LBA71 Systemic cancer treatment-related outcomes in patients with SARS-CoV-2 infection: A CCC19 registry analysis

Background: SARS-CoV-2 is associated with diverse clinical presentations ranging from asymptomatic infection to lethal complications. Small studies have suggested inferior outcomes in patients (pts) on active cancer treatment. This finding was not independently validated in our prior report on 928 pts, which included treatments administered within 4 weeks of COVID-19 diagnosis. Here, we examine outcomes related to systemic cancer treatment within one year of lab-confirmed SARS-CoV-2 infection in an expanded cohort. Method(s): The COVID-19 and Cancer Consortium (CCC19) registry (NCT04354701) was queried for pts ever receiving systemic treatment. Treatment type, cancer type, stage, and COVID-19 outcomes were examined. Pts were stratified by time from last treatment administration: <2 wk, 2-4 wk, 1-3 mo, or 3-12 mo. Standardized incidence ratios (SIR) of mortality by treatment type and timing were calculated. Result(s): As of 31 July 2020, we analyzed 3920 pts;42% received systemic anti-cancer treatment within 12 mo (Table). 159 distinct medications were administered. The highest rate of COVID-19-associated complications were observed in pts treated within 1-3 months prior to COVID-19;all-cause mortality in this group was 26%. 30-day mortality by most recent treatment type was 20% for chemotherapy, 18% for immunotherapy, 17% for chemoradiotherapy, 29% for chemoimmunotherapy, 20% for targeted therapy, and 11% for endocrine therapy. SIR of mortality was highest for chemoimmunotherapy or chemotherapy <2 wks, and lowest for endocrine treatments. A high SIR was also found for targeted agents within 3-12 mo. Pts untreated in the year prior to COVID-19 diagnosis had a mortality of 14%. [Formula presented] Conclusion(s): 30-day mortality was highest amongst cancer pts treated 1-3 months prior to COVID-19 diagnosis and those treated with chemoimmunotherapy. Except for endocrine therapy, mortality for subgroups was numerically higher than in pts untreated within a year prior to COVID-19 diagnosis. Clinical trial identification: NCT04354701. Legal entity responsible for the study: The COVID-19 and Cancer Consortium (CCC19). Funding(s): National Cancer Institute (P30 CA068485). Disclosure: T.M. Wise-Draper: Research grant/Funding (self), Travel/Accommodation/Expenses: AstraZeneca;Research grant/Funding (self): BMS;Research grant/Funding (self): Tesaro/GSK;Advisory/Consultancy: Shattuck Labs;Leadership role, Travel/Accommodation/Expenses, HNC POA Lead: Caris Life Sciences;Research grant/Funding (self), Travel/Accommodation/Expenses: Merck;Travel/Accommodation/Expenses: Eli Lilly;Travel/Accommodation/Expenses: Bexion. A. Elkrief: Research grant/Funding (self): AstraZeneca. B.I. Rini: Advisory/Consultancy, Research grant/Funding (self), Travel/Accommodation/Expenses: Merck;Advisory/Consultancy, Research grant/Funding (self): Roche;Advisory/Consultancy, Research grant/Funding (self), Travel/Accommodation/Expenses: Pfizer;Advisory/Consultancy, Research grant/Funding (self): AVEO;Advisory/Consultancy, Research grant/Funding (self), Travel/Accommodation/Expenses: BMS;Advisory/Consultancy: arravive;Advisory/Consultancy: 3D medicines;Advisory/Consultancy: Synthorx;Advisory/Consultancy: Surface Oncology;Shareholder/Stockholder/Stock options: PTC Therapeutics;Research grant/Funding (self): AstraZeneca. D.B. Johnson: Advisory/Consultancy: Array Biopharma;Advisory/Consultancy, Research grant/Funding (self): BMS;Advisory/Consultancy: Janssen;Advisory/Consultancy: Merck;Advisory/Consultancy: Novartis;Research grant/Funding (self): Incyte;Leadership role: ASCO melanoma scientific committee chair;Leadership role: NCCN Melanoma committee. G. Lopes: Honoraria (self), Travel/Accommodation/Expenses: Boehringer Ingelheim;Advisory/Consultancy, Research grant/Funding (institution), Travel/Accommodation/Expenses: Pfizer;Advisory/Consultancy, Research grant/Funding (self), Research grant/Funding (institution): AstraZeneca;Research grant/Funding (institution): Merck;Research grant/Funding (institution): EMD Serono;Research gr

