Use of Total Neoadjuvant Therapy for Locally Advanced Rectal Cancer: Initial Results From the Pembrolizumab Arm of a Phase 2 Randomized Clinical Trial

Osama E Rahma; Greg Yothers; Theodore S Hong; Marcia M Russell; Y Nancy You; William Parker; Samuel A Jacobs; Linda H Colangelo; Peter C Lucas; Marc J Gollub; William A Hall; Lisa A Kachnic; Namrata Vijayvergia; Mark A O’Rourke; Bryan A Faller; Richard K Valicenti; Tracey E Schefter; Katherine M Moxley; Radhika Kainthla; Philip J Stella; Elin Sigurdson; Norman Wolmark; Thomas J George

doi:10.1001/jamaoncol.2021.1683

. 2021 Jul 1;7(8):1–6. doi: 10.1001/jamaoncol.2021.1683

Use of Total Neoadjuvant Therapy for Locally Advanced Rectal Cancer

Initial Results From the Pembrolizumab Arm of a Phase 2 Randomized Clinical Trial

Osama E Rahma ^1,^2,^✉, Greg Yothers ^1,³, Theodore S Hong ^1,⁴, Marcia M Russell ^1,^5,⁶, Y Nancy You ⁷, William Parker ^1,⁸, Samuel A Jacobs ¹, Linda H Colangelo ^1,³, Peter C Lucas ^1,⁹, Marc J Gollub ¹⁰, William A Hall ^1,¹¹, Lisa A Kachnic ^1,^12,¹³, Namrata Vijayvergia ^1,¹⁴, Mark A O’Rourke ^1,¹⁵, Bryan A Faller ¹⁶, Richard K Valicenti ¹⁷, Tracey E Schefter ^1,¹⁸, Katherine M Moxley ^1,¹⁹, Radhika Kainthla ²⁰, Philip J Stella ^1,²¹, Elin Sigurdson ²², Norman Wolmark ^1,²³, Thomas J George ^1,²⁴

¹NRG Oncology, Philadelphia, Pennsylvania

²Department of Medical Oncology, Dana-Farber Cancer Institute/Alliance, Boston, Massachusetts

³Department of Biostatistics, University of Pittsburgh, Pittsburgh, Pennsylvania

⁴Department of Radiation Oncology, Massachusetts General Hospital, Boston

⁵Veterans Affairs Greater Los Angeles Healthcare System, Los Angeles, California

⁶David Geffen School of Medicine at UCLA, Los Angeles, California

⁷Department of Surgical Oncology, University of Texas MD Anderson Cancer Center, Houston

⁸Department of Medical Physics, McGill University Health Centre, Montréal, Quebec, Canada

⁹Department of Pathology, UPMC Hillman Cancer Center, Pittsburgh, Pennsylvania

¹⁰Department of Radiology, Memorial Sloan Kettering Cancer Center, New York, New York

¹¹Department of Radiation Oncology, Medical College of Wisconsin, Milwaukee

¹²Department of Radiation Oncology, Columbia University Irving Medical Center, Herbert Irving Comprehensive Cancer Center, New York, New York

¹³SWOG Cancer Research Network, San Antonio, Texas

¹⁴Fox Chase Cancer Center, Philadelphia, Pennsylvania

¹⁵National Cancer Institute Community Oncology Research Program, Prisma Health Cancer Institute, Greenville, South Carolina

¹⁶Missouri Baptist Medical Center, Heartland Cancer Research, National Cancer Institute Community Oncology Research Program, St Louis

¹⁷Department of Radiation Oncology, UC Davis, Davis, California

¹⁸Department of Radiation Oncology, University of Colorado Cancer Center, Aurora

¹⁹Section of Gynecologic Oncology, University of Oklahoma Stephenson Cancer Center, Oklahoma City

²⁰Department of Internal Medicine, UT Southwestern Medical Center, Dallas, Texas

²¹Department of Medical Oncology, St Joseph Mercy Hospital, Ann Arbor, Michigan

²²Department of Surgical Oncology, Fox Chase Cancer Center, Philadelphia, Pennsylvania

²³Department of Surgery, University of Pittsburgh, Pittsburgh, Pennsylvania

²⁴Department of Medicine, University of Florida Health Cancer Center, Gainesville

Accepted for Publication: April 8, 2021.

