Hem/Onc Updates – Page 21 – ChemoPrescribe LLC.

Genetically Adjusted PSA Values May Improve the Accuracy of Prostate Cancer Detection

April 20, 2022April 20, 2022 RR

SUMMARY: Prostate cancer is the most common cancer in American men with the exclusion of skin cancer, and 1 in 9 men will be diagnosed with prostate cancer during their lifetime. It is estimated that in the United States, about 268,490 new cases of prostate cancer will be diagnosed in 2022 and 34,500 men will die of the disease.

PSA is one of the most widely used prostate cancer biomarkers, and the widespread use of PSA testing in the recent years has resulted in a dramatic increase in the diagnosis and treatment of prostate cancer. The management of clinically localized prostate cancer that is detected based on Prostate Specific Antigen (PSA) levels remains controversial and management strategies for these patients have included Surgery, Radiotherapy or Active Monitoring. However, it has been proposed that given the indolent nature of prostate cancer in general, majority of the patients do not benefit from treatment intervention and many patients die of competing causes. Further, treatment intervention can result in adverse effects on sexual, urinary, or bowel function. The U.S. Preventive Services Task Force (USPSTF) has recommended that population screening for prostate cancer with PSA should not be adopted as a public health policy, because the risks appeared to outweigh benefits, from detecting and treating PSA-detected prostate cancer. PSA elevation can be associated with several non-malignant conditions such as older age, infection, inflammation and Benign Prostatic Hypertrophy.

The researchers in this study hypothesized that the accuracy of PSA screening for prostate cancer could be improved by accounting for genetic factors that cause changes in PSA levels not associated with prostate cancer. The aim of this study was to characterize genetic determinants of PSA levels in cancer-free men, in order to personalize prostate cancer screening.

The researchers conducted a large Genome Wide Association Study of PSA, to improve Prostate cancer screening, by accounting for genetic factors that cause noncancer-related variations in PSA levels, thereby personalizing prostate cancer screening. This study involved 95,768 men without a diagnosis prostate cancer from the US, UK and Sweden. The researchers identified 128 PSA-related variants across the genome, including 82 novel variants that were not previously recognized, and created a polygenic score for PSA levels. This polygenic score provided a cumulative measure of each individual’s genetic predisposition to high PSA levels.

The authors validated the polygenic score by applying the score to PSA values of 5,725 individuals enrolled in the Prostate Cancer Prevention Trial (PCPT) and the 25,917 individuals enrolled in the Selenium and Vitamin E Cancer Prevention Trial (SELECT). The analysis showed that the score explained 7.3% of variation in baseline PSA values in PCPT trial and 8.8% of variation in baseline PSA values in the SELECT cohort, and the polygenic score was not associated with prostate cancer in both the prevention trials, confirming that the score reflected benign PSA variation.

The researchers next tested the ability of the polygenic score’s ability to improve detection of clinically significant prostate cancer and reduce over diagnosis among a real-world cohort at Kaiser Permanente. They adjusted each individual’s PSA values based on his unique polygenic score and estimated the impact of this adjustment on the PSA thresholds that trigger biopsy referrals. The authors estimated that by substituting the patient’s polygenic score for measured PSA values, 19.6% of negative biopsies in men without prostate cancer potentially could have been avoided, and 15.7% of biopsies could have been avoided in men who had indolent, low-grade prostate cancer (Gleason score <7), which represented 71% of all men.

The researchers then evaluated whether genetically adjusted polygenic score would better detect aggressive prostate cancer (Gleason score 7, PSA 10 ng/mL, T3-T4 stage and/or distant nodal metastases). It was noted that in both the PCPT and the SELECT cohorts, polygenic score was more strongly associated with aggressive prostate cancer than measured unadjusted PSA values. The polygenic score also exceeded the performance of the 269-variant genetic risk score.

The authors from this study concluded that genetically adjusted PSA (polygenic score) could reduce unnecessary testing and overdiagnosis of low-risk prostate cancer, and increase detection of aggressive tumors and thus make PSA a more useful and accurate screening biomarker. The researchers pointed out that the population studied, were primarily European descent, and the polygenic score will need to be validated in more diverse populations.

Genetic determinants of PSA levels improve prostate cancer screening. Kachuri L, Graff RE, Berndt SI, et al. Presented at: AACR Annual Meeting 2022; April 8-13; New Orleans, Louisiana. Abstract 1441/8.

OPDIVO® (nivolumab) + chemotherapy (fluoropyrimidine + platinum-based) for the first-line (1L) treatment of metastatic gastric cancer, gastroesophageal junction cancer and esophageal adenocarcinoma, regardless of PD-L1 status

April 19, 2022April 19, 2022 RR

BMS Sponsored Content

By Dr Rahul Ravilla│Sponsored by Bristol Myers Squibb
Dr Ravilla is a paid consultant for BMS and was compensated for his contribution in drafting this content.

Introduction: Overview of gastroesophageal cancers

Gastroesophageal cancers consist of a group of heterogeneous tumors, including gastric cancer (GC), gastroesophageal junction cancer (GEJC), and esophageal cancer (EC).¹The majority of GC and GEJC are adenocarcinomas, while EC is categorized into 2 main histological subtypes: esophageal adenocarcinoma (EAC) and esophageal squamous cell carcinoma (ESCC).^2,3 EAC is the predominant histology in the United States, contributing to ~62% of all EC cases.^3,4EAC incidence rates have been increasing over the past 5 decades in Western countries.⁴Recent trends in the United States also suggest increasing incidence rates of GC overall in young adults (<50 years old).⁵

Gastric and esophageal cancers can be aggressive diseases with 5-year relative survival rates of <6% in the metastatic setting in the United States.^7,8 Worldwide, GC and EC represent the fourth and sixth most common causes of cancer-related deaths, respectively.⁵

Approximately 15%–20% of gastroesophageal adenocarcinomas overexpress human epidermal growth factor receptor 2 (HER2)⁹. In this article, we will focus on HER2-negative gastroesophageal adenocarcinomas. Historically, chemotherapy has been the standard of care for the 1L treatment in this setting.¹⁰ In 2021,chemoimmunotherapy combinations were approved for appropriate patients with certain types of gastroesophageal cancers.^11,12

OPDIVO + chemotherapy in 1L metastatic GC/GEJC/EAC

Currently, OPDIVO + fluoropyrimidine- and platinum-containing chemotherapy (chemo) is the only 1L chemoimmunotherapy regimen approved in metastatic non-HER2+ GC, GEJC, and EAC regardless of PD-L1 (programmed death ligand 1) status.^11,13,14 The combination was approved based on the results of Checkmate 649, a global phase 3 study in 1L metastatic GC/GEJC/EAC patients with ECOG performance status 0-1.^11,13 Key exclusion criteria included known HER2+ status and untreated CNS metastases.¹¹ The study recruited all eligible patients regardless of PD-L1 expression.^11,13

Checkmate 649 enrolled 1581 patients randomized 1:1 to OPDIVO + chemo (n=789) or chemo alone (n=792). A total of 473 patients in the OPDIVO + chemo arm and 482 patients in the chemo arm had tumors that expressed PD-L1 combined positive score (CPS) ≥5. The dual primary endpoints were overall survival (OS) and progression-free survival (PFS) in PD-L1 CPS ≥5. Key secondary endpoints included OS in PD-L1 CPS ≥1, OS in all randomized patients, and objective response rate (ORR) in all randomized patients. Checkmate 649 evaluated OPDIVO (10 mg/mL) injection for intravenous (IV) use (q2w or q3w) in combination with physician’s choice of either fluorouracil + oxaliplatin + leucovorin (mFOLFOX6) given q2w or capecitabine + oxaliplatin (CapeOx) given q3w. OPDIVO dosing was aligned with chemotherapy schedule. Treatment continued until disease progression, unacceptable toxicity, or up to 2 years. Baseline characteristics were consistent between all randomized and PD-L1 CPS ≥5 patients.¹³

There are Warnings and Precautions associated with OPDIVO to keep in mind. These include severe and fatal immune-mediated adverse reactions, infusion-related reactions, complications of allogeneic hematopoietic stem cell transplantation (HSCT); embryo-fetal toxicity, and increased mortality in patients with multiple myeloma when OPDIVO is added to a thalidomide analogue and dexamethasone, which is not recommended outside of controlled clinical trials.¹¹ Additional information related to Warnings and Precautions can be found in the Important Safety Information below.

In the primary analysis (minimum[min] follow-up of 12.1 months[mos]), OPDIVO + chemo demonstrated superior OS in all randomized, PD-L1 CPS ≥1, and PD-L1 CPS ≥5 patients as compared to chemotherapy alone. In all randomized patients, mOS was 13.8 mos (95% confidence interval [CI]: 12.6–14.6) with OPDIVO + chemo vs 11.6 mos (95% CI: 10.9–12.5) with chemo (HR=0.80;95% CI: 0.71–0.90; P=0.0002). In PD-L1 CPS≥1 (n=1296), mOS was 14.0 mos (95% CI: 12.6–15.0) with OPDIVO + chemo vs 11.3 mos (95% CI: 10.6–12.3) with chemo (HR=0.77; 95% CI: 0.68–0.88; P<0.0001). In PD-L1 CPS≥5 (n=955), mOS was 14.4 mos (95% CI: 13.1–16.2) with OPDIVO + chemo vs 11.1 mos (95% CI: 10.0–12.1) with chemo (HR=0.71; 95% CI: 0.61–0.83; P<0.0001).¹¹The dual primary endpoint, mPFS in CPS ≥5 patients, was 7.7 mos (95% CI: 7.0–9.2) with OPDIVO + chemo vs 6.0 mos (95% CI: 5.6–6.9) with chemo (HR=0.68; 95% CI: 0.58–0.79; P<0.0001).

