Poly(ADP-Ribose) Polymerase Inhibitors in Pancreatic Cancer: A New Treatment Paradigms and Future Implications
Abstract
:1. Introduction
2. Mechanism of Action of PARP Inhibitors
2.1. Repair Mechanisms in Healthy Cells
2.2. BRCA Deficiency
2.3. DNA Repair with BRCA-Deficient Cells in the Presence of PARPi
2.4. PARPi Pharmacology
2.5. Clinical Development of PARPi in PDAC
2.6. PARPi as Monotherapy in Advanced Disease
2.7. PARPi as Maintenance Therapy in Platinum-Sensitive Disease
3. PARPi in Combination with Other Therapies
3.1. PARP in Combination with Chemotherapy
3.2. PARP in Combination with Radiotherapy
3.3. PARPi in Combination with Immunotherapy
3.4. Molecular Targeted Therapy Combinations
4. Resistance Mechanisms
5. Discussion
6. Conclusions
Author Contributions
Funding
Conflicts of Interest
References
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Agent | # Potency for PARP Trapping | Mono Therapy Dose | Toxicities * | FDA Approvals ∫ | |
---|---|---|---|---|---|
Any (%) | Grade >/3 (%) | ||||
Olaparib | ++ | 300 mg PO BID | Any 96% Fatigue 60% Nausea 45% Anemia 27% Abd pain 29% Diarrhea 29% Anorexia 25% Constipation 23% | Any 40% Fatigue 5% Anemia 11% Abd pain 2% Anorexia 3Vomiting 1% Arthralgia 1% | -2014: gBRCA mutation positive ovarian cancer in 4th line of therapy. ORR of 34%, PFS of 6.7 mo [56] -2017: Maintenance post-recurrence in ovarian, primary peritoneal or fallopian tube carcinoma with CR or PR after platinum-based chemotherapy irrespective of BRCA status. PFS: olaparib (19 mo) vs. placebo (5.5 mo), HR 0.3, p < 0.0001) [57,58] -2018: Front-line maintenance in gBRCA or sBRCA mutation positive ovarian or primary peritoneal or fallopian tube carcinoma with CR or PR after platinum-based chemotherapy. 3-yr OS: olaparib (84%) vs placebo (80%), HR 0.95 (95% CI 0.6–1.53) [59] -2018: gBRCA mutation positive, Her-2 negative metastatic breast cancer </2 lines of therapy. PFS: olaparib (7 mo) vs std Rx (4 mo), HR 0.58 (p < 0.001); OS: olaparib (19.3 mo) vs. standard therapy (19.6mo), HR 0.9 (p = 0.57) [60] |
Rucaparib | ++ | 600 mg PO BID | Any 100% Nausea 75% Fatigue 69% Dysgeusia 39% Anemia 37% Constipation, Vomiting 37% Transaminitis 34% Diarrhea 32% Abd pain 30% Thrombocytopenia 28% | Any 48% Anemia 18% Asthenia 7% Neutropenia 5% Thrombocytopenia 3% Transaminitis 10% Nausea, Vomiting 4% Abd pain, Diarrhea, Anorexia, Arthralgia 1% | -2016: gBRCA or sBRCA mutation positive ovarian cancer after >/2 lines of therapy. PFS: BRCA mutation positive (13 mo), LOH high (6 mo), LOH low (5.2mo) [61,62] -2018: Maintenance post-recurrence in ovarian or primary peritoneal or fallopian tube carcinoma with CR or PR after platinum-based chemotherapy PFS: rucaparib (17mo) vs placebo (5 mo), HR 0.23 (p < 0.0001) [63] |
Veliparib | + | 400 mg PO BID | Nausea 43% Vomiting 29% Anemia 24% Leukopenia 20% Thrombocytopenia 9% | ||
