Second transplants for multiple myeloma relapsing after a previous autotransplant-reduced-intensity allogeneic vs autologous transplantation.

There is no standard therapy for multiple myeloma relapsing after an autotransplant. We compared the outcomes of a second autotransplant (N=137) with those of an allotransplant (N=152) after non-myeloablative or reduced-intensity conditioning (NST/RIC) in 289 subjects reported to the CIBMTR from 1995 to 2008. NST/RIC recipients were younger (median age 53 vs 56 years; P<0.001) and had a shorter time to progression after their first autotransplant. Non-relapse mortality at 1-year post transplant was higher in the NST/RIC cohort, 13% (95% confidence interval (CI), 8-19) vs 2% (95% CI, 1-5, P0.001). Three-year PFS and OS for the NST/RIC cohort were 6% (95% CI, 3-10%) and 20% (95% CI, 14-27%). Similar outcomes for the autotransplant cohort were 12% (95% CI, 7-19%, P=0.038) and 46% (95% CI, 37-55%, P=0.001). In multivariate analyses, risk of death was higher in NST/RIC recipients (hazard ratio (HR) 2.38 (95% CI, 1.79-3.16), P<0.001), those with Karnofsky performance score<90 (HR 1.96 (95% CI, 1.47-2.62), P<0.001) and transplant before 2004 (HR 1.77 (95% CI, 1.34-2.35) P0.001). In conclusion, NST/RIC was associated with higher TRM and lower survival than an autotransplant. As disease status was not available for most allotransplant recipients, it is not possible to determine which type of transplant is superior after autotransplant failure.

INTRODUCTION

High-dose chemotherapy followed by autologous hematopoietic cell transplantation is widely used to treat persons with multiple myeloma (MM). However, there is no standard therapy for those who relapse [1, 2]. The outcome of those relapsing after autotransplantation and are also refractory to proteasome inhibitors and immunomodulatory agents is particularly poor [3]. Options for relapsed patients include clinical trials, second autotransplants or an allogeneic stem cell hematopoietic cell transplant. Because of the high morbidity and mortality associated with myeloablative allogeneic transplantation, lower intensity conditioning regimens such as non-myeloablative (NST) or reduced-intensity conditioning (RIC) allogeneic transplants [4] are more commonly used.

There are limited data on the outcomes of NST/RIC in persons with myeloma failing an autotransplant. We used the Center for International Blood and Marrow Transplant Research (CIBMTR) database to compare outcomes of a 2nd autotransplant versus NST/RIC allotransplantation in this setting.

PATIENTS AND METHODS

Data source

The CIBMTR is a voluntary working group of more than 450 transplantation centers worldwide that contribute detailed data on consecutive allogeneic and autologous transplants to a statistical center at the Medical College of Wisconsin. Participating centers are required to register all transplants consecutively; compliance is monitored by on-site audits. Patients are followed up longitudinally, with yearly follow-up. Computerized checks for errors, physicians’ review of submitted data, and on-site audits of participating centers ensure data quality. Observational studies conducted by the CIBMTR are performed with a waiver of informed consent and in compliance with Health Insurance Portability and Accountability Act regulations as determined by the institutional review board and the privacy officer of the Medical College of Wisconsin. All CIBMTR centers contribute to the registration data. Research data are collected on subset of registered patients and include detailed disease and pre-transplantation and post-transplantation clinical information.

Patients

The study population comprised of MM patients <65 years who had relapsed/progressed after prior autologous transplant and subsequently received NST/RIC allogeneic transplant or a 2nd autotransplant between 1995 and 2008. The age limit of 65 was used since most transplant centers would not perform full myeloablative allogeneic transplants in patients 65 or older.

Recipients of planned tandem transplants (n = 931) were excluded from the study. The following allogeneic transplant recipients were excluded: those receiving NST/RIC for graft failure (n = 15) or second malignancies (n = 4) as well as patients who received cord blood transplants (n = 2).

Definitions

The intensity of conditioning regimens was categorized as RIC or NST using established consensus criteria [5]. Previously established criteria for categorizing the degree of HLA matching were used for unrelated donor transplants [6].