*FOLFOX or CapeOx.¹¹†Assessed using blinded independent central review (BICR).¹¹ ‡Based on confirmed response.¹¹§Secondary endpoint.¹³

Exploratory OS analyses were reported for the primary (min follow-up 12.1 months) and follow-up (min follow-up 24 months) analysis. The 12-month OS rate in all randomized patients was 55% with OPDIVO + chemo vs 48% with chemo.¹³The follow-up analysis at 24.0 months reported a mOS of 13.8 mos (95% CI: 12.4–14.5) with OPDIVO + chemo vs 11.6 mos (95% CI: 10.9–12.5) with chemo in all randomized patients (HR=0.79; (95% CI: 0.71–0.88) and 14.4 mos (95% CI: 13.1–16.2) with OPDIVO + chemo vs 11.1 mos with chemo (95% CI: 10.0–12.1) in PD-L1 CPS ≥5 (HR=0.70; (95% CI: 0.60–0.81).¹⁴ The 24.0-month OS rate was 28% vs 19% for OPDIVO + chemo vs chemo, respectively, in all randomized patients.¹⁴

A secondary endpoint (min follow-up of 12.1 mos), ORR in all randomized patients, was 47% (95% CI: 43–50) with OPDIVO + chemo vs 37% (95% CI: 34–40) with chemo alone. Complete response (CR) rates were 10% vs 7% and partial response (PR) rates were 37% vs 30% for OPDIVO + chemo vs chemo, respectively.¹¹

In Checkmate 649, the most common adverse reactions reported in ≥20% of patients treated with OPDIVO in combination with chemotherapy were peripheral neuropathy, nausea, fatigue, diarrhea, vomiting, decreased appetite, abdominal pain, constipation, and musculoskeletal pain. Of the ARs occurring in ≥10% of patients, those which were Grade 3–4 (OPDIVO + chemo vs chemo) were peripheral neuropathy (7% vs 4.8%), headache (0.8 vs 0.3%), nausea (3.2% vs 3.7%), diarrhea (5% vs 3.7%), vomiting (4.2% vs 4.2%), abdominal pain (2.8% vs 2.6%), constipation (0.6% vs 0.4%), stomatitis (1.8% vs 0.8%), fatigue (7% vs 5%), pyrexia (1% vs 0.4%), edema (0.5% vs 0.1%), decreased appetite (3.6% vs 2.5%), hypoalbuminemia (0.3% vs 0.3%), weight decreased (1.3% vs 0.7%), increased lipase (7% vs 3.7%), increased amylase (3.1% vs 0.4%), musculoskeletal pain (1.3% vs 2%), rash (1.7% vs 0.1%), palmar-plantar erythrodysesthesia syndrome (1.5% vs 0.8%), cough (0.1% vs 0%) and upper respiratory tract infection (0.1% vs 0.1%).

OPDIVO and/or chemotherapy were discontinued in 44% of patients and at least one dose was withheld in 76% of patients due to an adverse reaction. Serious adverse reactions occurred in 52% of patients treated with OPDIVO in combination with chemotherapy. The most frequent serious adverse reactions reported in ≥2% of patients treated with OPDIVO in combination with chemotherapy were vomiting (3.7%), pneumonia (3.6%), anemia (3.6%), pyrexia (2.8%), diarrhea (2.7%), febrile neutropenia (2.6%), and pneumonitis (2.4%). Fatal adverse reactions occurred in 16 (2.0%) patients who were treated with OPDIVO in combination with chemotherapy; these included pneumonitis (4 patients), febrile neutropenia (2 patients), stroke (2 patients), gastrointestinal toxicity, intestinal mucositis, septic shock, pneumonia, infection, gastrointestinal bleeding, mesenteric vessel thrombosis, and disseminated intravascular coagulation.¹¹

Summary/conclusions

OPDIVO, in combination with fluoropyrimidine- and platinum-containing chemotherapy, is an approved treatment option for 1L metastatic non-HER2+ GC/GEJC/EAC regardless of PD-L1 status.¹¹This approval is based on the Checkmate 649 study, which at the primary analysis demonstrated superior OS with OPDIVO + chemotherapy versus chemotherapy in all randomized patients.¹¹

1L=first line; chemo=chemotherapy; CI=confidence interval; CNS=central nervous system; ECOG=Eastern Cooperative Oncology Group; GEJC=gastroesophageal junction cancer; HR=hazard ratio; mo=month; mOS=median OS; q2w=every two weeks; q4w=every four weeks.

Indication

OPDIVO, in combination with fluoropyrimidine- and platinum-containing chemotherapy, is indicated for the treatment of patients with advanced or metastatic gastric cancer, gastroesophageal junction cancer, and esophageal adenocarcinoma.¹¹

Important Safety Information

Severe and Fatal Immune-Mediated Adverse Reactions
• Immune-mediated adverse reactions listed herein may not include all possible severe and fatal immune-mediated adverse reactions.
• Immune-mediated adverse reactions, which may be severe or fatal, can occur in any organ system or tissue. While immune-mediated adverse reactions usually manifest during treatment, they can also occur after discontinuation of OPDIVO. Early identification and management are essential to ensure safe use of OPDIVO. Monitor for signs and symptoms that may be clinical manifestations of underlying immune-mediated adverse reactions. Evaluate clinical chemistries including liver enzymes, creatinine, and thyroid function at baseline and periodically during treatment with OPDIVO. In cases of suspected immune-mediated adverse reactions, initiate appropriate workup to exclude alternative etiologies, including infection. Institute medical management promptly, including specialty consultation as appropriate.
• Withhold or permanently discontinue OPDIVO depending on severity (please see section 2 Dosage and Administration in the accompanying Full Prescribing Information). In general, if OPDIVO interruption or discontinuation is required, administer systemic corticosteroid therapy (1 to 2 mg/kg/day prednisone or equivalent) until improvement to Grade 1 or less. Upon improvement to Grade 1 or less, initiate corticosteroid taper and continue to taper over at least 1 month. Consider administration of other systemic immunosuppressants in patients whose immune-mediated adverse reactions are not controlled with corticosteroid therapy. Toxicity management guidelines for adverse reactions that do not necessarily require systemic steroids (e.g., endocrinopathies and dermatologic reactions) are discussed below.

Immune-Mediated Pneumonitis
• OPDIVO can cause immune-mediated pneumonitis. The incidence of pneumonitis is higher in patients who have received prior thoracic radiation. In patients receiving OPDIVO monotherapy, immune-mediated pneumonitis occurred in 3.1% (61/1994) of patients, including Grade 4 (<0.1%), Grade 3 (0.9%), and Grade 2 (2.1%).

Immune-Mediated Colitis
• OPDIVO can cause immune-mediated colitis. A common symptom included in the definition of colitis was diarrhea. Cytomegalovirus (CMV) infection/reactivation has been reported in patients with corticosteroid-refractory immune-mediated colitis. In cases of corticosteroid-refractory colitis, consider repeating infectious workup to exclude alternative etiologies. In patients receiving OPDIVO monotherapy, immune-mediated colitis occurred in 2.9% (58/1994) of patients, including Grade 3 (1.7%) and Grade 2 (1%).

Immune-Mediated Hepatitis and Hepatoxicity
• OPDIVO can cause immune-mediated hepatitis. In patients receiving OPDIVO monotherapy, immune-mediated hepatitis occurred in 1.8% (35/1994) of patients, including Grade 4 (0.2%), Grade 3 (1.3%), and Grade 2 (0.4%).

Immune-Mediated Endocrinopathies
• OPDIVO can cause primary or secondary adrenal insufficiency, immune-mediated hypophysitis, immune-mediated thyroid disorders, and Type 1 diabetes mellitus, which can present with diabetic ketoacidosis. Withhold OPDIVO depending on severity (please see section 2 Dosage and Administration in the accompanying Full Prescribing Information). For Grade 2 or higher adrenal insufficiency, initiate symptomatic treatment, including hormone replacement as clinically indicated. Hypophysitis can present with acute symptoms associated with mass effect such as headache, photophobia, or visual field defects. Hypophysitis can cause hypopituitarism; initiate hormone replacement as clinically indicated. Thyroiditis can present with or without endocrinopathy. Hypothyroidism can follow hyperthyroidism; initiate hormone replacement or medical management as clinically indicated. Monitor patients for hyperglycemia or other signs and symptoms of diabetes; initiate treatment with insulin as clinically indicated.
• In patients receiving OPDIVO monotherapy, adrenal insufficiency occurred in 1% (20/1994), including Grade 3 (0.4%) and Grade 2 (0.6%).
• In patients receiving OPDIVO monotherapy, hypophysitis occurred in 0.6% (12/1994) of patients, including Grade 3 (0.2%) and Grade 2 (0.3%).
• In patients receiving OPDIVO monotherapy, thyroiditis occurred in 0.6% (12/1994) of patients, including Grade 2 (0.2%).
• In patients receiving OPDIVO monotherapy, hyperthyroidism occurred in 2.7% (54/1994) of patients, including Grade 3 (<0.1%) and Grade 2 (1.2%).
• In patients receiving OPDIVO monotherapy, hypothyroidism occurred in 8% (163/1994) of patients, including Grade 3 (0.2%) and Grade 2 (4.8%).
• In patients receiving OPDIVO monotherapy, diabetes occurred in 0.9% (17/1994) of patients, including Grade 3 (0.4%) and Grade 2 (0.3%), and 2 cases of diabetic ketoacidosis.