Published Online: July 1, 2021. doi:10.1001/jamaoncol.2021.1683

^✉

Corresponding Author: Osama E. Rahma, MD, Department of Medical Oncology, Dana-Farber Cancer Institute/Alliance, 450 Brookline Ave, Boston, MA 02215 (osamae_rahma@DFCI.harvard.edu).

Author Contributions: Drs Rahma and Yothers had full access to all the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis, as well as the work as a whole, from inception to published article.

Concept and design: Rahma, Yothers, Hong, Russell, You, Jacobs, Colangelo, Hall, Kachnic, Sigurdson, Wolmark, George.

Acquisition, analysis, or interpretation of data: Rahma, Yothers, You, Parker, Colangelo, Lucas, Gollub, Vijayvergia, O’Rourke, Faller, Valicenti, Schefter, Moxley, Kainthla, Stella, George.

Drafting of the manuscript: Rahma, Yothers, Jacobs, Colangelo, Hall, Kachnic, O’Rourke, Moxley, George.

Critical revision of the manuscript for important intellectual content: Rahma, Yothers, Hong, Russell, You, Parker, Colangelo, Lucas, Gollub, Vijayvergia, Faller, Valicenti, Schefter, Moxley, Kainthla, Stella, Sigurdson, Wolmark, George.

Statistical analysis: Yothers, Colangelo.

Obtained funding: George.

Administrative, technical, or material support: Yothers, Russell, You, Parker, Jacobs, Lucas, Valicenti, Sigurdson, Wolmark, George.

Supervision: Rahma, Yothers, Gollub, Hall, Kachnic, Faller, George.

Conflict of Interest Disclosures: Dr Rahma reported receiving personal fees from the Sobi Advisory Board, the Genentech Advisory Board, the Bayer Advisory Board, the GSK Advisory Board, the Imvax Advisory Board, the Maverick Advisory Board, and the Puretech Advisory Board outside the submitted work; in addition, Dr Rahma had a patent for DFCI 2386.010 pending. Dr Yothers reported receiving grants from the NRG Oncology Statistical and Data Management Center during the conduct of the study and serving on the Orbus Pharmaceuticals Data Monitoring Committee outside the submitted work. Dr Hong reported serving as a consultant for Merck, Novocure, and Synthetic Biologics outside the submitted work. Dr Russell reported serving as a consultant for the American College of Surgeons. Dr Colangelo reported receiving grants from NRG Oncology during the conduct of the study. Dr Lucas reported stock ownership in Amgen and having a spouse who received speaker honorarium from Schrodinger outside the submitted work. Dr Hall reported receiving institutional research support from Elekta AB outside the submitted work. Dr Kachnic reported receiving honorarium from UpToDate outside the submitted work. Dr Vijayvergia reported serving on advisory boards for Lexicon, Halio Dx, and QED Therapeutics, serving as a consultant for Novartis, and receiving grants from Merck and Bayer outside the submitted work. Dr George reported receiving institutional support from BMS, Merck, AstraZeneca, Genentech, Tesaro/GSK, Ipsen, Bayer, and Lilly outside the submitted work. No other disclosures were reported.

Funding/Support: This study was supported by grants U10CA180868, U10CA180822, UG1-189867, and U24-196067 from the National Cancer Institute and by Merck (Dr Rahma).

Role of the Funder/Sponsor: The funding sources had no role in the design of the study; the collection, analysis, and/or interpretation of the data; the writing of the manuscript; or the decision to submit the manuscript for publication.

Additional Contributions: Christine I. Rudock and Wendy L. Rea, BA, National Surgical Adjuvant Breast and Bowel Project, Pittsburgh, Pennsylvania, provided editorial support. They were not compensated beyond their normal salaries for this work.

Data Sharing Statement: See Supplement 3.

^✉

Corresponding author.

PMCID: PMC8251652 PMID: 34196693

Key Points

Question

Does the addition of pembrolizumab to neoadjuvant chemoradiotherapy improve efficacy compared with chemoradiotherapy alone for patients with locally advanced rectal cancer who have completed neoadjuvant FOLFOX (5-fluorouracil, leucovorin, and oxaliplatin)?

Findings

In this randomized clinical trial, which included 185 patients with stage II/III locally advanced rectal cancer, the mean neoadjuvant rectal score was 11.53 for the pembrolizumab arm compared with 14.08 for the control arm.

Meaning

The results do not support combining neoadjuvant pembrolizumab with chemoradiotherapy after FOLFOX treatment of locally advanced rectal cancer.