Study Endpoints and statistical analysis

Primary outcomes were non-relapse mortality (NRM), progression/relapse, progression-free survival (PFS), and overall survival (OS) after the second transplant. NRM was defined as death from any cause within the first 28 days after transplantation or death thereafter in the absence of relapse/progression. Relapse/progression was defined according to the standard EBMT/IBMTR/ABMTR criteria. Probabilities of NRM and myeloma progression/relapse were calculated using cumulative incidence curves to accommodate competing risks [8, 9]. OS interval was defined as the time from second transplant to death from any cause. PFS interval was defined as the time from second transplant to relapse/progression or death from any cause whichever occurs first. Patients alive without evidence of disease relapse/progression were censored at last follow up. Probabilities of PFS and OS were calculated using the Kaplan-Meier product limit estimate. Other outcomes analyzed included acute and chronic graft versus-host disease (GVHD) and cause of death. Acute GVHD was defined and graded based on the pattern and severity of organ involvement using established criteria [7]. Chronic GVHD was defined as the development of any chronic GVHD based on clinical criteria. Both of these events were summarized by the corresponding cumulative incidence estimate, with death without development of GVHD as the competing risk.

Associations between patient-, disease-, and transplant-related factors and survival were assessed using multivariate Cox proportional hazards regression [10]. The variables considered in the multivariate analysis were: age (< 50 vs. ≥ 50), sex, Karnofsky performance score (KPS), Durie-Salmon (DS) stage, immunochemical subtype of MM, conditioning regimen for second transplant, interval from diagnosis to first transplant, interval from first transplant to relapse/progression, time interval from first to second transplant and the year of second transplant. Stepwise variable selection at a 0.05 significance level was used to identify covariates. In the model, the assumption of proportional hazards was tested for each variable using a time-dependent covariate and graphical methods. All variables considered in the multivariate analysis satisfied the proportionality assumption. All computations were made using the statistical package SAS version 9.1 (SAS Institute, Cary, NC).

RESULTS

Subject-, Disease-, and Transplant-Related Variables (Table 1)

Between 1995 and 2008, 152 subjects received NST/RIC (32 from HLA-identical siblings and 120 from HLA-matched unrelated donors) for relapsed/progressive MM after a prior autotransplant. 137 subjects received a 2nd autotransplant in the same setting. Median follow-up of NST/RIC survivors is 30 months (range, 2–98 months) and 29 months for patients who underwent a 2nd autotransplant (range, 3–97 months). The NST/RIC cohort was younger: median age, 53 years versus 56 years (p = 0.001). Gender distribution and Karnofsky performance score (KPS) were similar.

There was a higher proportion of pts with IgG MM in the autotransplantation cohort (p = 0.004). Stage at diagnosis was similar with 58% of patients in Durie-Salmon stage III in both cohorts.

As expected, conditioning regimens differed between cohorts. Most (85%) recipients of 2nd autotransplant received high-dose melphalan alone. Melphalan containing regimens were used in only 43% of the NST/RIC group. Only 4% of the autotransplant cohort received total body irradiation as part of their conditioning, in contrast to 29% of the NST/RIC.

The amount of missing myeloma related data—beta-2 microglobulin, albumin, and response status prior to 2nd transplant—between the two groups was strikingly different, with 25% of the NST/RIC patients having these data available. There was no meaningful way to compare the disease state prior to transplant in the 2 cohorts. Among autotransplant recipients 54 (39%) were in complete or partial remission where as 78% of the NST/RIC cohort had missing disease status data.