Immune-Mediated Nephritis with Renal Dysfunction
• OPDIVO can cause immune-mediated nephritis. In patients receiving OPDIVO® monotherapy, immune-mediated nephritis and renal dysfunction occurred in 1.2% (23/1994) of patients, including Grade 4 (<0.1%), Grade 3 (0.5%), and Grade 2 (0.6%).

Immune-Mediated Dermatologic Adverse Reactions
• OPDIVO can cause immune-mediated rash or dermatitis. Exfoliative dermatitis, including Stevens-Johnson syndrome (SJS), toxic epidermal necrolysis (TEN), and drug rash with eosinophilia and systemic symptoms (DRESS) has occurred with PD-1/PD-L1 blocking antibodies. Topical emollients and/or topical corticosteroids may be adequate to treat mild to moderate nonexfoliative rashes.
• Withhold or permanently discontinue OPDIVO depending on severity (please see section 2 Dosage and Administration in the accompanying Full Prescribing Information).
• In patients receiving OPDIVO monotherapy, immune-mediated rash occurred in 9% (171/1994) of patients, including Grade 3 (1.1%) and Grade 2 (2.2%).

Other Immune-Mediated Adverse Reactions
• The following clinically significant immune-mediated adverse reactions occurred at an incidence of <1% (unless otherwise noted) in patients who received OPDIVO monotherapy or were reported with the use of other PD-1/PD-L1 blocking antibodies. Severe or fatal cases have been reported for some of these adverse reactions: cardiac/vascular: myocarditis, pericarditis, vasculitis; nervous system: meningitis, encephalitis, myelitis and demyelination, myasthenic syndrome/myasthenia gravis (including exacerbation), Guillain-Barré syndrome, nerve paresis, autoimmune neuropathy; ocular: uveitis, iritis, and other ocular inflammatory toxicities can occur; gastrointestinal: pancreatitis to include increases in serum amylase and lipase levels, gastritis, duodenitis; musculoskeletal and connective tissue: myositis/polymyositis, rhabdomyolysis, and associated sequelae including renal failure, arthritis, polymyalgia rheumatica; endocrine: hypoparathyroidism; other (hematologic/immune): hemolytic anemia, aplastic anemia, hemophagocytic lymphohistiocytosis (HLH), systemic inflammatory response syndrome, histiocytic necrotizing lymphadenitis (Kikuchi lymphadenitis), sarcoidosis, immune thrombocytopenic purpura, solid organ transplant rejection.
• Some ocular IMAR cases can be associated with retinal detachment. Various grades of visual impairment, including blindness, can occur. If uveitis occurs in combination with other immune-mediated adverse reactions, consider a Vogt-Koyanagi-Harada–like syndrome, which has been observed in patients receiving OPDIVO, as this may require treatment with systemic corticosteroids to reduce the risk of permanent vision loss.

Infusion-Related Reactions
• OPDIVO can cause severe infusion-related reactions. Discontinue OPDIVO in patients with severe (Grade 3) or life-threatening (Grade 4) infusion-related reactions. Interrupt or slow the rate of infusion in patients with mild (Grade 1) or moderate (Grade 2) infusion-related reactions. In patients receiving OPDIVO monotherapy as a 60-minute infusion, infusion-related reactions occurred in 6.4% (127/1994) of patients. In a separate trial in which patients received OPDIVO monotherapy as a 60-minute infusion or a 30-minute infusion, infusion-related reactions occurred in 2.2% (8/368) and 2.7% (10/369) of patients, respectively. Additionally, 0.5% (2/368) and 1.4% (5/369) of patients, respectively, experienced adverse reactions within 48 hours of infusion that led to dose delay, permanent discontinuation or withholding of OPDIVO.
Complications of Allogeneic Hematopoietic Stem Cell Transplantation
• Fatal and other serious complications can occur in patients who receive allogeneic hematopoietic stem cell transplantation (HSCT) before or after being treated with OPDIVO. Transplant-related complications include hyperacute graft-versus-host-disease (GVHD), acute GVHD, chronic GVHD, hepatic veno-occlusive disease (VOD) after reduced intensity conditioning, and steroid-requiring febrile syndrome (without an identified infectious cause). These complications may occur despite intervening therapy between OPDIVO and allogeneic HSCT.
• Follow patients closely for evidence of transplant-related complications and intervene promptly. Consider the benefit versus risks of treatment with OPDIVO prior to or after an allogeneic HSCT.
Embryo-Fetal Toxicity
• Based on its mechanism of action and findings from animal studies, OPDIVO can cause fetal harm when administered to a pregnant woman. Advise pregnant women of the potential risk to a fetus. Advise females of reproductive potential to use effective contraception during treatment with OPDIVO and for at least 5 months after the last dose.
Increased Mortality in Patients with Multiple Myeloma when OPDIVO® is Added to a Thalidomide Analogue and Dexamethasone
• In randomized clinical trials in patients with multiple myeloma, the addition of OPDIVO to a thalidomide analogue plus dexamethasone resulted in increased mortality. Treatment of patients with multiple myeloma with a PD-1 or PD-L1 blocking antibody in combination with a thalidomide analogue plus dexamethasone is not recommended outside of controlled clinical trials.
Lactation
• There are no data on the presence of OPDIVO in human milk, the effects on the breastfed child, or the effects on milk production. Because of the potential for serious adverse reactions in breastfed children, advise women not to breastfeed during treatment and for 5 months after the last dose.
Serious Adverse Reactions
• In Checkmate 649, serious adverse reactions occurred in 52% of patients treated with OPDIVO in combination with chemotherapy (n=782). The most frequent serious adverse reactions reported in ≥2% of patients treated with OPDIVO in combination with chemotherapy were vomiting (3.7%), pneumonia (3.6%), anemia (3.6%), pyrexia (2.8%), diarrhea (2.7%), febrile neutropenia (2.6%), and pneumonitis (2.4%). Fatal adverse reactions occurred in 16 (2.0%) patients who were treated with OPDIVO in combination with chemotherapy; these included pneumonitis (4 patients), febrile neutropenia (2 patients), stroke (2 patients), gastrointestinal toxicity, intestinal mucositis, septic shock, pneumonia, infection, gastrointestinal bleeding, mesenteric vessel thrombosis, and disseminated intravascular coagulation.
Common Adverse Reactions
• In Checkmate 649, the most common adverse reactions (≥20%) in patients treated with OPDIVO in combination with chemotherapy (n=782) were peripheral neuropathy (53%), nausea (48%), fatigue (44%), diarrhea (39%), vomiting (31%), decreased appetite (29%), abdominal pain (27%), constipation (25%), and musculoskeletal pain (20%).

Please see US Full Prescribing Information for OPDIVO.

References:
1. Paydary K, Reizine N, Catenacci DVT. Immune-checkpoint inhibition in the treatment of gastro-esophageal cancer: a closer look at the emerging evidence. Cancers (Basel). 2021;13(23):5929.
2. National Cancer Institute. Gastric cancer treatment (PDQ®)–health professional version. National Cancer Institute website. Updated April 22, 2021.Accessed December 3, 2021.
http://cancer.gov/types/stomach/hp/stomach-treatment-pdq.
3. Chen Z, Ren Y, Du XL, et al. Incidence and survival differences in esophageal cancer among ethnic groups in the United States. Oncotarget. 2017;8(29):47037-47051.
4. He H, Chen N, Hou Y, et al. Trends in the incidence and survival of patients with esophageal cancer: a SEER database analysis. Thorac Cancer. 2020;11(5):1121-1128.
5. Sung H, Ferlay J, Siegel RL, et al. Global cancer statistics 2020: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries.CA Cancer J Clin. 2021;71(3):209-249.
6. Arnold M, Ferlay J, van Berge Henegouwen MI, Soerjomataram I. Global burden of oesophageal and gastric cancer by histology and subsite in 2018. Gut. 2020;69(9):1564-1571.
7. National Cancer Institute Surveillance, Epidemiology, and End Results Program. Cancer stat facts: stomach cancer. National Cancer Institute website. Accessed December 3, 2021.
http://seer.cancer.gov/statfacts/html/stomach.html.
8. National Cancer Institute Surveillance, Epidemiology, and End Results Program. Cancer stat facts: esophageal cancer. National Cancer Institute website. Accessed December 3, 2021.
http://seer.cancer.gov/statfacts/html/esoph.html.
9. Grieb BC, Agarwal R. HER2-Directed Therapy in Advanced Gastric and Gastroesophageal Adenocarcinoma: Triumphs and Troubles. Curr Treat Options Oncol. 2021;22(10):88.
10. ShankaranV, Xiao, H, Bertwistle D, et al. A comparison of real-world treatment patterns and clinical outcomes in patients receiving first-line therapy for unresectable advanced gastric or gastroesophageal junction cancer versus esophageal adenocarcinomas. Adv Ther. 2021;38:
707-720.
11. OPDIVO® (nivolumab) [package insert]. Princeton, NJ: Bristol-Myers Squibb Company; 2021.
12. KEYTRUDA® (pembrolizumab) [package insert]. Kenilworth, NJ: Merck & Co., Inc; 2021.
13. Janjigian YY, Shitara K, Moehler M, et al. First-line nivolumab plus chemotherapy versus chemotherapy alone for advanced gastric, gastroesophageal junction cancer/oesophageal adenocarcinoma (CheckMate 649): a randomised, open-label, phase 3 trial. Lancet. 2021;398(10294):27-40.
14. Janjigian YY, Ajani JA, Moehler M, et al. Nivolumab plus chemotherapy or ipilimumab vs chemotherapy as first-line treatment for advanced gastric cancer/gastroesophageal junction cancer/ esophageal adenocarcinoma: CheckMate 649 study. Presentation at ESMO 2021. Abstract LBA7.
15. Data on file. BMS-REF-NIVO-0120. Princeton, NJ: Bristol-Myers Squibb Company; 2021.