Racial and ethnic disparities among patients with breast cancer and COVID-19

Background: Racial/ethnic minorities have disproportionately increased risk of contracting COVID-19 and experiencing severe illness;they also have worse breast cancer (BC) outcomes. COVID-19 outcomes among racial/ethnic minorities with BC are currently unknown. We sought to compare clinicopathologic characteristics and COVID-19 outcomes stratified by race/ethnicity. Methods: The COVID-19 and Cancer Consortium registry (NCT04354701) was used to identify patients with invasive BC and laboratory-confirmed SARS-CoV-2 diagnosed in the U.S. between 2020-03-06 and 2021-02-04. The primary analysis was restricted to women who selfidentified as non-Hispanic White (NHW), nonHispanic Black (NHB), or Hispanic (H). Demographic, cancer characteristics, and COVID-19 outcomes were evaluated. COVID-19 outcomes included: hospital admission, intensive care unit (ICU) admission, mechanical ventilation, death within 30 days of COVID-19 diagnosis and death from any cause during follow-up. Descriptive statistics were used to compare clinicopathologic characteristics and Fisher exact tests were used to compare COVID19 outcomes across the 3 racial/ethnic groups. Results: A total of 1133 patients were identified of which 1111 (98%) were women;of which 575 (52%) NHW, 243 (22%) NHB, 183 (16%) H, and 110 (10%) other/unknown. Baseline characteristics differed among racial/ethnic groups. H were younger (median age: NHW 63y;NHB 62y;H 54y) and more likely to be never smokers (NHW 62%;NHB 62%;H 78%). NHB had higher rates of obesity (NHW 40%;NHB 54%;H 46%), diabetes (NHW 16 %;NHB 32%;H 20%) and combined moderate and severe baseline COVID-19 at presentation (NHW 28%;NHB 42%;H 28%). Cancer characteristics are as shown (Table). Significant differences were observed in outcomes across racial/ethnic groups including higher rates of hospital admission (NHW 34%;NHB 49%;H 34%;P <0.001), mechanical ventilation (NHW 3%;NHB 9%;H 5%;P=0.002), 30-day mortality (NHW 6%;NHB 9%;H 4%;P=0.043) and total mortality (NHW 8%;NHB 12%;H 5%;P=0.05) among NHB compared to NHW and H. Conclusions: This is the largest study to show significant differences in COVID-19 outcomes by racial/ethnic groups of women with BC. The adverse outcomes in NHB could be due to higher moderate to severe COVID-19 at presentation and preexisting comorbidities. H did not have worse outcomes despite having more active disease and recent anti-cancer therapy, including with cytotoxic chemotherapy - potentially due to younger age and nonsmoking status. (Table Presented).

Supportive care in patients with cancer during the COVID-19 pandemic.

Cancer care has been profoundly impacted by the global pandemic of severe acute respiratory syndrome coronavirus 2 disease (coronavirus disease 2019, COVID-19), resulting in unprecedented challenges. Supportive care is an essential component of cancer treatment, seeking to prevent and manage chemotherapy complications such as febrile neutropenia, anaemia, thrombocytopenia/bleeding, thromboembolic events and nausea/vomiting, all of which are common causes of hospitalisation. These adverse events are an essential consideration under routine patient management, but particularly so during a pandemic, a setting in which clinicians aim to minimise patients' risk of infection and need for hospital visits. Professional medical oncology societies have been providing updated guidelines to support health care professionals with the management, treatment and supportive care needs of their patients with cancer under the threat of COVID-19. This paper aims to review the recommendations made by the most prominent medical oncology societies for devising and modifying supportive care strategies during the pandemic.

Clinical impact of COVID-19 on patients with cancer: Data from the COVID-19 and Cancer Consortium (CCC19)

Background: There are limited data on COVID-19 in patients with cancer. We characterize the outcomes of patients with cancer and COVID-19 and identify potential prognostic factors. Methods: The COVID- 19 and Cancer Consortium (CCC19) cohort study includes patients with active or prior hematologic or invasive solid malignancies reported across academic and community sites. Results: We included 1,018 cases accrued March-April 2020. Median age was 66 years (range, 18-90). Breast (20%) and prostate (16%) cancers were most prevalent;43% of patients were on active anti-cancer treatment. At time of data analysis, 106 patients (10.4%) have died and 26% met the composite outcome of death, severe illness requiring hospitalization, and/or mechanical ventilation. In multivariable logistic regression analysis, independent factors associated with increased 30- day mortality were age, male sex, former smoking, ECOG performance status (2 versus 0/1: partially adjusted odds ratio (pAOR) 2.74, 95% CI 1.31-5.7;3/4 versus 0/1: pAOR 5.34, 95% CI 2.44-11.69), active malignancy (stable/responding, pAOR 1.93, 95% CI 1.06-3.5;progressing, pAOR 3.79, 95% CI 1.78-8.08), and receipt of azithromycin and hydroxychloroquine. Tumor type, race/ethnicity, obesity, number of comorbidities, recent surgery, and type of active cancer therapy were not significant factors for mortality. Conclusions: All-cause 30-day mortality and severe illness in this cohort were significantly higher than previously reported for the general population and were associated with general risk factors as well as those unique to patients with cancer. Cancer type and treatment were not independently associated with increased 30-day mortality. Longer follow-up is needed to better understand the impact of COVID-19 on outcomes in patients with cancer, including the ability to continue specific cancer treatments.