Radionuclide Therapy of Bone Metastases: Past, Present, Future
Andrei Iagaru, MD Sep 19th, 2013 MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Prostate Cancer Clinical States
Non-metastatic, Non- Hormone-responsive metastatic >200,000 60,000 Prostate cancer CRPC Clinically Biochemically Localized Relapsed Prostate cancer Prostate cancer >30,000
Prostatectomy Salvage Metastatic, Metastatic Chemo-refractory Radiation ± ADT Radiation Hormone-responsive Brachytherapy CRPC CRPC Primary ADT Prostate cancer Active Surveillance
Prostate cancer- specific death Death from co-morbidities
10 - 15 years + MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Progress in Prostate Cancer
1941 1976 1980 1996 2004 2010 2011 2012
ADVANCED PROSTATE CANCER
Docetaxel AA abiraterone Orchiectomy Zoledronic acid Mitoxantrone LHRH Cabazitaxel Enzalutamide Sipuleucel-T Radium 223 Denosumab MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Spectrum of Bone Disease in Prostate Cancer Treatment-Related Disease-Related New Bone Metastases Fractures Skeletal Complications
Castrate sensitive, Castrate resistant, Castrate resistant, nonmetastatic nonmetastatic metastatic MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Ketoconazole Provenge Taxotere Cabazitaxel Nilutamide Abiraterone Enzalutamide Estrogens Alpharadin
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology 85Sr (circa 1966) 18F (circa 1970) 87mSr (circa 1974) 99mTc (circa 1974)
Skeletal Nuclear Medicine. Collier, Fogelman, Rosenthall. 1995
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology 99mTc MDP
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology 0-5 min
10-15 min
25-30 min
40-45 min
Dynamic 18F NaF PET Diagnostic 18F NaF PET
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology DJD Single metastasis Multiple metastases
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Ø Introduction
Ø Past
Ø Present
Ø Future
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Targeted
Radionuclide
Therapy
MIPS Stanford Molecular Imaging Program at Stanford School of Medicine, Department of Radiology Targeted
Radionuclide
Therapy à Treatment of benign or malignant lesions
MIPS Stanford Molecular Imaging Program at Stanford School of Medicine, Department of Radiology Targeted
Radionuclide à Use of radiation to destroy lesions
Therapy à Treatment of benign or malignant lesions
MIPS Stanford Molecular Imaging Program at Stanford School of Medicine, Department of Radiology Targeted à Delivery of radiation to specific tissue
Radionuclide à Use of radiation to destroy lesions
Therapy à Treatment of benign or malignant lesions
MIPS Stanford Molecular Imaging Program at Stanford School of Medicine, Department of Radiology Targeted Radionuclide Therapy
Katie Walker, Lawrence Livermore National Lab
MIPS Stanford Molecular Imaging Program at Stanford School of Medicine, Department of Radiology Choice of Carrier
Radiotherapy and Oncology 2003. 66(2): 107-117 MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Nuclear Medicine: Therapy The ideal agent for painful bone metastases:
ü More uptake in lesions than normal bone ü Distribution predicted by Tc-99m MDP scan ü Rapid clearance from remainder of body ü Long half life ü Beta energy >0.8 MeV - < 2.0 MeV ü Easy to produce ü Cost reasonable
McEwan. Cancer Biother Radiopharmaceut 1998;13:413
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Nuclear Medicine: Therapy
Radiopharmaceuticals
Radionuclide T½ MaxB (Mev) Max Range (mm) 89Sr 50.5 1.46 6.7 32P 14.3 1.71 8 153Sm 1.95 0.8 3.4
186Re HEDP 3.8 1.07 4.7
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Ø Introduction
Ø Past
Ø Present
Ø Future
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Past: 32P Sodium Phosphate
Ø Careful, do not confuse with 32P Chromic Phosphate (used for intracavitary administration)
Ø 32P Sodium Phosphate is for i.v. administration
Ø FDA-approved prior to Jan 1, 1982 for Mallinckrodt
Ø It is usually not administered for the treatment of bone metastases when the leukocyte count is below 5,000/ cu mm and platelet count is below 100,000/cu mm
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Ø Marketed by Anazao Health since June 2012
Ø Very infrequently used for painful bone metastases Ø There is perception that bone marrow suppression is more common than with other radiopharmaceuticals
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology
Ø Bound to hydoxyapatite
Ø Excretion mainly renal
Ø Main use in hematological diseases ü Throbocythemia ü Polycythemia vera
Ø Historically used for bone metastases and leukemia
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Ø Introduction
Ø Past Ø Present
Ø Future
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Present: 89Sr (Metastron®)
Ø Pure beta emitter Ø Half-life 50.5 days Ø Calcium analogue Ø 85Sr and 87mSr produce scans similar to 99mTc MDP scans Ø Excretion mostly renal
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Present: 89Sr (Metastron®)
Ø 4 mCi fixed dose
Ø FDA-approved in Jun, 1993 for Amersham Health (now GE Healthcare)
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Present: 153Sm (Quadramet®)
Ø Complex decay Ø Beta has maximum energy of 0.81 keV Ø Half-life 1.95 days Ø Gamma photon (103 keV) can be used for imaging Ø Excretion mostly renal
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology 99mTc MDP 153Sm
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Present: 153Sm (Quadramet®)
Ø 1 mCi/Kg
Ø FDA-approved in March 1997 for DuPont Merck Ø Now marketed by Jazz Pharmaceuticals in the US and IBA worldwide