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1506-US-2200006 03/22

TUKYSA® in Pretreated HER2-positive Metastatic Breast Cancer With and Without Brain Metastases: Final Overall Survival Analysis

April 14, 2022April 14, 2022 RR

The HER or erbB family of receptors consist of HER1, HER2, HER3 and HER4. Approximately 15-20% of invasive breast cancers overexpress HER2/neu oncogene, which is a negative predictor of outcomes without systemic therapy. Patients with HER2-positive metastatic breast cancer are often treated with anti-HER2 targeted therapy along with chemotherapy, irrespective of hormone receptor status, and this has resulted in significantly improved treatment outcomes. HER2-targeted therapies include HERCEPTIN® (Trastuzumab), TYKERB® (Lapatinib), PERJETA® (Pertuzumab), KADCYLA® (ado-Trastuzumab emtansine), ENHERTU® (Trastuzumab deruxtecan) and MARGENZA® (Margetuximab). Dual HER2 blockade with HERCEPTIN® and PERJETA®, given along with chemotherapy (with or without endocrine therapy), as first line treatment, in HER2-positive metastatic breast cancer patients, was shown to significantly improve Progression Free Survival (PFS) as well as Overall Survival (OS). The superior benefit with dual HER2 blockade has been attributed to differing mechanisms of action and synergistic interaction between HER2 targeted therapies. Patients progressing on Dual HER2 blockade often receive KADCYLA® which results in an Objective Response Rate (ORR) of 44% and a median PFS of 9.6 months, when administered after HERCEPTIN® and a taxane. There is however no standard treatment option for this patient population following progression on KADCYLA®.

It is estimated that close to 50% of patients with HER2-positive metastatic breast cancer develop brain metastases. Systemic HER2-targeted agents, including Tyrosine Kinase Inhibitors, as well as chemotherapy have limited antitumor activity in the brain. This is therefore an area of high unmet need. Local therapeutic interventions for brain metastases include neurosurgical resection and Stereotactic or Whole-Brain Radiation Therapy.

TUKYSA® (Tucatinib) is an oral Tyrosine Kinase Inhibitor that is highly selective for the kinase domain of HER2 with minimal inhibition of Epidermal Growth Factor Receptor. In a Phase 1b dose-escalation trial, TUKYSA® in combination with HERCEPTIN® and XELODA® (Capecitabine) showed encouraging antitumor activity in patients with HER2-positive metastatic breast cancer, including those with brain metastases.

HER2CLIMB is an international, randomized, double-blind, placebo-controlled trial in which the combination of TUKYSA® plus HERCEPTIN® and XELODA® was compared with placebo plus HERCEPTIN® and XELODA®. A total of 612 patients with unresectable locally advanced or metastatic HER2-positive breast cancer, who were previously treated with HERCEPTIN®, PERJETA® (Pertuzumab) and KADCYLA® (ado-Trastuzumab emtansine) were enrolled. Patients were randomly assigned in a 2:1 ratio to receive either TUKYSA® 300 mg orally twice daily throughout the treatment period (N=410) or placebo orally twice daily (N=201), in combination with HERCEPTIN® 6 mg/kg IV once every 21 days, following an initial loading dose of 8 mg/kg, and XELODA® 1000 mg/m2 orally twice daily on days 1 to 14 of each 21-day cycle. Stratification factors included presence or absence of brain metastases, ECOG Performance Status and geographic region. The median patient age was 54 years and patient demographic as well as disease characteristics at baseline were well balanced between the two treatment groups. In the total treatment population, 47.5% had brain metastases at baseline, 48.3% in the TUKYSA® combination group and 46% in the placebo combination group. The Primary endpoint was Progression Free Survival (PFS). Secondary end points included Overall Survival (OS), PFS among patients with brain metastases, confirmed Objective Response Rate (ORR), and safety.

In the primary analysis, at a median follow-up of 14 months, TUKYSA® added to HERCEPTIN® and XELODA®, significantly improved Overall Survival (OS) and Progression Free Survival (PFS) in patients with HER2-positive metastatic breast cancer. After the primary analysis, the protocol was amended to allow unblinding and cross-over from the placebo combination to the TUKYSA® combination. Protocol prespecified descriptive analyses of OS, PFS and safety were carried out at about 2 years from the last patient randomized. The researchers in this publication reported the final efficacy and safety outcomes after an additional 15.6 months follow up (total follow up of 29.6 months) in patients from the HER2CLIMB trial.

At a median follow up of 29.6 months, the median duration of OS was 24.7 months for the TUKYSA® combination group versus 19.2 months in the placebo combination group (HR for death=0.73; P=0.004). The estimated OS rate at 2 years was 51% in the TUKYSA® combination group and 40% in the placebo combination group. The OS benefit with the TUKYSA® combination was noted across all prespecified subgroups in the overall study population and was consistent with the primary analysis. The median duration of PFS was 7.6 months for the TUKYSA® combination group versus 4.9 months for the placebo combination group (HR for progression or death=0.57; P<0.00001), and PFS at 1 year was 29% and 14%, respectively.

Systemic treatment with TUKYSA® in combination with HERCEPTIN® and XELODA® provided consistent clinical benefit to patients with and without brain metastases. TUKYSA® combination doubled the intracranial Objective Response Rate, reduced the risk of intracranial progression or death by two-thirds in all patients with brain metastases. In this study population, the estimated 1-year intracranial PFS was 40% in the TUKYSA® group and 0% in the control group. In patients with untreated or treated and progressing (active) brain metastases, the estimated 1-year intracranial PFS was 35% in the TUKYSA® group, 0% in the control group, and in patients with treated (stable) brain metastases, was 53% in the TUKYSA® group and 0% in the control group. The TUKYSA® combination was well tolerated with a low rate of discontinuation due to toxicities. Common adverse events in the TUKYSA® group included diarrhea, Palmar-Plantar Erythrodysesthesia syndrome, nausea, vomiting and fatigue. Diarrhea and abnormal liver function tests were more common in the TUKYSA® group than in the control group.

It was concluded that with additional follow up, TUKYSA® in combination with HERCEPTIN® and XELODA® provided a clinically meaningful survival benefit, including those with brain metastases, supporting the use of this combination in patients with previously treated HER2-positive metastatic breast cancer, after progression on two HER2-targeted therapies.

Tucatinib versus placebo added to trastuzumab and capecitabine for patients with pretreated HER2+ metastatic breast cancer with and without brain metastases (HER2CLIMB): final overall survival analysis. Curigliano G, Mueller V, Borges V, et al. Ann Oncol. 2022;33:321-329.

Early-Stage Multi-Cancer Detection Using an Extracellular Vesicle Protein-Based Blood Test

April 14, 2022April 14, 2022 RR

SUMMARY: The American Cancer Society’s estimates that in 2022, about 62,210 people will be diagnosed with pancreatic cancer and 49,830 people will die of the disease, 19,880 women will receive a new diagnosis of ovarian cancer and about 12,810 women will die of the disease, and about 81,800 new cases of bladder cancer will be diagnosed in 2022 and about 17,100 patients will die of the disease. These three cancer types are estimated to account for approximately 80,000 deaths in the US in 2022. Detecting cancer at early stages can significantly increase survival rates and outcomes.

Several multi-cancer early detection tests are being developed that involve blood-based circulating cell-free tumor DNA (cfDNA) in the plasma, to track hundreds of patient-specific mutations, to detect Minimal Residual Disease (MRD) , as well as detection of abnormal methylation patterns, followed by machine learning approaches, to differentiate between cancer and non-cancer, for detecting clinically significant, late-stage (III and IV) cancers. Early detection of cancer however is the key to improving survival. This is particularly relevant for certain cancer types. Pancreatic Ductal AdenoCarcinoma (PDAC) is one of the deadliest cancers, and a leading cause of all cancer-related deaths in the United States, and is typically detected when the disease is advanced. However, when detected at Stage I, survival rates can be as high as 80%. Ovarian cancer is often detected when the disease is advanced and the 5-year survival rates are less than 30%, but can be as high as 93% when detected early. The same holds true for metastatic bladder cancer, with 5-year survival rates of only 6%, whereas while detected when the tumor is still localized to the bladder wall inner layer results in a 5-year survival rate of 96%. Even though serum CA19-9 is intended as an aid in the management of patients with confirmed pancreatic cancer for serial monitoring of their response to therapy and disease progression, it is not recommended by the FDA for screening, as it may be elevated in several benign conditions. Similarly, serum CA-125 is FDA approved for use in monitoring patients with ovarian cancer for disease persistence and recurrence, but is not recommended to screen for ovarian cancer. Currently, there are few general screening strategies to detect asymptomatic, early-stage PDAC, ovarian, or bladder cancer and there is therefore a significant unmet need in this patient group.

