Is CA125 useful in monitoring patients with platinum-resistant ovarian cancer?

Patients with recurrent ovarian cancer are offered chemotherapy (CT) with the aim of improving survival and palliating symptoms. Due to the toxicity of therapy and expense particularly of biological therapy, treatment should only be continued if it is known to be effective. This requires regular monitoring during therapy to determine whether the cancer is responding or progressing. Providing patients are tolerating the therapy, it would normally be continued for a specified number of cycles or until it was shown to be ineffective. RECIST criteria, which rely upon serial measurements of tumour size by radiological imaging, are routinely used in clinical trials to define whether a tumour is responding if there is a decrease of ≥30% in unidimensional measurements, or progressing if ≥20% increase in unidimensional measurements, or development of new lesions [1]. There is great interest in determining whether CA125 is as reliable as RECIST in monitoring ovarian cancer as ovarian cancer can be difficult to accurately image and a blood test can be repeated more frequently than scans [2]. The Gynecological Cancer Intergroup (GCIG) agreed criteria based on serial changes in CA125 levels that could be used in clinical trials to define progression-free survival (PFS) after treatment of first line or recurrent disease, and to define response to treatment of recurrent disease [3]. The GCIG stated that there were no data to validate whether CA125 should be used to define response or progression in patients on maintenance or consolidation therapy. Lindemann et al. [4] have now retrospectively analysed the GCIG definition for progression in the Aurelia trial. This trial compared CT alone versus chemotherapy plus bevacizumab (BEV-CT) in patients with platinum-resistant ovarian cancer (PROC). To validate the use of CA125, the GCIG have previously analysed an end point such as response or PFS, and determined whether a similar trial result would have been found if PFS had been measured using either RECIST or CA125. In the original Aurelia publication, the objective response rate (ORR) according to RECIST alone in 287 patients was 11.8% versus 27.3% for CT and BEV-CT, respectively (P = 0.001) and according to GCIG CA125 criteria alone in 297 patients was 11.6% with CT versus 31.8% with BEV-CT (P < 0.001), indicating a consistent ORR response irrespective of the assessment method used [5]. The primary objective of the study by Lindemann et al. was to assess concordance between a modification of the GCIG CA 125 criteria and RECIST-defined progressive disease (PD), but not to validate the use of the GCIG CA125 criteria. This was not possible as they could not compare PFS according to RECIST with PFS according to CA125 criteria between the CT and BEV-CT arms in the Aurelia trial, as CA 125 results were not collected after RECIST-defined PD and 40% of patients in the CT arm received bevacizumab on progression. There were 218 patients with RECIST-defined PD and sufficient CA125 values out of 361 patients entered into Aurelia. Only 94 (42%) patients had concordant RECIST and CA125 PFS status, with a further 56 (26%) patients having rising CA125 levels which were not classified as PD by GCIG criteria. Patients without RECIST PD were excluded from formal analysis, but interestingly, 37 of 52 (71%) of those excluded patients who progressed had a CA125 confirmed progression. RECIST requires a 20% increase in unidimensional diameter while GCIG require a 50% increase in CA125 values to classify a patient’s tumour as progressing. One would therefore expect some patients with <20% increase in unidimensional diameter to have a >50% decrease in CA125, and some patients to have >20% increase in unidimensional diameter but <50% decrease in CA 125 levels. The timing of a declared PD by the two surrogate criteria is also likely to be different. Previous studies during follow-up after first-line CT showed that CA125 predicted PD some months before RECIST [6]. This was not shown in Aurelia probably because patients with PROC have a far shorter PFS, with most progressing according to RECIST while still on therapy when some cancer clones producing CA125 might still be responding. There were 42 patients (19%) who had falling CA125 levels at the time of RECIST PD. It is not recorded whether any of these had a fall in CA 125 sufficient to be classified as responding according to GCIG criteria. Again one would expect some patients to have fluctuating or even falling levels at the time of RECIST-defined PD as the latter is an arbitrary surrogate measure. Furthermore, we and others have noted that CA125 levels can fall in some terminally ill patients, which would include many with progressive platinum-resistant disease. As Bowtell’s group have observed several molecular events associated with acquired resistance of high-grade serous ovarian cancer, it would be no surprise if CA125 expression was also reduced in some patients under the selective pressure of CT [7]. There is increasing concern that therapy should not necessarily be stopped based purely on progression according to RECIST as particularly with biological therapies, the rate of tumour growth could still be slower on that therapy than if it was stopped [8]. Lindemann et al. correctly state that a major role of therapy in platinum-resistant disease is palliation of symptoms. The randomised trial data showing no benefit from earlier reintroduction of CT just because of rising CA125 levels should persuade oncologists to delay CT for recurrent ovarian cancer until they develop symptoms [6]. Most oncologists would use the palliation of those symptoms as a good guide to the effectiveness of the therapy. Better objective measurement of symptom control is also leading to an increasing interest in patient-reported outcomes (PROs) as an end point in clinical trials involving these patients [9]. The use ed ito ria ls editorials Annals of Oncology 27: 1365–1366, 2016 doi:10.1093/annonc/mdw253 Published online 29 June 2016