Abstract

Importance

Total neoadjuvant therapy (TNT) is often used to downstage locally advanced rectal cancer (LARC) and decrease locoregional relapse; however, more than one-third of patients develop recurrent metastatic disease. As such, novel combinations are needed.

Objective

To assess whether the addition of pembrolizumab during and after neoadjuvant chemoradiotherapy can lead to an improvement in the neoadjuvant rectal (NAR) score compared with treatment with FOLFOX (5-fluorouracil, leucovorin, and oxaliplatin) and chemoradiotherapy alone.

Design, Setting, and Participants

In this open-label, phase 2, randomized clinical trial (NRG-GI002), patients in academic and private practice settings were enrolled. Patients with stage II/III LARC with distal location (cT3-4 ≤ 5 cm from anal verge, any N), with bulky disease (any cT4 or tumor within 3 mm of mesorectal fascia), at high risk for metastatic disease (cN2), and/or who were not candidates for sphincter-sparing surgery (SSS) were stratified based on clinical tumor and nodal stages. Trial accrual opened on August 1, 2018, and ended on May 31, 2019. This intent-to-treat analysis is based on data as of August 2020.

Interventions

Patients were randomized (1:1) to neoadjuvant FOLFOX for 4 months and then underwent chemoradiotherapy (capecitabine with 50.4 Gy) with or without intravenous pembrolizumab administered at a dosage of 200 mg every 3 weeks for up to 6 doses before surgery.

Main Outcomes and Measures

The primary end point was the NAR score. Secondary end points included pathologic complete response (pCR) rate, SSS, disease-free survival, and overall survival. This report focuses on end points available after definitive surgery (NAR score, pCR, SSS, clinical complete response rate, margin involvement, and safety).

Results

A total of 185 patients (126 [68.1%] male; mean [SD] age, 55.7 [11.1] years) were randomized to the control arm (CA) (n = 95) or the pembrolizumab arm (PA) (n = 90). Of these patients, 137 were evaluable for NAR score (68 CA patients and 69 PA patients). The mean (SD) NAR score was 11.53 (12.43) for the PA patients (95% CI, 8.54-14.51) vs 14.08 (13.82) for the CA patients (95% CI, 10.74-17.43) (P = .26). The pCR rate was 31.9% in the PA vs 29.4% in the CA (P = .75). The clinical complete response rate was 13.9% in the PA vs 13.6% in the CA (P = .95). The percentage of patients who underwent SSS was 59.4% in the PA vs 71.0% in the CA (P = .15). Grade 3 to 4 adverse events were slightly increased in the PA (48.2%) vs the CA (37.3%) during chemoradiotherapy. Two deaths occurred during FOLFOX: sepsis (CA) and pneumonia (PA). No differences in radiotherapy fractions, FOLFOX, or capecitabine doses were found.

Conclusions and Relevance

Pembrolizumab added to chemoradiotherapy as part of total neoadjuvant therapy was suggested to be safe; however, the NAR score difference does not support further study.

Trial Registration

ClinicalTrials.gov Identifier: NCT02921256

This randomized clinical trial assesses whether the addition of pembrolizumab during and after neoadjuvant chemoradiotherapy can lead to an improvement in the neoadjuvant rectal score compared with treatment with FOLFOX and chemoradiotherapy alone.

Introduction

Trimodality therapy of chemotherapy, chemoradiotherapy, and surgery has been considered the mainstay of treatment for stage II/III locally advanced rectal cancer (LARC).¹ Preoperative chemoradiotherapy is used for tumor downstaging, reducing local recurrence, and avoiding colostomies.² Total neoadjuvant therapy (TNT) is an emerging option to optimize successful delivery of chemotherapy. However, despite a low locoregional relapse rate of 6%, 5-year overall survival (OS) is 75%.^3,4 The TNT platform is a randomized clinical study to test novel agents with parallel, noncomparative experimental arms in LARC. The primary objective is to assess whether the addition of a novel agent during and after neoadjuvant chemoradiotherapy can lead to an improvement in the neoadjuvant rectal (NAR) score, which is a short-term surrogate end point proven to be more strongly associated with disease-free survival (DFS) and OS than pathological complete response (pCR).^5,6 The NAR score combines pathologic nodal status (ypN stage) with tumor downstaging (ypT minus baseline cT) to evaluate tumor response; it is calculated from 24 items on a pseudo-continuous scale from 0 (pCR from cT4) to 100 (ypN2 and progression from cT1 to ypT4), with lower scores indicating better prognosis.^5,6 Chemoradiotherapy can increase the immunogenic properties of tumor cells, thereby increasing their vulnerability to cytotoxic lymphocytes^7,8 and inducing expression of programmed death–ligand 1 on tumor cells, which can lead to an immunosuppressive microenvironment.^9,10 We hypothesized that the addition of anti–programmed death 1 therapy to neoadjuvant chemoradiotherapy could increase CD8⁺ T cells, leading to better pCR and improved NAR score. In this article, we present the primary end point (NAR score) results of the experimental pembrolizumab arm (PA) vs the control arm (CA). Results from the other experimental arm have been previously presented.¹¹