Median interval from diagnosis to first transplant was similar in both cohorts. In contrast, interval from 1st transplant to relapse/progression was significantly shorter in the NST/RIC cohort: 12 months (range, < 1–61 months) vs. 17 months (range, < 1–121 months; p = 0.009) in the autotransplant cohort. Interval from 1st to 2nd transplants was also shorter for the NST/RIC cohort, 23 months (range 6–78 months) versus 30 months (range, 6–122 months; p = 0.014). Between 1995 and 2000, comparable numbers of patients were salvaged with autotransplants and NST/RIC, but between 2001 and 2006, NST/RIC appeared to be favored, while from 2007–2008, the trend appeared to reverse itself, favoring autotransplantation. One-half of subjects receiving an autotransplant received maintenance therapy, but only 11% of the NST/RIC group was reported to receive maintenance; comparisons are again confounded by missing maintenance data for 58% of patients in the NST/RIC group.

Patient outcomes

Table 2 demonstrates unadjusted outcomes. Platelet engraftment at 28 and 60 days was inferior in the NST/RIC group. NRM (Figure 1) was 13% (95% CI, 8–19) at one year for subjects receiving NST/RIC versus 2% (95% CI, 1–5%) for AHCT recipients (p = < 0.001). Three-year probabilities of NRM were 14% (95% CI, 9–20) versus 4% (95% CI, 2–8; p ≤ 0.001). Relapse rates differed at 12 months, favoring the autotransplant group, but this difference did not persist long term (Figure 2). There was a trend toward better 5-year progression rates in the NST/RIC group. PFS results also favored the autotransplant group, with the most striking differences at 12 and 36 months (Figure 3). Finally, OS was far superior at all time points in the autotransplant group (Figure 4).

Table 2

Unadjusted univariate analysis

Outcomes	Autologous		NST/RIC		P-value
	N	Prob (95% CI)	N	Prob (95% CI)
Engraftment
ANC ≥ 500/mm3
@ 28 days	137	96 (92–98)	152	96 (93–98)	0.999
Platelets ≥ 20 × 109/L
@ 28 days	137	90 (84–94)	152	77 (70–83)	0.007*
@ 60 days	137	93 (89–97)	152	84 (78–89)	0.009*
Acute graft-versus-host disease
@ 30 days		NA	152	21 (15–28)	--
@ 60 days		NA		35 (28–43)	--
Chronic graft-versus-host disease
@ 12 months		NA	152	42 (34–50)	--
@ 36 months		NA		44 (36–52)	--
Relapse/Progression
@ 12 months	137	53 (44–61)	152	72 (64–79)	<0.001*
@ 36 months	137	84 (76–90)		80 (73–86)	0.655
@ 60 months	137	91 (85–96)		83 (77–89)	0.046*
Non-relapse mortality
@ 12 months	137	2 (1–5)	152	13 ( 8–19)	<0.001*
@ 36 months		4 (2–8)		14 ( 9–20)	<0.001*
@ 60 months		4 (2–8)		15 (10–21)	<0.001*
Progression free survival
@ 12 months	137	45 (37–54)	152	15 (10–21)	<0.001*
@ 36 months		12 (7–19)		6 ( 3–10)	0.038*
@ 60 months		4 (1–11)		2 (<1–5)	0.235
Overall survival
@ 100 days	137	97 (91–98)	152	77 (69–83)	<0.001*
@ 12 months		82 (75–88)		51 (42–58)	<0.001*
@ 36 months		46 (37–55)		20 (14–27)	<0.001*
@ 60 months		29 (20–40)		9 ( 5–15)	<0.001*

significant difference

NST/RIC = non-myeloablative stem cell transplant/reduced intensity conditioning

Figure 1

Non-relapsed mortality (NRM) after second hematological cell transplant by type of second transplant

This figure describes the cumulative incidence rate of NRM after second hematological cell transplant by type of second transplant, which are second salvage autologous transplant and allogeneic transplant

Figure 2

Relapse rate (REL) after second hematological cell transplant by type of second transplant

This figure describes the cumulative incidence rate of TRM after second hematological cell transplant by type of second transplant, which are second salvage autologous transplant and allogeneic transplant

Figure 3

Progression-free survival (PFS) after second hematological cell transplant by type of second transplant

This figure describes the probability estimates of PFS after second hematological cell transplant by type of second transplant, which are second salvage autologous transplant and allogeneic transplant

Figure 4

Overall survival (OS) after second hematological cell transplant by type of second transplant