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Contraindications:
Ø White count <2,500 Ø Platelet count <60,000 (higher if falling) Ø Impending cord compression Ø Impending pathological fracture Ø Disseminated coagulapathy Ø Extensive soft tissue metastases Ø Death imminent (life expectancy should be > 3-6 months) Ø Within 1 month of myelosuppressive chemotherapy
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Methods:
Ø Review indications and requirements Ø Discussion with patient Ø Discussion with referring physicians Ø Radiation safety issues Ø Follow-up arrangements Ø Complications Ø Re-treatment
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Check list:
Ø Proven bone metastases Ø Objective evidence of referral for therapy Ø Complete blood count Ø Recent bone scan Ø Signed consent form Ø Appropriate continuity of care, including blood counts
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Nuclear Medicine: Therapy
Dates No of papers No of patients %Responding 1974-83 9 190 77 (42-90) 1985-96 18 962 74 (45-91)
About 20% can stop analgesics A proportion have a worsening before improvement
After McEwan Semin Nucl Med 1997
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Ø 50 males with prostate carcinoma and 26 females with breast cancer were treated Ø Good response in 64%, partial in 25%, and no response in the remaining 11% with prostate cancer Ø Good response in 62%, partial in 31%, and no response in the remaining 8% with breast cancer Ø Duration of the response: 3 - 12 months (mean 6 months) Ø Retreatment was as effective Ø A decrease in the initial leucocyte and platelet counts after the 1st month of treatment, with a gradual recovery within 6 months
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Ø Palliative treatment was given to 131 patients in the form of local radiotherapy (n=10), 89Sr (n=46) or i.v. olpadronate (n=66) Ø The incidence of SCC was 17% in the whole group, and highest in controls receiving no palliation (50%) Ø None of the patients treated with local radiotherapy, only 4% of patients receiving 89Sr and 21% of patients given olpadronate developed this complication
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Ø 64 patients with painful bone metastases treated with 153Sm were retrospectively evaluated Ø The most common primaries were breast in 28 cases (44%) and prostate in 27 (41%) Ø The response rate was 85% (21% complete, 40% moderate, and 24% minor) Ø Onset of improvement took place a median of 7 days after 153Sm administration, and pain relief persisted for a mean of 3 months Ø Myelotoxicity appeared in 29% of the administrations
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Ø 43 prostate cancer patients with bone metastases were given consolidation docetaxel 20 mg/m(2)/wk for 6 weeks and 153Sm (37 MBq/kg) during week 1 Ø A PSA response was obtained in 77% (95% CI, 61% to 82%) Ø The pain response rate was 69% (95% CI, 49% to 85%) Ø Although a serum PSA relapse eventually occurred in all patient cases, this regimen resulted in pain control in the long-term
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Ø 60 male patients with advanced prostate carcinoma and 40 female patients with advanced breast carcinoma Ø 30 men and 20 women were treated with 89Sr Ø 30 men and 20 women were treated with 153Sm Ø Complete pain relief was found in 40% of women and 40% of men treated using 153Sm and in 25% of women and 33% of men treated with 89Sr Ø No analgesic effect occurred in 20% of patients Ø A better analgesic effect was found in cases of osteoblastic metastases compared to mixed metastases
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Ø 48 patients with solid tumors who failed multi-agent chemotherapy were investigated Ø In patients who received 153Sm, there is a spike in FL* concentration at approximately 3 weeks after dose administration preceding a decrease in WBC and PLT counts Ø A spike in FL levels in patients who received 89Sr therapy is noted at approximately 10 weeks (p < 0.034) Ø Changes associated with 153Sm therapy occurred earlier and returned to control levels more rapidly than did those in patients similarly treated with 89Sr
*FL = plasma flt3 ((FMS (Friend murine strain))-like tyrosine kinase 3)-ligand cytokine
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Ø Aim: to estimate the cost of medical care for patients on 89Sr as adjunct therapy in patients with prostate cancer metastatic to bone and to compare the costs of those receiving 89Sr with those receiving placebo Ø The group receiving 89Sr had a lifetime reduction of $1,720 per person when compared with placebo Ø A reduction of $5,696 per patient in the 89Sr group was shown based upon requirements for admission for tertiary care
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Ø Introduction
Ø Past
Ø Present
Ø Future
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Future: 223Ra (Alpharadin®)
Ø Complex decay scheme, including mostly alpha, but also beta and gamma Ø Half life of 11.4 days Ø Excretion mostly renal, but also through the GI tract Ø Very short range and therefore causes less damage to surrounding tissues than other radiopharmaceuticals
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Future: 223Ra (Alpharadin®)
Ø 50 kBq/kg
Ø Developed in Norway by Algeta, approved in Europe Ø Marketed by Bayer Healthcare
MIPS Stanford Molecular Imaging Program at Stanford School of Medicine, Department of Radiology MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Future: 223Ra (Alpharadin®)
Cancer Manag Res. 2013; 5: 1–14.