Methods

This study is a prospective, open-label, phase 2 randomized clinical trial, with equal allocation to each trial arm by permuted block method. Trial accrual opened on August 1, 2018, and ended on May 31, 2019. A total of 185 patients were concurrently randomized, with 95 randomized to the CA and 90 to the PA. This intent-to-treat analysis is based on data as of August 2020. The trial protocol can be found in Supplement 1. Written informed consent was provided by the study participants. Data were not deidentified. The NRG-GI002 study was approved by local human investigations committees with assurances filed with the US Department of Health and Human Services.

Patients were randomized to receive 6 cycles of FOLFOX (5-fluorouracil, leucovorin, and oxaliplatin) followed by chemoradiotherapy (825 mg/m² of capecitabine twice daily concurrently with 4500 cGy in 25 fractions for 5 weeks plus a 540-cGy boost in 3 fractions) starting 3 to 4 weeks after FOLFOX (CA) or the same dosage of FOLFOX followed by the same chemoradiotherapy regimen in combination with 200 mg of pembrolizumab every 3 weeks starting on day 1 of chemoradiotherapy for up to 6 doses (PA). Surgery was performed 8 to 12 weeks after the last dose of radiotherapy (eFigure in Supplement 2).

Stratification factors included clinical tumor stage (T1 or T2, T3, or T4) and clinical nodal stage (N0, N1, or N2). Inclusion criteria included stage II or III LARC that met at least 1 of the following criteria: distal location (cT3-4 ≤ 5 cm from the anal verge), bulky disease (any cT4 or evidence that the tumor is within 3 mm of the mesorectal fascia), high risk of metastatic disease with 4 or more involved regional lymph nodes (cN2), or not a candidate for sphincter-sparing surgery (SSS) at presentation. The sample size of 79 evaluable patients per arm was calculated based on targeting an NAR score reduction of 4.70 points for the PA (mean reduction in NAR score from 14.32 to 9.62) compared with a mean NAR score from similarly eligible patients derived from the GCR-3 and Complete Neoadjuvant Treatment for Rectal Cancer (CONTRE) studies,^3,4 with 1-sided type 1 error of α = .10 and a type 2 error of β = 0.20 (power of 80%). Secondary objectives include pCR, SSS rate, DFS, and OS. Mean NAR scores were compared in a linear model that controlled for baseline cT stage, and binary outcomes were compared by the Fisher exact test.

Results

A total of 185 patients (126 [68.1%] male; mean [SD] age, 55.7 [11.1] years) were concurrently randomized to the CA (n = 95) and PA (n = 90). Patient and tumor characteristics are reported in the Table. More patients in the PA had bulky disease vs the CA patients (60 [66.7%] vs 55 [57.9%]), whereas more patients in the CA vs the PA had T4 disease (22 [23.2%] vs 19 [21.1%]). Thirty-seven of 81 patients (45.7%) who started radiotherapy in the PA received 6 doses of pembrolizumab, whereas 21 patients (25.9%) received 5 doses, 21 (25.9%) received 1 to 4 doses, and 2 (2.5%) did not receive any pembrolizumab.

Table. Patient and Tumor Characteristics at Baseline: NRG-GI002 Study.