Niraparib | +++ | 300 mg PO QD | Nausea 74% Thrombocytopenia 61% Fatigue 59% Anemia 50% Constipation 40% Vomiting 34% Neutropenia 30% Headache 26% Anorexia 25% Insomnia 24% Abd pain 23% | Thrombocytopenia 34% Anemia 25% Neutropenia 20% Fatigue 8% Nausea 3% Hypertension 8% Vomiting 2% Abd pain, Dyspnea 1% | -2017: Maintenance post-recurrence in ovarian or primary peritoneal or fallopian tube carcinoma with CR or PR after platinum-based chemotherapy. PFS: niraparib (21mo) vs placebo (5.5 mo), HR 0.27 (95% CI 0.17–0.41) [64] |
Talazoparib | ++++ | 1 mg PO QD | Anemia 53% Fatigue 50% Nausea 49% Headache 32% Neutropenia 35% Thrombocytopenia 27% Vomiting 25% | Anemia 39% Neutropenia 18% Thrombocytopenia 11% Leukopenia 6% Lymphopenia 3% Fatigue, Headache, Vomiting, back pain, dyspnea 2% | -2018: gBRCA mutation, Her-2 negative metastatic breast cancer </3 lines of therapy. PFS: talazoparib (8.6mo) vs placebo (5.6 mo), HR 0.54; p < 0.001. Interim OS HR 0.76 (95% CI 0.55–1.06, p = 0.11) [65] |
Pamiparib | 60 mg PO BID | Nausea 50% Fatigue 33% Anemia 20% Vomiting 15% Neutropenia 13% | Anemia 13% Neutropenia 8% Fatigue 5% | No FDA approved indications yet |
Clinical Study | Phase | Patient Population | Intervention | Outcome | ADEs |
---|---|---|---|---|---|
PARPi as Monotherapy | |||||
NCT01078662 Kauffman et al. [56] | II | gBRCA1/2 mutation positive advanced recurrent cancers, PDAC cohort with progression on gemcitabine (65% prior platinum-based regimen) | Single arm olaparib 400mg PO BID | PEP: ORR (PDAC cohort) 22% SEP: Stable disease at > 8 weeks 35%, DOR 134 days, PFS 4.6 mo, OS 9.8 mo | Any grade: Fatigue (74%), Nausea (48%), Vomiting, Anemia (40%) Grade >/3: Anemia (17%) Fatigue (13%) |
NCT02042378 Shroff et al. [70] | II | sBRCA1/2 or gBRCA1/2 mutation positive advanced PDAC, 1–2 prior lines of therapy, prior platinum exposure in 79% pts, platinum refractory disease in 42% patients | Single arm rucaparib 600 mg BID | PEP: ORR 16% (3/19, 1CR and 2PR), SEP: DCR 32%, 44% with 1 prior line of therapy | Any grade: Nausea (63%) Anemia (47%), Abdominal pain, fatigue (37%) Grade >/3: Anemia (32%) Fatigue, Ascites (16%) Nausea, abdominal pain, increased AST, ALT (10%) |
Lowery et al. [71] | II | gBRCA1/2 or PALB2 mutation positive advanced PDAC patients, prior 1–2 lines of therapies (88% prior platinum-based regimen, 64% of these pts had PD on platinum-based regimen) | Single arm veliparib 300mg BID PO (n = 3), 400 mg BID (n = 15) | PEP: ORR-No CR or PR, Stable disease 25% pts at 8 weeks SEP: PFS 1.7 mo, OS 3.1 mo | Fatigue (25%) Elevated bilirubin (19%) Thrombocytopenia, dehydration, increased alkaline phosphatase (13%) |
NCT02677038, NCT02511223 Golan et al. [72] | II | Advanced PDAC, >/1 lines of therapy with BRCAness phenotype | Single arm olaparib PO BID | PEP: ORR Israel-5SD, 12 PD; U.S.-2PR, 6 SD, 3 PD SEP: PFS-14 wks (Israel) and 25 wks (U.S.) | Grade 1–2 anemia, fatigue, nausea |
PARPi as Maintenance Therapy | |||||