Ø Self-targets to bone metastases by virtue of its properties as a calcium-mimic
MIPS Stanford Molecular Imaging Program at Stanford School of Medicine, Department of Radiology Cancer Manag Res. 2013; 5: 1–14
Decay of 223Ra: Ø 95.3% emitted as α particles Ø 3.6% emitted as β particles Ø 1.1% emitted as photons
MIPS Stanford University Molecular Imaging School of Medicine Program at Stanford Department of Radiology Ø Phase II: Found no significant side effects and showed 4.5 months increased OS, delayed SREs, and improvement in biochemical end points (PSA, total ALP)
Ø Phase III: Alpharadin successfully met the primary endpoint of OS in the ALSYMPCA (ALpharadin in SYMptomatic Prostate CAncer patients) study in 922 patients
MIPS Stanford Molecular Imaging Program at Stanford School of Medicine, Department of Radiology ALSYMPCA Trial Results
Ø 223Ra improved overall survival by 44% compared to placebo (p = 0.00185) Ø Average overall survival was 14.0 months for men treated with 223Ra and 11.2 months for men treated with placebo Ø Average time to first skeletal-related event was 13.6 months for men treated with 223Ra and 8.4 months for men treated with placebo Ø Levels of total alkaline phosphatase (ALP) were normalized in 33% of men treated with 223Ra and 1% of men treated with placebo Ø Treatment with 223Ra improved time to PSA progression by 49% compared to placebo (p = 0.00015)
MIPS Stanford Molecular Imaging Program at Stanford School of Medicine, Department of Radiology ALSYMPCA Trial Results
MIPS Stanford Molecular Imaging Program at Stanford School of Medicine, Department of Radiology ALSYMPCA Trial Results
MIPS Stanford Molecular Imaging Program at Stanford School of Medicine, Department of Radiology ALSYMPCA Trial Results (Continued)
Ø Common non-hematologic adverse events (occurring in at least 15% of patients) included ü Bone pain (in 43% of 223Ra patients vs. 58% of placebo-treated patients) ü Nausea (34% vs. 32%) ü Diarrhea (22% vs. 13%) ü Constipation (18% vs. 18%) ü Vomiting (17% vs. 13%) Ø The most common hematologic adverse event was anemia (in 27% of 223Ra patients vs. 27% of placebo-treated patients) Ø The most common grade 3 and grade 4 adverse event was bone pain (18% of 223Ra patients vs. 23% of placebo-treated patients)
MIPS Stanford Molecular Imaging Program at Stanford School of Medicine, Department of Radiology Radiation/Release Considerations
Ø Since patients treated with Alpharadin® emit negligible external radiation doses, they can be released immediately Ø For example, the average patient receiving 3.5 MBq (95 µCi) would have a dose rate at 1 m < 0.35 µSv/h (0.035 mrem/h) Ø There are no restrictions on family contact after administration of Alpharadin® Ø The range of α-particles in human tissue is approximately 0.1 mm Ø Once injected, α-particles are stopped by the patient’s tissue
MIPS Stanford Molecular Imaging Program at Stanford School of Medicine, Department of Radiology MIPS Stanford Molecular Imaging Program at Stanford School of Medicine, Department of Radiology THANK YOU! http://nuclearmedicine.stanford.edu http://mips.stanford.edu