Patient or tumor characteristic	No. (%) of patients			P value
Patient or tumor characteristic	CA (n = 95)	PA (n = 90)	Total (n = 185)	P value
Sex
Female	29 (30.5)	30 (33.3)	59 (31.9)	.75
Male	66 (69.5)	60 (66.7)	126 (68.1)	.75
Age, y
<50	30 (31.6)	25 (27.8)	55 (29.7)	.76
50-59	28 (29.5)	33 (36.7)	61 (33.0)
60-69	30 (31.6)	27 (30.0)	57 (30.8)
≥70	7 (7.4)	5 (5.6)	12 (6.5)
Race
White	77 (81.1)	77 (85.6)	154 (83.2)	.22
American Indian or Alaska Native	2 (2.1)	1 (1.1)	3 (1.6)
Asian	4 (4.2)	3 (3.3)	7 (3.8)
Black or African American	6 (6.3)	2 (2.2)	8 (4.3)
Not reported	3 (3.2)	4 (4.4)	7 (3.8)
Unknown	3 (3.2)	3 (3.3)	6 (3.2)
Ethnicity
Hispanic or Latino	5 (5.3)	9 (10.0)	14 (7.6)	.28
Not Hispanic or Latino	83 (87.4)	78 (86.7)	161 (87.0)
Not reported	4 (4.2)	2 (2.2)	6 (3.2)
Unknown	3 (3.2)	1 (1.1)	4 (2.2)
Distal location
No	27 (28.4)	25 (27.8)	52 (28.1)	>.99
Yes	68 (71.6)	65 (72.2)	133 (71.9)	>.99
Bulky disease
No	40 (42.1)	30 (33.3)	70 (37.8)	.23
Yes	55 (57.9)	60 (66.7)	115 (62.2)	.23
High risk of metastatic disease
No	58 (61.1)	55 (61.1)	113 (61.1)	>.99
Yes	37 (38.9)	35 (38.9)	72 (38.9)	>.99
Not a candidate for SSS
No	44 (46.3)	41 (45.6)	85 (45.9)	>.99
Yes	51 (53.7)	49 (54.4)	100 (54.1)	>.99
N stage
N0	22 (23.2)	20 (22.2)	42 (22.7)	>.99
N1	36 (37.9)	35 (38.9)	71 (38.4)
N2	37 (38.9)	35 (38.9)	72 (38.9)
T stage
T1/T2	5 (5.3)	4 (4.4)	9 (4.9)	.90
T3	68 (71.6)	67 (74.4)	135 (73.0)
T4	22 (23.2)	19 (21.1)	41 (22.2)

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Abbreviations: CA, control arm; PA, pembrolizumab arm; SSS, sphincter-sparing surgery.

Clinical and Pathological Outcomes

Patient disposition is summarized in Figure 1. Of the 138 patients with resected tumor, 137 had complete pathologic assessment and a valid NAR score. The mean (SD) NAR scores were 11.53 (12.43) (95% CI, 8.54-14.51) in the PA (n = 69) vs 14.08 (13.82) (95% CI, 10.74-17.43) in the CA (n = 68). The difference of 2.55 was not statistically significant (P = .26) (Figure 2). Twelve patients with invalid NAR scores because of missing pathologic assessment underwent clinical staging immediately before surgery. The evaluable sample size per arm was less than our targeted 79 patients per arm, resulting in a reduced power of 75.7% instead of 80.0%. We created an exploratory modified NAR score by substituting presurgical ycT and ycN in place of ypT and ypN for the patients with clinical staging but no pathologic staging. The mean (SD) mNAR scores were 11.52 (12.85) (95% CI, 8.59-14.46) for the PA (n = 76) vs 13.70 (14.21) (95% CI, 10.47-16.93) for the CA (n = 77). The difference of 2.17 was not statistically significant (P = .32). Although there was a slightly higher pCR rate in the PA of 31.9% (22 of 69; 95% CI, 21.2%-44.2%) vs 29.4% (20 of 68; 95% CI, 19.0%-41.7%) in the CA, this finding was not statistically significant (P = .75). The clinical complete response rate, based on presurgical staging as an exploratory end point, was 13.9% (11 of 79; 95% CI, 7.2%-23.6%) in the PA and 13.6% (11 of 81; 95% CI, 7.0%-23.0%) in the CA (P = .95). The R0 resection rate was 94% in the PA vs 89.4% in the CA (P = .36). In patients who underwent tumor resection, the SSS rate was lower in the PA (41 of 69 [59.4%]; 95% CI, 46.9%-71.1%) vs the CA (49 of 69 [71.0%]; 95% CI, 58.8%-81.3%), which was not statistically significant (P = .15). Analyses of longer-term outcomes, including DFS and OS, remain ongoing.

Figure 2. — This histogram displays the distribution of the NAR scores along with the best fit normal (gaussian distribution) and kernel (smoothed nonparametric) distributions.

Adverse Events

Grade 3 to 4 adverse events were slightly increased on the PA during and after chemoradiotherapy (39 [48.2%] vs 31 [37.3%]). No grade 5 adverse events were reported during and after chemoradiotherapy. Immune-related adverse events were reported in 35 patients (43.2%) on in the PA, including only 3 (3.7%) with grade 3 events and no grade 4 or 5 events. Immune-related adverse events were consistent with the pembrolizumab safety profile (eTable in Supplement 2).