This figure describes the probability estimates of OS after second hematological cell transplant by type of second transplant, which are second salvage autologous transplant and allogeneic transplant

The multivariate analyses were limited by the quality of data requested in the forms (insufficient cytogenetic and FISH data) and the quality of data provided for the patients in the NST/RIC group. Factors that affected overall mortality included NST/RIC (HR 2.38, 95%, CI, 1.79–3.16, p = <0.001), year of 2nd transplant (HR 0.57, 0.43–0.75, p = <0.001) for patients transplanted in later time periods, and functional status (HR1.96, 1.47–2.62, p = <0.001). In multivariate analyses (Table 3) allotransplants were associated with a higher risk of NRM (HR 7.14, 95% CI, 2.70–8.91; p = 0.001) and death (HR 2.38, 95% CI, 1.79 – 3.16; p < 0.001). Effect of therapy on treatment failure was only significant in subjects with Durie-Salmon stage III. In these patients, allotransplant is associated with a higher risk of relapse and treatment-failure compared to autotransplantation (HR 3.05, 95% CI, 2.20–4.22; p = 0.001).

Table 3

Multivariate Analysis

Factor	Level	N	HR	95% CI	P-value
OS
Main effect	Auto	137	1
	NST/RIC	152	2.38	(1.79 – 3.16)	<0.001
Year of 2nd transplant	1995–2004	148	1
	2005–2008	141	0.57	(0.43 – 0.75)	<0.001
Karnofsky score	≥ 90	144	1		0.001*
	<90	118	1.96	(1.47 – 2.62)	<0.001
	Missing	27	1.85	(1.14 – 3.01)	0.013
Treatment failure
Interactional effect between main effect and Durie-Salmon Stage	DS stage I–II, Auto	40	1
	DS stage I–II, NST/RIC	54	1.33	(0.87–2.02)	0.189
	DS stage III, Auto	80	1
	DS stage III, NST/RIC	88	3.05	(2.20–4.22)	<0.001
	DS missing, Auto	17	1
	DS missing, NST/RIC	10	1.53	(0.63–3.70)	0.344
Relapse
Interactional effect between main effect and Durie-Salmon Stage	DS stage I–II, Auto	40	1
	DS stage I–II, NST/RIC	54	1.16	(0.74–1.82)	0.518
	DS stage III, Auto	80	1
	DS stage III, NST/RIC	88	2.70	(1.93–3.80)	<0.001
	DS missing, Auto	17	1
	DS missing, NST/RIC	10	1.51	(0.59–3.83)	0.388
NRM
Main effect	Auto	137	1
	NST/RIC	152	7.14	(2.70–18.91)	<0.001

overall p-value

Auto = autotransplant

NST/RIC = non-myeloablative stem cell transplant/reduced intensity conditioning

DS = Durie-Salmon

NRM = non-relapse mortality

Patients who underwent NST/RIC from related and unrelated donors had a similar outcome. The PFS and OS were similar at 1, 3 and 5 years (data not shown). The 3-year OS of patients who underwent NST/RIC from related donors was 19% (95% CI, 7–33) compared to patients whose donors were unrelated, 21% (95% CI, 14–28; p = 0.82). The TRM was also similar irrespective of donor type (HR 1.077, 95% CI 0.75–1.54, p = 0.68).

DISCUSSION

The optimal therapy for patients with resistant or relapsed MM after autotransplantation remains unknown. The immunomodulatory agents and proteosome inhibitors have greatly expanded the therapeutic armamentarium against MM and many patients can benefit from additional therapy after autotransplant relapse. However, the disease eventually progress or patients develop unacceptable toxicities that limit these therapies. Since autotransplantation induces durable remissions with acceptable toxicity, a second autotransplant is also a consideration. Several studies have documented that this approach is feasible and transplant centers frequently harvest enough stem cells for two transplants in preparation for a second autotransplant upon MM progression or relapse [11-17]. Other investigators prefer the use of allogeneic transplantation because the graft is free of tumor and has the potential to induce a graft-versus-MM effect [18-28]. Since the morbidity and mortality associated with myeloablative allogeneic transplantation is high, most centers have relied on low-intensity conditioning NST/RIC. The aim of our study was to have a better understanding whether one type of transplant was favored for patients with relapse/refractory MM requiring salvage transplantation.