Exosomes are 30-150 nm-sized Extracellular Vesicles (EVs) secreted by multiple different cell types and ejected by tumors into the bloodstream. They mediate intercellular signaling by transferring mRNAs and microRNAs between distant cells and tissues and therefore carry functional protein biomarkers representing the tumor proteome. Exosomes represent one potential approach for more sensitive detection of cancer-related biomarkers from blood.

The researchers in this study used an Alternating Current Electrokinetic (ACE)-based platform (Verita™ System) to efficiently isolate EVs from soluble contaminants such as cells, small proteins, or other vesicles from patient samples, and then measured the concentrations of associated protein biomarkers (“EV proteins”) present in the purified EV samples from our case-control study subjects. The researchers chose this platform over the current gold standard ultracentrifugation method, which the authors felt was inefficient and not suitable for point-of-care applications. Artificial Intelligence machine-learning algorithm developed by the researchers, enabled detection of early-stage pancreatic, ovarian, and bladder cancers.

In this case-control pilot study, 139 pathologically confirmed Stage I and II cancer cases representing pancreatic, ovarian, or bladder patients were compared with 184 control subjects, using the Verita™ System. The Extracellular Vesicles (EVs) isolated using this technology, were consistent with the presence of Exosomes, in accordance with the International Society for Extracellular Vesicles (ISEV) 2018 guidelines. The researchers selected a panel of 13 Extracellular Vesicle (EV) proteins along with age, a known cofactor in cancer. In order to simulate a real-world screening scenario, all cancer cases were treatment-naïve and to ensure that these were early-stage patients, the histopathologic staging was confirmed using the American Joint Commission on Cancer (AJCC) guidelines. The median age of the cancer cases was 60 years and 63.3% of the overall cancer cases were Stage I, with the remaining 36.7% at Stage II. The median age of the control group was 57 years and had no known history of cancer, autoimmune diseases, neurodegenerative disorders or diabetes mellitus.

When the overall cancer case cohort was compared with the control individuals using the EV protein biomarker test, the average sensitivity was 71.2%, at a specificity of 99.5%. When considered across all the three cancers studied, EV protein biomarker test using this technology demonstrated similar sensitivities of 70.5% and 72.5% for Stage I and II patients, respectively. This new technology detected 95.5% of Stage I pancreatic cancers, 73.1% of pathologic Stage IA lethally aggressive serous ovarian adenocarcinomas and 43.8% in bladder cancer, demonstrating the potential value of this platform for detection of early stage cancers. The lower sensitivity for detecting early stage bladder cancer may be due to high molecular and histologic heterogeneity of bladder tumors.

It was concluded from this study that blood-based EV protein detection test has potential clinical value for early cancer detection and the use of Verita™ platform resulted in the accurate detection of early stage pancreatic, ovarian, or bladder cancer. The authors added that mortality from pancreatic cancer which will soon become the second leading cause of cancer mortality in the U.S., can be greatly reduced if this study results are validated.

Early-stage multi-cancer detection using an extracellular vesicle protein-based blood test. Hinestrosa, J.P., Kurzrock, R., Lewis, J.M. et al. Commun Med 2, 29 (2022). https://doi.org/10.1038/s43856-022-00088-6.

FDA Approves Neoadjuvant OPDIVO® and Chemotherapy Combination for Early Stage Non Small Cell Lung Cancer

April 7, 2022April 7, 2022 RR

SUMMARY: The FDA on March 4, 2022, approved OPDIVO® (Nivolumab) with platinum-doublet chemotherapy for adult patients with resectable Non Small Cell Lung Cancer (NSCLC) in the neoadjuvant setting. This represents the first FDA approval for neoadjuvant therapy for early stage NSCLC. The American Cancer Society estimates that for 2022, about 236,740 new cases of lung cancer will be diagnosed and 135,360 patients will die of the disease. Lung cancer is the leading cause of cancer-related mortality in the United States. Non-Small Cell Lung Cancer (NSCLC) accounts for approximately 85% of all lung cancers. Of the three main subtypes of NSCLC, 30% are Squamous Cell Carcinomas (SCC), 40% are Adenocarcinomas and 10% are Large Cell Carcinomas. With changes in the cigarette composition and decline in tobacco consumption over the past several decades, Adenocarcinoma now is the most frequent histologic subtype of lung cancer.

Surgical resection with a curative intent is the primary treatment for approximately 30% of patients with NSCLC who present with early Stage (I–IIIA) disease, unless medically unfit. These numbers are likely to increase with the implementation of Lung Cancer screening programs. These patients are often treated with platinum-based adjuvant chemotherapy/immunotherapy following surgical resection, to decrease the risk of recurrence. Nonetheless, 45-75% of these patients develop recurrent disease. There is therefore an unmet need for this patient population.

CHECKMATE-816 is an open-label, multicenter, randomized Phase III study which evaluated OPDIVO® plus chemotherapy versus chemotherapy alone as neoadjuvant treatment in patients with resectable Stage IB to IIIA NSCLC. In this trial, 358 patients with clinical Stage IB to Stage IIIA resectable NSCLC, with an ECOG Performance Status of 0 to 1 and no known sensitizing EGFR mutations or ALK alterations, were randomly assigned 1:1 to receive OPDIVO® at a dose of 360 mg IV along with platinum-doublet chemotherapy every 3 weeks for 3 doses (N=179) or chemotherapy alone on the same schedule (N=179). Patients then underwent radiologic staging and surgical resection within 6 weeks of neoadjuvant therapy. They then had the option of adjuvant therapy with or without radiation therapy, and were followed up. Both treatment groups were well balanced with regards to age, sex, histology and smoking status. About two-thirds of the patients had Stage IIIA disease. The median patient age was 65 years and patients were stratified by cancer stage, gender and PD-L1 status (1% or higher versus less than 1%). Tumor Mutational Burden results were available for 50% of patients. The Primary end points of this study were pathologic Complete Response (pCR), defined as the absence of viable tumor cells in lung and lymph nodes, and Event Free Survival (EFS). Secondary endpoints include major pathological response and Overall Survival. Key exploratory endpoints included feasibility of surgery and surgery-related adverse events.

The pCR rate was 24% in the OPDIVO® plus chemotherapy group and 2.2% in the chemotherapy alone group. The pCR improvement was noted with the OPDIVO® plus chemotherapy combination regardless of disease stage and irrespective of radiologic downstaging. Overall, 83% of patients assigned to OPDIVO® plus chemotherapy and 78% of patient’s assigned to chemotherapy alone achieved R0 resection, with 10% versus 74% median residual viable tumor cells noted in the primary tumor bed respectively. Lung-sparing surgery (lobectomy) was performed in 77% of patients assigned to OPDIVO® plus chemotherapy versus 61% among those assigned to chemotherapy alone. The median EFS was 31.6 months in the OPDIVO® plus chemotherapy group and 20.8 months for those receiving chemotherapy alone (HR=0.63; P=0.0052).

The authors concluded that CheckMate 816 is the first Phase III trial to show a benefit for neoadjuvant immunotherapy plus platinum-doublet chemotherapy in earlier stage resectable NSCLC, with marked improvement in pathologic Complete Response rate, without any meaningful increase in toxicity or decrease in the feasibility of surgery. It is likely that the higher pathologic Complete Response rate may translate into higher cure rates, with longer follow up.

Surgical outcomes from the phase 3 CheckMate 816 trial: nivolumab (NIVO) + platinum-doublet chemotherapy (chemo) vs chemo alone as neoadjuvant treatment for patients with resectable non-small cell lung cancer (NSCLC). Spicer J, Wang C, Tanaka F, et al. J Clin Oncol. 2021;39(suppl 15):8503. doi:10.1200/JCO.2021.39.15_suppl.8503

FDA Approves YESCARTA® for Second Line Treatment of Large B-cell Lymphoma

April 7, 2022April 7, 2022 RR

SUMMARY: The FDA on April 1, 2022, approved YESCARTA® (Axicabtagene ciloleucel) for adult patients with Large B-cell lymphoma (LBCL) that is refractory to first-line chemoimmunotherapy or relapses within 12 months of first-line chemoimmunotherapy.

What is (CAR) T-cell immunotherapy? Chimeric Antigen Receptor (CAR) T-cell therapy is a type of immunotherapy and consists of T cells collected from the patient’s blood in a leukapheresis procedure, and genetically engineered to produce special receptors on their surface called Chimeric Antigen Receptors (CAR). These reprogrammed cytotoxic T cells with the Chimeric Antigen Receptors on their surface are now able to recognize a specific antigen on tumor cells. These genetically engineered and reprogrammed CAR T-cells are grown in the lab and are then infused into the patient. These cells in turn proliferate in the patient’s body and the engineered receptor on the cell surface help recognize and kill cancer cells that expresses that specific antigen. It is a therefore a customized treatment created using patient’s own T cells to destroy cancer cells.