Discussion

The addition of pembrolizumab to chemoradiotherapy as part of TNT in LARC did not demonstrate our prespecified improvement in the primary end point of NAR score compared with FOLFOX and chemoradiotherapy alone. Although the pCR rate was higher in the PA, it did not reach statistical significance. The DFS and OS data are not mature and will be presented in future publications. The combination was well tolerated without new safety concerns raised.

Although the efficacy of programmed cell death 1 blockade has been impressive in microsatellite-instable tumors,¹² the microsatellite-stable tumors (which account for >95% of rectal cancers) remain resistant to immune checkpoint inhibitors. This resistance may be attributable to many factors, including major histocompatibility complex 1 downregulation, low tumor mutation burden, the immune desert or excluded phenotypes, and the immune suppressive microenvironment.¹³ Whether additional immune checkpoint inhibitors or immune agonists are needed to overcome the resistance to programmed cell death 1 blockade remains to be determined.^14,15 The ongoing genomic (including microsatellite status) and immune correlatives from the NRG-GI002 trial will further explore the mechanisms of immune resistance and inform future LARC studies.

Limitations

Although patients in both arms had similar exposures to chemoradiotherapy, 44 (54.3%) did not receive all 6 doses of pembrolizumab and 23 (28.4%) received fewer than 5 doses. The NRG-GI002 study had slightly less power than originally planned (75.7% vs 80.0%).

Conclusions

These results suggest that pembrolizumab added to chemoradiotherapy as part of total neoadjuvant therapy is safe; however, the NAR score difference does not support further study.

Supplement 1.

Trial Protocol

Click here for additional data file.^{(1.4MB, pdf)}

Supplement 2.

eTable. Immune-Related Adverse Events During and After Chemoradiation: NRG Oncology GI002

eFigure. Study Schema: NRG Oncology GI002

Click here for additional data file.^{(311.8KB, pdf)}

Supplement 3.

Data Sharing Statement

Click here for additional data file.^{(21KB, pdf)}

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Supplement 1.

Trial Protocol

Click here for additional data file.^{(1.4MB, pdf)}

Supplement 2.

eTable. Immune-Related Adverse Events During and After Chemoradiation: NRG Oncology GI002

eFigure. Study Schema: NRG Oncology GI002

Click here for additional data file.^{(311.8KB, pdf)}

Supplement 3.

Data Sharing Statement

Click here for additional data file.^{(21KB, pdf)}

[cbr210009r1] 1.George TJ, Franke AJ, Chakravarthy AB, et al. National Cancer Institute (NCI) state of the science: targeted radiosensitizers in colorectal cancer. Cancer. 2019;125(16):2732-2746. doi: 10.1002/cncr.32150 [DOI] [PMC free article] [PubMed] [Google Scholar]

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PERMALINK

Use of Total Neoadjuvant Therapy for Locally Advanced Rectal Cancer

Osama E Rahma, MD

Greg Yothers, PhD

Theodore S Hong, MD

Marcia M Russell, MD

Y Nancy You, MD

William Parker, MS

Samuel A Jacobs, MD

Linda H Colangelo, MS

Peter C Lucas, MD, PhD

Marc J Gollub, MD

William A Hall, MD

Lisa A Kachnic, MD

Namrata Vijayvergia, MD

Mark A O’Rourke, MD

Bryan A Faller, MD

Richard K Valicenti, MD

Tracey E Schefter, MD

Katherine M Moxley, MD

Radhika Kainthla, MD

Philip J Stella, MD

Elin Sigurdson, MD

Norman Wolmark, MD

Thomas J George, MD

Key Points

Question

Findings

Meaning

Abstract

Importance

Objective

Design, Setting, and Participants

Interventions

Main Outcomes and Measures

Results

Conclusions and Relevance

Trial Registration

Introduction

Methods

Results

Table. Patient and Tumor Characteristics at Baseline: NRG-GI002 Study.

Clinical and Pathological Outcomes

Figure 1. CONSORT Diagram of Patients in the NRG-GI002 Study.

Figure 2. Neoadjuvant Rectal (NAR) Score of Patients in the NRG-GI002 Study.

Adverse Events

Discussion

Limitations

Conclusions

References

Associated Data

Supplementary Materials

ACTIONS

PERMALINK

RESOURCES

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