NCT02184195, Golan et al. [66] | III | gBRCA1/2 mutation positive, mPDAC, non-progressive disease during first line platinum-based therapy for at least 16 weeks | 3:2 randomization to olaparib versus placebo | PEP: PFS-7.4 mo vs 3.8 mo (HR 0.53, p = 0.004) SEP: OS (46% data maturity)-19 mo vs. 18 mo (p = 0.7), no difference in HrQOL scores | Any grade: Olaparib vs. placebo (96% vs. 93%), Fatigue (60% vs. 35%), nausea (45% vs. 23%), abdominal pain (29% vs. 25%), anemia (27% vs. 17%) Grade >/3: Olaparib vs placebo (40% vs. 23%) Anemia (11% vs. 3%) Fatigue (5% vs. 2%) Abdominal pain (2% each) |
NCT 03140670, Binder et al. [73] | II | gBRCA1/2, gPALB2, sBRCA1/2, or sPALB2 mutation positive advanced PDAC, non-progressive disease during first line platinum-based therapy for at least 16 weeks | Single arm rucaparib 600mg PO BID | PEP: PFS Prelim data (19/24 pts enrolled, 42 planned) -mPFS of 9 mo SEP: ORR 37% (1CR, 6 PRs), DCR-90% for at least 8 weeks | Most common (grade 1,2): Nausea (46%) Dysgeusia (33%) Fatigue (25%) No grade 3 ADEs |
PARP in combination with chemotherapy | |||||
NCT02890355, Chiorean et al. [74] | II | mPDAC, second line therapy with (1st line Rx with non-irinotecan-based therapy), 9% (11/123) pts with HRD (4 germline BRCA1/2, ATM; 7 somatic BCRA2, PALB2, ATM, CDK12), 20% (24/123) pts with DDR, non HRD mutations | 1:1 randomization to either veliparib + FOLFIRI vs FOLFIRI alone | Planned interim futility analysis at 35% PFS events PEP: OS 5.1 vs. 5.9 mo (HR 1.3, p = 0.2) SEP: PFS 2 mo vs. 3 mo (HR 1.5, p = 0.05) | Most common Grade >/3 ADEs: Veliparib + mFOLFIRI vs FOLFIRI Neutropenia (33% vs. 20%) Fatigue (19% vs. 4%) Nausea (11% vs. 4%) |
NCT01489865, Pishvaian et al. [75] | I/II | mPDAC pts, phase I (31 pts), phase II (33pts). Phase II pts preselected for germline or somatic BRCA1/2, PALB2 mutations (27%) or FH of breast /ovarian syndrome (69%); both previously treated (18/33) and untreated (15/33) | Veliparib + mFOLFOX6 | 57/64 pts evaluable PEP: ORR-26% all pts, 58% in pts with +FH, +DDR, platinum naïve (12 pts) SEP: OS 8.5 mo, PFS 3.7 mo | Grade >/3: Myelosuppression (16%) Nausea, vomiting (6%) |
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Gupta, M.; Iyer, R.; Fountzilas, C. Poly(ADP-Ribose) Polymerase Inhibitors in Pancreatic Cancer: A New Treatment Paradigms and Future Implications. Cancers 2019, 11, 1980. https://doi.org/10.3390/cancers11121980
Gupta M, Iyer R, Fountzilas C. Poly(ADP-Ribose) Polymerase Inhibitors in Pancreatic Cancer: A New Treatment Paradigms and Future Implications. Cancers. 2019; 11(12):1980. https://doi.org/10.3390/cancers11121980
Chicago/Turabian StyleGupta, Medhavi, Renuka Iyer, and Christos Fountzilas. 2019. "Poly(ADP-Ribose) Polymerase Inhibitors in Pancreatic Cancer: A New Treatment Paradigms and Future Implications" Cancers 11, no. 12: 1980. https://doi.org/10.3390/cancers11121980
APA StyleGupta, M., Iyer, R., & Fountzilas, C. (2019). Poly(ADP-Ribose) Polymerase Inhibitors in Pancreatic Cancer: A New Treatment Paradigms and Future Implications. Cancers, 11(12), 1980. https://doi.org/10.3390/cancers11121980