YESCARTA® is a Chimeric Antigen Receptor (CAR) T cell immunotherapy and consists of autologous T cells that are genetically modified to produce a CAR protein, allowing the T cells to seek out and destroy cancer cells expressing the antigen CD19, which is found uniquely on B cells. Patients, following treatment with CAR T-cells, develop B-cell aplasia (absence of CD19 positive cells) due to B-cell destruction and may need immunoglobin replacement. Hence, B-cell aplasia can be a useful therapeutic marker, as continued B-cell aplasia has been seen in all patients who had sustained remission, following CAR T-cell therapy. Cytokine Release Syndrome (CRS), an inflammatory process is the most common and serious side effect of CAR T-cell therapy and is associated with marked elevation of Interleukin-6. Cytokine release is important for T-cell activation and can result in high fevers and myalgias. This is usually self limiting although if severe can be associated with hypotension and respiratory insufficiency. Tocilizumab (ACTEMRA®), an Interleukin-6 receptor blocking antibody produces a rapid improvement in symptoms. This is however not recommended unless the symptoms are severe and life threatening, as blunting the cytokine response can in turn negate T-cell proliferation. Elevated serum Ferritin and C-reactive protein levels are surrogate markers for severe Cytokine Release Syndrome. The CAR T-cells have been shown to also access sanctuary sites such as the central nervous system and eradicate cancer cells. CD19 antigen is expressed by majority of the B cell malignancies and therefore most studies using CAR T-cell therapy have focused on the treatment of advanced B-cell malignancies such as Chronic Lymphocytic Leukemia (CLL), Acute Lymphoblastic Leukemia (ALL) and Non Hodgkin lymphoma (NHL), such as Diffuse Large B-Cell Lymphoma (DLBCL).

Diffuse Large B-Cell Lymphoma (DLBCL) is the most common of the aggressive Non-Hodgkin lymphoma’s in the United States, and the incidence has steadily increased 3 to 4% each year. Outcomes for patients with relapsed/refractory disease, is poor, with an Objective response Rate (ORR) of 26%, Complete Response (CR) rate of 8% and a median Overall Survival (OS) of 6.6 months. There is therefore a significant unmet need in this patient group.

The present FDA approval was based on ZUMA-7, an international, randomized, open-label, multicenter Phase III trial, which compared the safety and efficacy of YESCARTA® with that of the current Standard of Care, as second-line treatment in patients with relapsed or refractory Large B-Cell Lymphoma (LBCL). In this study, 359 enrolled patients were randomized 1:1 to receive either a single infusion of YESCARTA® following Fludarabine and Cyclophosphamide lymphodepleting chemotherapy (N=180) or Standard of Care investigator-chosen second-line therapy, consisting of 2 or 3 cycles of chemoimmunotherapy followed by high-dose therapy and autologous Hematopoietic Stem Cell Transplantation (HSCT), in patients who attained Complete Remission or Partial Remission (N=179). Patients randomized to YESCARTA® underwent leukapheresis, and then, lymphodepleting chemotherapy with Fludarabine 30 mg/m2/day and Cyclophosphamide 500 mg/m2/day for 3 days, followed by a single infusion of YESCARTA® at 2 × 10⁶ CAR T cells/kg. Corticosteroid bridging therapy was allowed for patients with high disease burden at screening. Lack of response to chemotherapy was the most common reason for not receiving autologous HSCT, and 35% received on-protocol HSCT. Both treatment groups were well balanced. The median patient age was 59 years, 30% of patients were aged 65 years or older, 79% of patients had Stage III/IV disease, 74% of patients were primary refractory to their frontline therapy, 16% had high-grade B-cell lymphoma (double/triple-hit), and 44% of patients had elevated LDH levels. Key stratification factors included response to frontline therapy and second-line Age-Adjusted International Prognostic Index (sAAIPI) stage. The Primary endpoint was Event Free Survival (EFS), defined as time from randomization to disease progression, start of new lymphoma therapy, or death, and was determined by an Independent Review Committee (IRC). Secondary endpoints included Objective Response Rates (ORR), Overall Survival (OS), Progression Free Survival (PFS), Duration of Response, Safety, and Patient Reported Outcomes (PRO).

At a median follow-up of 24.9 months, the EFS was significantly longer in the YESCARTA® group and the estimated median EFS was 8.3 months in the YESCARTA® group compared with 2.0 months for those receiving Standard of Care chemotherapy (HR=0.40; P<0.0001). The estimated 18-month EFS rate was 41.5% in the YESCARTA® group and 17.0% in the standard therapy group. The IRC-assessed best ORR was statistically significantly higher in the YESCARTA® arm compared to the standard therapy arm (83% versus 50% respectively) and Complete Response rate was 65% versus 32% respectively. EFS was superior with YESCARTA® over Standard of Care across all key patient subgroups, including age, response to first-line therapy at randomization, second-line Age-Adjusted International Prognostic Index (sAAIPI) stage, and prognostic markers.

The authors concluded that ZUMA-7 met its primary EFS end point, demonstrating statistically significant and clinically meaningful improvement in efficacy with YESCARTA® compared to second-line Standard of Care in relapsed/ refractory Large B-Cell Lymphoma, with a 4-fold greater median EFS, a 33% higher Objective Response Rate, a doubling of the Complete Response rate, Event Free Survival improvements across key subgroups, and should therefore be a new standard for patients with second-line relapsed/refractory Large B-Cell Lymphoma. The NCCN updated its clinical practice guidelines to include YESCARTA® as a Category 1 recommendation for patients with early relapsed or primary-refractory Diffuse Large B-Cell Lymphoma.

Primary analysis of ZUMA 7: a phase 3 randomized trial of axicabtagene ciloleucel (axi-cel) versus standard of care therapy in patients with relapsed/refractory large B-cell lymphoma. Locke F, Miklos DB, Jacobson CA, et al. Blood. 2021;138(suppl 1):2. doi:10.1182/blood-2021-148039

FDA Approves PSMA Targeted Therapy for Metastatic Castrate Resistant Prostate Cancer

March 31, 2022March 31, 2022 RR

SUMMARY: The FDA on March 23, 2022, approved PLUVICTO® (Lutetium Lu 177 vipivotide tetraxetan) for the treatment of adult patients with Prostate-Specific Membrane Antigen (PSMA)-positive metastatic Castration-Resistant Prostate Cancer (mCRPC), who had been treated with Androgen Receptor (AR) pathway inhibition and Taxane-based chemotherapy. The FDA also approved LOCAMETZ® (Gallium Ga 68 gozetotide), a radioactive diagnostic agent for Positron Emission Tomography (PET) of PSMA-positive lesions, including selection of patients with metastatic prostate cancer for whom PLUVICTO® PSMA-directed therapy is indicated. LOCAMETZ® is the first radioactive diagnostic agent approved for patient selection in the use of a radioligand therapeutic agent.

The development and progression of prostate cancer is driven by androgens. Androgen Deprivation Therapy (ADT) or testosterone suppression has therefore been the cornerstone of treatment of advanced prostate cancer, and is the first treatment intervention. Approximately 10-20% of patients with advanced Prostate cancer will progress to Castration Resistant Prostate Cancer (CRPC) within five years during ADT, and over 80% of these patients will have metastatic disease at the time of CRPC diagnosis. Among those patients without metastases at CRPC diagnosis, 33% are likely to develop metastases within two years. Progression to Castration Resistant Prostate Cancer (CRPC) often manifests itself with a rising PSA (Prostate Specific Antigen) and the estimated mean survival of patients with CRPC is 9-36 months, and there is therefore an unmet need for new effective therapies.

Prostate-Specific Membrane Antigen (PSMA) is a Type II cell membrane glycoprotein that is selectively expressed in prostate cells, with high levels of expression in prostatic adenocarcinoma. PSMA is a therefore an excellent target for molecular imaging and therapeutics, due to its high specificity for prostate cancer.

PLUVICTO® is a radiopharmaceutical that targets PSMA. It is comprised of Lutetium-177, a cytotoxic radionuclide , linked to the ligand PSMA-617, a small molecule designed to bind with high affinity to PSMA. Radioligand therapy with PLUVICTO® targets PSMA and releases its payload of lethal beta radiation into the prostate cancer cell. The antitumor activity and safety PLUVICTO® have been established previously in a Phase II study (Lancet Oncol. 2018;19:825-833).

VISION is an international, randomized, open-label Phase III study in which the benefit of PLUVICTO® was evaluated in men with PSMA-positive mCRPC, previously treated with second generation Androgen Receptor signaling pathway inhibitor (XTANDI® -Enzalutamide or ZYTIGA®-Abiraterone acetate), and 1 or 2 taxane chemotherapy regimens. In this trial, 831 patients were randomized 2:1 to receive PLUVICTO® 7.4 GBq (200 mCi) every 6 weeks for up to a total of 6 cycles plus Standard of Care as determined by the treating physician (N=551), or Standard of Care only (N=280). Both treatment groups were well balanced and this trial excluded patients treated with XOFIGO® (Radium-223). All enrolled patients received a GnRH analog or had prior bilateral orchiectomy and had a castrate level or serum/plasma testosterone of lower than 50ng/dL. PET imaging with LOCAMETZ® was used to determine PSMA positivity by central review. PSMA-positive mCRPC was defined as having at least one tumor lesion with LOCAMETZ® uptake greater than normal liver. Patients were excluded from enrollment if any lesions exceeding certain size criteria in the short axis had uptake less than or equal to uptake in normal liver. The Primary endpoints were radiographic Progression Free Survival (rPFS) by Independent Central Review (ICR) and Overall Survival (OS). Secondary endpoints included Objective Response Rate (ORR), Disease Control Rate (DCR), and time to first Symptomatic Skeletal Event (SSE). The median study follow up was 20.9 months.

Treatment with the combination of PLUVICTO® plus Standard of Care resulted in a statistically significant improvement in the Primary endpoints of Overall Survival and radiographic Progression Free Survival. PLUVICTO® plus Standard of Care significantly improved rPFS by 60%, compared to Standard of Care alone (median rPFS 8.7 versus 3.4 months, HR=0.40; P<0.001). The median OS was also significantly improved by 38% in the study group (median OS 15.3 versus 11.3 months, HR=0.62; P<0.001). All key secondary endpoints including Objective Response Rate, Disease Control Rate, and time to first Symptomatic Skeletal Event were statistically significant, and in favor of PLUVICTO® plus Standard of Care. The most common adverse reactions in patients receiving PLUVICTO® were fatigue, dry mouth, nausea, decreased appetite, constipation, anemia, lymphopenia, thrombocytopenia, hypocalcemia and hyponatremia.