Our data demonstrate that patients who undergo autotransplantation rather than NST/RIC as their second transplant fare better across all measures including rates of progression. Major limitations of this study are the absence of cytogenetic data and a paucity of other prognostic factors available in the NST/RIC cohort. The autotransplant cohort was lower risk based on a longer time interval from 1st autotransplant to relapse.

If one compares these registry data to small series from individual institutions, our NRM is lower. The CIBMTR registry 1-year NRM for RIC/NST was 13% as compared to single institution reporting NRM varying from 11% to 26% [18-28]. An EBMTR analysis of large number of patients who underwent RIC/NST, most of them after autotransplant failure, reported a NRM of 22% [29]. Our results are remarkable when it is taken into consideration that 90% of the patients in this study underwent unrelated RIC/NST. Despite the lower NRM, both PFS and OS in the current study are lower than what has been reported in other studies: OS (24%–74%) and DFS (21%–61%) [18-28]. These differences may be in part a reflection of patient selection since most of these studies were from single institutions and had smaller numbers of patients.

The outcome of patients who underwent 2nd autotransplants in this study is similar to previously published reports despite the fact that we only included patients younger than 66 years of age [11-17].

In a biologic assignment trial comparing patients who underwent tandem autotransplants to patients who underwent autotransplants followed by NSC as their initial therapy for myeloma, the 3-year DFS and OS was similar. However, the NRM was higher in the autologous-NSC arm of the study, as observed in our study.

Our study has several strengths and limitations. Strengths include the large number of patients from multiple centers who contributed cases to this study over a long period of time, reflecting more accurately the practice of transplantation throughout this period. Limitations include the lack of information regarding prognostic factors including cytogenetics and International Staging System stage, information on maintenance therapy and the disease status at the time of alloHCT. With these caveats in mind, the conclusion from these data is that patients who undergo autotransplants as their second transplant fare better than NST/RIC across all measures including progression rates and NRM. Since disease status was not available for most allotransplant recipients, is not possible to determine which type of transplant is superior after autotransplant failure.

Table 1

Characteristics of patients who underwent second autologous, HLA-identical or unrelated non-myeloablative/reduced intensity conditioning transplantation as therapy for persistent or recurrent disease after autologous transplantation for Multiple Myeloma in North American, reported to CIBMTR between 1995 and 2008.

