclosporin, azathioprine, and prednisolone. In the early 2000s, this regime was gradually replaced with the combination of tacrolimus, prednisolone, and mycophenolate mofetil. From 2004 on, this was combined with anti–IL-2 induction therapy. These switches of immunosuppressive medication over the last 10–15 years seemed to be a major hurdle in the analysis of the specific effect of the various immunosuppressive regimes.

Nevertheless, the fact that we found such a high effect of long–lasting, relatively mild immunosuppressive therapy to current standards implies that the risk of cancer will certainly be even greater in children who are currently transplanted.

There is discussion in the literature as to what extent being on dialysis may contribute to the increased risk of cancer compared with transplantation (15). There are several insuperable hurdles that make investigation of the effect of dialysis on cancer occurrence virtually impossible. An increase in risk of cancer will only occur after a certain exposure time of the risk factor. All physicians will try to shorten dialysis time in children and young adults as much as possible. As a consequence, the average overall time on dialysis in young patients on RRT is relatively short. Those children who are forced to stay on dialysis for a relatively long period are at extremely high risk for early death caused by cardiovascular disease long before they may develop cancer. This practice is illustrated by the course of the patients in our cohort. Of the total RRT time, our patients spent six times as much time with a functioning graft as on dialysis.

The most important cancer registered in this study is cSCC. Many of the other more deadly cancers, especially lymfoproliferative disorders, occurred earlier and have killed some of the recipients of transplants, and therefore, cutaneous cancer, which has low mortality, was what was left behind. The incidence of cSCC was 744 times as high as that in the age-matched population. This outnumbers previous reports, which confirm NMSC and virus-related cancers to be the predominant types of cancers found in patients with transplants (3–5,10–12). Studies that have included NMSC have found a 3- to 5-fold increased risk for all cancers and 13- to 222-fold increased risk for NMSC after transplantation (4,9–12,16). Because these reports concern adult recipients, the total exposure time is far less than the exposure time in the LERIC Study cohort. Studies done in the Dutch population of adult recipients of kidney transplants found a lower IR of squamous cell carcinoma (SCC) than that presented in this paper (17). As mentioned above, the discrepancy between the results is because of the fact that the LERIC Study cohort is an unique cohort with an exceptionally long exposure to immunosuppressive agents and RRT.

In contrast to the GP (13), the incidence of cSCC in this patient population exceeded that of BCC. The cSCC incidence was nearly two times that of BCC. Earlier studies also described a reversed ratio of BCC to cSCC with the GP, in which BCC is the most common one. The predominance of SCC over BCC is more pronounced in pediatric than in adult recipients of transplants (SCC:BCC is 2.8:1 versus 1.7:1) (18). Ultraviolet (UV) exposure and human papilloma virus (HPV) combined with immunosuppression are thought to be the most important causative factors for the development of post-transplant cSCC. UV radiation is probably one of the most important factors (19). This would explain the extremely high incidence of cSCC in Australia, a country with a majority of genetically ill–protected white people and a very high sun exposure; there is 93% skin cancer among all post-transplant malignancies (20). Sun protection is, therefore, of utmost importance. cSCC may appear in the absence of any preexisting skin lesion but is often preceded by actinic keratosis, which could mean some involvement of HPV in its pathogenesis. There is, however, no conclusive evidence regarding the causal role of HPV in actinic keratosis at this time. Additional evidence for the role of HPV comes from a study on post-transplant SCC that occurred in a cohort of 500 recipients of allografts; HPV DNA could be detected in nearly 50% of all SCCs (21–23).

Malignancies recurred often; 31% of the patients had a second de novo malignancy within 1 year (Figure 1C). Figure 1D can be used to explain the risk of developing a second de novo cancer (i.e., if a patient developed cancer, the chance of a de novo malignancy within 4 years is 54%). This number emphasizes the need for regular follow-up.

Most of them were NMSC, one was a leiomyosarcoma, and two were MM. Although in most patients, it is not lethal at the time of investigation, NMSC (especially cSCC) tended to recur very often within a short interlude. Some patients seemed more susceptible for multiple reoccurrences or distant metastasis of NMSC than others. One patient was diagnosed 12 times with NMSC. Eventually, two patients died because of metastases of cSCCs. Unfortunately, we had no information on potential risk factors, such as HPV status and the extent of UV exposure (24). Previous studies in adult transplantation confirm that post-transplant cSCC tends to be far more aggressive than that in the GP.

As we continue to improve the life expectancy of our patients by better cardiovascular risk management and prevention of infection, we elongate the exposure on RRT. With longer exposure, the risk of malignancy will increase. The follow-up in our patient cohort may be too short to fully appreciate its final effect on mortality, and therefore, additional research must be conducted.

This long–term follow-up study of late effects of renal insufficiency in children shows a cumulative cancer incidence of 41% after 30 years post-transplantation. cSCC occurs, by far, most frequently, occurs relatively late after transplantation, and tends to recur frequently. Although in most patients, it is not lethal at short follow-up, the high recurrence rate may affect the outcome on the longer term. Moreover, the chronicity of the disease may have an important negative effect on quality of life because of frequent hospital visits, excisions, and cosmetic consequences. Additionally, the threat of becoming a lethal disease is always present.

We, therefore, advise that all risk factors concerning skin cancer must be reduced. The most important risk factor is sunburn at an early age. This reduction could take place through education, parental role modeling, and sunscreen vigilance.