It was concluded that radioligand therapy with PLUVICTO® significantly improved radiographic Progression Free Survival and Overall Survival when added to Standard of Care, compared with Standard of Care alone, in men with PSMA-positive metastatic Castration Resistant Prostate Cancer.

Lutetium-177-PSMA-617 for Metastatic Castration-Resistant Prostate Cancer. Sartor O, de Bono J, Chi KN, et al. N Engl J Med 2021; 385:1091-1103.

FDA Approves Single Agent KEYTRUDA® for Advanced Endometrial Carcinoma

March 31, 2022March 31, 2022 RR

SUMMARY: The FDA on March 21, 2022 approved KEYTRUDA® (Pembrolizumab) as a single agent, for patients with advanced endometrial carcinoma that is MicroSatellite Instability-High (MSI-H) or MisMatch Repair deficient (dMMR), as determined by an FDA-approved test, who have disease progression following prior systemic therapy in any setting, and who are not candidates for curative surgery or radiation. The FDA also approved VENTANA MMR RxDx Panel (Ventana Medical Systems/Roche Tissue Diagnostics) as a companion diagnostic device to select patients with dMMR in solid tumors that are eligible for treatment with KEYTRUDA® The FDA previously approved the FoundationOne CDx (F1CDx, Foundation Medicine, Inc.) as a companion diagnostic device to select patients with MSI-H in solid tumors that are eligible for treatment with KEYTRUDA®.

The American Cancer Society estimates that approximately 65,950 new cases of uterine cancer will be diagnosed in 2022 and about 12,550 individuals will die of the disease. Endometrial carcinoma is the second most prevalent gynecologic cancer in women worldwide, and its incidence has been increasing. Risk factors include age, factors that influence hormone levels such as obesity and estrogen replacement therapy, family history, diet and exercise, drugs such as Tamoxifen, etc. Patients with advanced or recurrent endometrial cancer are often treated with a combination of Carboplatin and Paclitaxel. Treatment options following failure of first-line therapy for this patient group however are limited, with single agent response rates of 10-15% and 5-year survival rates of approximately 17%.

The DNA MisMatchRepair (MMR) system is responsible for molecular surveillance and works as an editing tool that identifies errors within the microsatellite regions of DNA and removes them. Defective MMR system leads to MSI (Micro Satellite Instability) and hypermutation, with the expression of tumor-specific neoantigens at the surface of cancer cells, triggering an increase in CD3-positive, CD8-positive, and Programmed Death-1 (PD-1) expressing Tumor Infiltrating Lymphocytes and Programmed Death Ligand-1 (PD-L1) expressing intraepithelial and peritumoral immune cells, compared with MicroSatellite Stable cancers. This results in an enhanced antitumor immune response.

MSI is therefore a hallmark of defective/deficient DNA MisMatchRepair (dMMR) system. Defective MMR can be a sporadic or heritable event and can manifest as a germline mutation occurring in MMR genes including MLH1, MSH2, MSH6 and PMS2. This produces Lynch Syndrome often called Hereditary Nonpolyposis Colorectal Carcinoma-HNPCC, an Autosomal Dominant disorder that is often associated with a high risk for Colorectal and Endometrial carcinoma, as well as several other malignancies including Ovary, Stomach, Small bowel, Hepatobiliary tract, Brain and Skin. MSI is a hallmark of Lynch Syndrome-associated cancers. MSI high tumors tend to have better outcomes and this has been attributed to the abundance of Tumor Infiltrating Lymphocytes in these tumors from increase immunogenicity. These tumors therefore are susceptible to blockade with Immune Checkpoint Inhibitors.

MSI testing is performed using a PCR or NGS based assay and MSI-High refers to instability at 2 or more of the 5 mononucleotide repeat markers and MSI-Low refers to instability at 1 of the 5 markers. Patients are considered Micro Satellite Stable (MSS) if no instability occurs. MSI-L and MSS are grouped together because MSI-L tumors are uncommon and behave similar to MSS tumors. Tumors considered MSI-H have deficiency of one or more of the DNA MMR genes. MMR gene deficiency can be detected by ImmunoHistoChemistry (IHC). NCCN Guidelines recommend MMR or MSI testing for all patients with a history of Colon or Rectal cancer. Unlike Colorectal and Endometrial cancer, where MSI-H/dMMR testing is routinely undertaken, the characterization of Lynch Syndrome across heterogeneous MSI-H/dMMR tumors is unknown.

KEYTRUDA® (Pembrolizumab) is a fully humanized, Immunoglobulin G4, anti-PD-1, monoclonal antibody, that binds to the PD-1 receptor and blocks its interaction with ligands PD-L1 and PD-L2, thereby undoing PD-1 pathway-mediated inhibition of the immune response and unleashing the tumor-specific effector T cells. The FDA in 2017 granted accelerated approval to KEYTRUDA® for patients with advanced MSI-High or dMMR solid tumors, that have progressed following prior treatment, and who have no satisfactory alternative treatment options. This has led to routine MSI-H/dMMR testing in advanced solid tumors. The FDA in 2021 also approved KEYTRUDA® in combination with the multireceptor Tyrosine Kinase Inhibitor LENVIMA® (Lenvatinib) for patients with advanced endometrial carcinoma, irrespective of tumor MSI status based on the KEYNOTE-146 study.

KEYNOTE-158 is a multicenter, nonrandomized, open-label, multicohort, Phase II trial of KEYTRUDA® evaluating predictive biomarkers, in patients with advanced unresectable and/or metastatic solid tumors, who had progressed on standard of care therapy. The present FDA approval was based on the results from a total of 90 patients with MSI-H/dMMR endometrial cancer, who were enrolled in cohort D (11 patients) and cohort K (79 patients) of KEYNOTE-158 trial. This group of previously treated patients received KEYTRUDA® 200 mg IV once every 3 weeks for 35 cycles. The median patient age was 64 years, 48% had received 2 or more lines of prior therapy, and the majority of patients (68%) had received prior radiation therapy. The median duration of treatment was 8.3 months. The Primary end point was Objective Response Rate (ORR) by independent central radiologic review. Secondary end points included Duration of Response, Progression Free Survival (PFS), Overall Survival (OS), and Safety.

The Objective Response Rate was 48%, and median Duration of Response was not reached after a median follow up of 42.6 months. The median PFS was 13.1 months, and median Overall Survival was Not Reached. No new safety signals were identified and the immune-mediated adverse events or infusion reactions occurred in 28% of patients and 7% were Grades 3-4, with no fatal events.

It was concluded that KEYTRUDA® demonstrated robust and durable antitumor activity with manageable toxicity in patients with advanced MSI-H/dMMR endometrial cancer, and should be considered as a treatment option for patients with advanced MSI-H/dMMR endometrial cancer, following failure on prior therapy.

Pembrolizumab in Patients With Microsatellite Instability–High Advanced Endometrial Cancer: Results From the KEYNOTE-158 Study. O’Malley DM, Bariani GM, Cassier PA, et al. DOI: 10.1200/JCO.21.01874 Journal of Clinical Oncology 40, no. 7 (March 01, 2022) 752-761. Published online January 06, 2022.

KISQALI® Plus FEMARA® Improves Overall Survival in Advanced Breast Cancer

March 24, 2022March 24, 2022 RR

SUMMARY: Breast cancer is the most common cancer among women in the US and about 1 in 8 women (12%) will develop invasive breast cancer during their lifetime. Approximately 290,560 new cases of breast cancer will be diagnosed in 2022 and about 43,780 individuals will die of the disease, largely due to metastatic recurrence. Approximately 70% of breast tumors express Estrogen Receptors and/or Progesterone Receptors and these patients are often treated with anti-estrogen therapy as first line treatment. However, resistance to hormonal therapy occurs in a majority of the patients.

Cyclin Dependent Kinases (CDK) play a very important role to facilitate orderly and controlled progression of the cell cycle. Genetic alterations in these kinases and their regulatory proteins have been implicated in various malignancies. Cyclin Dependent Kinases 4 and 6 (CDK4 and CDK6) phosphorylate RetinoBlastoma protein (RB), and initiate transition from the G1 phase to the S phase of the cell cycle. RetinoBlastoma protein has antiproliferative and tumor-suppressor activity and phosphorylation of RB protein nullifies its beneficial activities. CDK4 and CDK6 are activated in hormone receptor positive breast cancer, promoting breast cancer cell proliferation. Further, there is evidence to suggest that endocrine resistant breast cancer cell lines depend on CDK4 for cell proliferation and associated with increased expression of CDK4. The understanding of the role of Cyclin Dependent Kinases in the cell cycle, has paved the way for the development of CDK inhibitors. Cell-Cycle-Inhibition-by-RIBOCICLIB

KISQALI® (Ribociclib) is an orally bioavailable, selective, small-molecule inhibitor of CDK4/6, preferentially inhibiting CDK4, that blocks the phosphorylation of RetinoBlastoma protein, thereby preventing cell-cycle progression and inducing G1 phase arrest. In a phase 1b study involving postmenopausal women with ER positive, HER2-negative advanced breast cancer, KISQALI® in combination with FEMARA® (Letrozole) demonstrated an Overall Response Rate (ORR) of 46% and a Clinical Benefit Rate of 79%, in treatment-naïve patients with advanced breast cancer. This led to the design of MONALEESA-2 trial.