Characteristics of patients	Autologous	Allogeneic	P-value
Patients-related
Number of patients	137	152
Number of centers	54	65
Age at 2nd transplant, median (range), years	56 (28–65)	53(32–65)	0.001*
18–29	1 (<1)	0 (0)	0.039*
30–39	4 ( 3)	9 ( 6)
40–49	32 (23)	47 (31)
50–59	60 (44)	72 (47)
60–65	40 (29)	24 (16)
Gender
Male	84 (61)	90 (59)	0.720
Karnofsky score pre-transplant
≥90%	68 (50)	76 (50)	0.884
<90%	55 (40)	63 (41)
Missing	14 (10)	13 ( 9)
Disease-related
Immunochemical subtype of MM
IgG	67 (49)	63 (41)	0.004*
IgA	20 (15)	37 (24)
Light chain	26 (19)	36 (24)
Othersa	7 ( 5)	12 ( 8)
Missing	17 (12)	4 ( 3)
Durie-Salmon stage at diagnosis
Stage I	8 ( 6)	13 ( 9)	0.293
Stage II	32 (23)	41 (27)
Stage III	80 (58)	88 (58)
Missing	17 (13)	10 ( 7)
Percent of plasma cell prior to transplant	6 (1–95)	12 (1–95)	---
Evaluable	85 (62)	27 (18)
Albumin prior to transplant
<3.5 g/dL	44 (32)	12 (8)	---
≥3.5g/dL	88 (64)	20 (13)
Missing	5 ( 4)	120 (79)
β2-microglobulin level prior to transplant
<3.5 mg/L	63 (46)	19 (13)	---
≥3.5 mg/L	22 (16)	6 ( 4)
Missing	52 (38)	127 (84)
Transplant-related
Conditioning regimen
Melphalan alone	116 (85)	3 ( 2)	<0.001*
Melphalan + TBI ± others	4 ( 3)	7 ( 5)
Melphalan (no TBI) + others	11 ( 8)	58 (38)
TBI (no Melphalan) ± others	2 ( 1)	37 (24)
Busulfan + cyclophosphamide ± others	3 ( 2)	1 (<1)
Busulfan + fludarabine ± others	0 ( 0)	30 (20)
Cyclophosphamide + fludarabine ± others	0 ( 0)	16 (11)
Othersb	1 (<1)	0 (0)
Disease status prior 2nd transplant
CR/PR	54 (39)	1(<1)	<0.001*
MR/NR/SD	60 (44)	7 (5)
Relapse/progression	23 (17)	25 (16)
Missing	--	119 (78)
Graft type
Bone marrow	0 ( 0)	26 (17)	<0.001*
Peripheral blood	137(100)	126 (83)
Donor type
Related	--	32
Unrelated	--	120
Reason for 2nd transplant
Persistent malignancy	54 (39)	57 (38)	0.809
Recurrent malignancy	83 (61)	95 (62)
Donor age, years	NA	37 (19–78)	---
Donor-recipient sex match
Male-Male	NA	65 (43)	---
Male-Female	NA	25 (16)
Female-Male	NA	33 (22)
Female-Female	NA	29 (19)
GVHD prophylaxis
FK506+MTX ± other	NA	53 (35)	---
FK506 ± other	NA	41 (27)
MTX+CSA ± other	NA	9 ( 6)
CSA ± other	NA	49 (32)
RIC vs. Non-myeloablative
RIC	NA	111 (73)	---
Non-myeloablative	NA	41 (27)
Time from diagnosis to 1st transplant, median(range), months	7 (4–69)	8 (<1–119)	0.114
<12 months	102 (74)	110 (72)	0.790
≥12 months	35 (26)	42 (28)
Time from 1st transplant to relapse/progression, months	17 (<1–121)	12 (<1–61)	0.009*
<6 months	26 (19)	36 (24)	0.135
6–12 months	22 (16)	27 (18)
12–24 months	39 (28)	31 (20)
24–36 months	24 (18)	14 ( 9)
>36 months	26 (19)	17 (11)
Missing	0 ( 0)	27 (18)
Time from 1st to 2nd transplant, median(range), months	30 (6–122)	23 (6–78)	0.014*
12–24 months	44 (32)	78 (51)	0.001*
>24 months	93 (68)	74 (49)
Year of transplant
1995–1996	3 ( 2)	0 ( 0)	<0.001*
1997–1998	5 ( 4)	3 ( 2)
1999–2000	9 ( 7)	11 ( 7)
2001–2002	16 (12)	28 (18)
2003–2004	26 (19)	47 (31)
2005–2006	39 (28)	54 (36)
2007–2008	39 (28)	9 ( 6)
Post-transplant
Maintenance therapy
No	68 (50)	47 (31)	<0.001
Yes	69 (50)	17 (11)
Missing	0	88 (58)
DLI given
Yes	0	19 (13)	<0.001
No	137 (100)	133 (88)
Median follow-up of survivors (range), months	29 (3–97)	30 (12–98)

Abbreviations: TBI = total body irradiation; RIC = reduced intensity; conditioning; FK506 = tacrolimus; CSA = cyclosporine; MTX = methotrexate.

Follow-up completeness index as of 12/31/2009: @ 1year (96%), @ 3 year (92%), and @ 5 year 91%.

Other immunochemical subtype includes:

: non-secretory (n=5), IgD (n=1), and IgM (n=1)

: non-secretory (n=11), and IgD (n=1)

Others conditioning regimen

: CY+ARAC+ETOP+NITRO (n=1)