MONALEESA-2 trial is a randomized, double-blind, placebo-controlled, Phase III study in which 668 patients were randomly assigned in a 1:1 ratio to receive either KISQALI® plus FEMARA® or placebo plus FEMARA®. Eligible patients included post-menopausal women with HR-positive, HER2-negative advanced or metastatic breast cancer who had received no prior therapy for advanced disease. Treatment consisted of oral KISQALI® 600 mg daily on a 3-weeks on and 1-week off schedule, in 28-day treatment cycles plus FEMARA® 2.5 mg orally daily on a continuous schedule or placebo plus FEMARA®. Patients were stratified according to the presence or absence of liver or lung metastases and treatment was continued until disease progression or unacceptable toxicity. No treatment crossover was allowed. The median age was 62 years, close to 60% of the patients had visceral metastases, and patients were stratified according to the presence or absence of liver or lung metastases. The Primary end point was Progression Free Survival (PFS) and Secondary end points included Overall Survival (OS), Overall Response Rate (ORR), Clinical Benefit Rate (Overall Response plus Stable disease lasting 24 weeks or more), Safety, and Quality of Life assessments.

In the primary and updated analyses of the MONALEESA-2 trial, PFS was significantly longer with KISQALI® plus FEMARA® than with placebo plus FEMARA® (25.3 months versus 16.0 months; HR for disease progression or death=0.57; P<0.001). The Overall Survival data were immature at the time of the primary and updated analyses. The authors have now reported the findings from the protocol-specified final analysis of Overall Survival, which is a key Secondary end point.

After a median follow up of 6.6 years, a significant Overall Survival benefit was observed with KISQALI® plus FEMARA®, compared to placebo plus FEMARA®. The median Overall Survival was 63.9 months with KISQALI® plus FEMARA® and 51.4 months with placebo plus FEMARA® (HR=0.76; two-sided P=0.008). This Overall Survival benefit was consistent across all prespecified subgroups. The median time to first subsequent chemotherapy was 50.6 months in the KISQALI® group and 38.9 months in the placebo group (HR for receipt of first chemotherapy=0.74). No new safety signals were observed.

It was concluded from the analysis of the MONALEESA-2 trial that first line therapy with KISQALI® plus FEMARA® showed a significant Overall Survival benefit as compared with placebo plus FEMARA®, in patients with HR-positive, HER2-negative advanced breast cancer, with a 24% relative reduction in the risk of death. The authors added that MONALEESA trials of KISQALI® have shown a consistent Overall Survival benefit regardless of accompanying endocrine therapy, line of therapy, or menopausal status.

Overall Survival with Ribociclib plus Letrozole in Advanced Breast Cancer. Hortobagyi GN, Stemmer SM, Burris HA, et al. N Engl J Med 2022; 386:942-950

FDA Approves LAG-3 Inhibitor OPDUALAG® and OPVIDO® in Advanced Untreated Melanoma

March 24, 2022March 24, 2022 RR

SUMMARY: The FDA on March 18, 2022, approved OPDIVO® (Nivolumab) and OPDUALAG® (Relatlimab-rmbw), for adult and pediatric patients 12 years of age or older, with unresectable or metastatic melanoma. The American Cancer Society’s estimates that for 2022, about 99,780 new cases of melanoma of the skin will be diagnosed in the United States and 7,650 people are expected to die of the disease. The rates of melanoma have been rising rapidly over the past few decades, but this has varied by age.

A better understanding of Immune checkpoints has opened the doors for the discovery of novel immune targets. Immune checkpoints are cell surface inhibitory proteins/receptors that harness the immune system and prevent uncontrolled immune reactions. Survival of cancer cells in the human body may be related to their ability to escape immune surveillance, by inhibiting T lymphocyte activation. Under normal circumstances, inhibition of an intense immune response and switching off the T cells of the immune system is accomplished by Immune checkpoints or gate keepers. With the recognition of Immune checkpoint proteins and their role in suppressing antitumor immunity, antibodies have been developed that target the membrane bound inhibitory Immune checkpoint proteins/receptors such as CTLA-4 (Cytotoxic T-Lymphocyte Antigen 4, also known as CD152), PD-1(Programmed cell Death 1), etc. By blocking the Immune checkpoint proteins, T cells are unleashed, resulting in T cell proliferation, activation and a therapeutic response.

YERVOY® (Ipilimumab), a fully human immunoglobulin G1 monoclonal antibody that blocks Immune checkpoint protein/receptor CTLA-4 was compared with PD-1 inhibitors, OPDIVO® (Nivolumab) and KEYTRUDA® (Pembrolizumab) in patients with advanced melanoma, and both OPDIVO® and KEYTRUDA® have demonstrated superior Overall Survival (OS), Progression Free Survival (PFS), and Objective Response Rate (ORR), and with a better safety profile. In the CheckMate 067, which is a double-blind Phase III study, results from the 6.5 year analysis showed that a combination of OPDIVO® plus YERVOY® demonstrated significant improvement in OS and PFS, when compared to single agent OPDIVO® or single agent YERVOY®.

In an attempt to improve outcomes and enhance the risk-benefit profiles of immunotherapy combinations, alternate Immune checkpoints are being explored. LAG-3 (Lymphocyte-Activation Gene 3 (LAG-3), is a cell-surface receptor expressed on immune cells including activated CD4+ T cells, and negatively regulates T-cell proliferation, inhibits T-cell activation and effector T-cell function. LAG-3 is upregulated in several tumor types, including malignant melanoma.

OPDUALAG® (Relatlimab) is a first-in-class human IgG4 LAG-3–blocking antibody that binds to LAG-3 and restores the effector function of exhausted T cells, resulting in T cell proliferation, activation and a therapeutic response. In preclinical studies, dual inhibition of LAG-3 and PD-1 showed synergistic antitumor activity, and in a Phase I/II trial, the combination of OPDUALAG® and OPDIVO®, demonstrated durable Objective Responses in patients with Relapsed/Refractory melanoma following treatment with PD-1 inhibitors.

RELATIVITY-047 is a Phase II/III, global, multicenter, double-blind, randomized trial in which a fixed-dose combination of OPDUALAG® and OPDIVO® was compared with OPDIVO® alone, in patients with previously untreated metastatic or unresectable melanoma. In this study, 714 patients were randomly assigned 1:1 to receive OPDUALAG® 160 mg and OPDIVO® 480 mg in a fixed-dose combination (N=355) or single agent OPDIVO® 480 mg (N=359). Both regimens were administered as an IV infusion over 60 minutes every 4 weeks, and treatment was continued until disease progression, unacceptable toxicities, or withdrawal of consent. Both treatment groups were well balanced and patients were stratified according to LAG-3 expression (1% or more versus less than 1%), PD-L1 expression (1% or more versus less than 1%), BRAF V600 mutation status, and metastasis stage (M0 or M1 with normal LDH levels versus M1 with elevated LDH levels). More patients in the OPDUALAG®- OPDIVO® group had Stage M1c disease, and a larger proportion had three or more sites with at least one metastatic lesion. The Primary end point was Progression Free Survival (PFS) as assessed by blinded Independent Central Review. Secondary end points included Overall Survival and Objective Response Rate (ORR). The median follow up was 13.2 months and the use of subsequent therapies upon progression was similar in the two treatment groups.

The median PFS was 10.1 months with OPDUALAG®- OPDIVO® as compared with 4.6 months with OPDIVO® (HR=0.75; P=0.006). The PFS benefit at 12 months with OPDUALAG®- OPDIVO® was 47.7% compared to 36.0% with OPDIVO®. The PFS benefit was more so with Relatlimab- OPDIVO® across key prespecified subgroups, compared to single agent OPDIVO®. Patients with poor prognosis characteristics, such as visceral metastases, high tumor burden, elevated levels of serum LDH, or mucosal or acral melanoma, had better outcomes with OPDUALAG®- OPDIVO® combination, than with single agent OPDIVO®. Further, a benefit with OPDUALAG®- OPDIVO® was also noted across BRAF mutant and wild-type subgroups, compared to OPDIVO®. Expression of LAG-3 or PD-L1 was not useful in predicting a benefit of OPDUALAG®- OPDIVO® over single agent OPDIVO® and appears to NOT have a clear role in treatment selection.

Grade 3 or 4 toxicities occurred in 18.9% of patients in the OPDUALAG®- OPDIVO® group and in 9.7% of patients in the single agent OPDIVO® group. The Safety profile of OPDUALAG®- OPDIVO® appeared favorable, when compared with dual checkpoint inhibition with a CTLA-4 inhibitor and PD-1 inhibitor combination (YERVOY®- OPDIVO®) in the CheckMate 067 trial, in which Adverse Events were noted in 59% of patients.

It was concluded that inhibition of two immune checkpoints, LAG-3 and PD-1, provided greater benefit with regards to Progression Free Survival, than inhibition of PD-1 alone, in patients with previously untreated metastatic or unresectable melanoma. The authors added that these results validate blocking LAG-3 in combination with PD-1 as a therapeutic strategy for patients with melanoma, and establishes LAG-3 as the third immune checkpoint pathway, thus providing more treatment options for patients with advanced melanoma.

Relatlimab and Nivolumab versus Nivolumab in Untreated Advanced Melanoma. Tawbi HA, Schadendorf D, Lipson EJ, et al. for the RELATIVITY-047 Investigators. N Engl J Med 2022;386:24-34.

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Category: Hem/Onc Updates