Updates on the Management of Colorectal Cancer in Older Adults
Abstract
:Simple Summary
Abstract
1. Introduction
2. Geriatric Assessment
3. Localized Rectal Cancer with Microsatellite Stability
3.1. Early Stage
3.2. Locally Advanced
4. Localized Colon Cancer with Microsatellite Stability
Stage II Disease
5. Localized Colorectal Cancers with Microsatellite Instability
6. Advanced/Metastatic Disease in Older Adults
7. Traditional Chemotherapy Backbones in a Palliative Setting
7.1. FOLFOX
7.2. FOLFIRI
7.3. Anti-VEGF Antibody
7.4. Anti-EGFR Antibody
7.5. Triplet Chemotherapy and Biologic
7.6. Immunotherapy
7.7. Later-Line Options
8. Conclusions
9. Future Directions
Author Contributions
Funding
Conflicts of Interest
References
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Tool | Purpose | Components | Scoring | CRC-Specific Evidence |
---|---|---|---|---|
G8 [8] | To identify patients in need of CGA | Decline in food intake; weight loss; mobility impairment; neuropsychological problems; BMI; polypharmacy; patient perceived health status; age | G8 > 14—CGA not necessary G8 ≤ 14—CGA necessary |
|
CRASH [13] | To predict hematological and non-hematological treatment-related toxicity | Diastolic BP, IADLs, LDH, MMHS, chemotherapy risk | Hematological: 0–1—low; 2–3—low-intermediate; 4–5-intermediate-high; ≥6—high Non-hematological: 0–2—low; 3–4—low-intermediate; 5–6—intermediate-high; ≥7—high Combined score 0–3—low; 4–6—low-intermediate; 7–9—intermediate-high; ≥10—high |
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Domain | Deficit | Interventions |
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Functional Status |
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Comorbidities |
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Cognition |
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Nutrition |
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Psychological Status |
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Social Circumstances |
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Polypharmacy |
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Clinical Symptoms |
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Study | Design (n) | Inclusion Criteria | Intervention | Efficacy | Comments |
---|---|---|---|---|---|
GAIN [21] | 2:1 Randomized Trial (605) | Age ≥ 65, solid malignancy, starting chemotherapy | A: CGA-guided management and interventions (see Table 2 for examples) B: Standard care (no CGA-guided recommendations) | 1°: Grade ≥ 3 chemotherapy-related toxicity: 50.5% vs. 60.6%, p = 0.02Advanced Directive completion: 28.4% vs. 13.3%, p < 0.00112 m OS: 66% vs. 64%; p = 0.55 |
|
GAP70+ [28] | Cluster-randomized trial (718) | Age ≥ 70, incurable solid malignancy or lymphoma, ≥1 geriatric domain impairment (other than poly- pharmacy), starting a new systemic regimen with ≥50% prevalence of grade 3–5 toxicity | A: CGA summary and management recommendations B: Standard care (no recommendations) | 1°: Grade ≥ 3 toxicity: 51% vs. 71%; p < 0.001Patient-reported symptomatic toxicities Grade ≥ 2: 88.9% vs. 94.8%; p = 0.0356-month OS: 72% vs. 75%; p = 0.38 |
|
INTEGERATE [29] | 1:1 randomized trial (154) | Age ≥ 70, solid malignancy or diffuse-large B-cell lymphoma, starting systemic therapy | A: CGA B: Standard care | 1°: Change in health-related quality of life: better in the intervention group, p = 0.030
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|
Clinical Scenario | Recommendations | |||
---|---|---|---|---|
All Stages of Disease | ||||
| ||||
Localized Disease, Microsatellite Stable | ||||
Early Stage Rectal Cancer (T1-2, N0) | ||||
FIT |
| |||
MEDIUM FIT |
| |||
Locally Advanced Rectal Cancer (T3-4, N0-2, or TxN+), Neoadjuvant Therapy | ||||
FIT |
| |||
MEDIUM FIT |
| |||
Colon Cancer, Adjuvant Therapy | ||||
Stage II with high-risk features | ||||
FIT or MEDIUM FIT |
| |||
Stage III | ||||
FIT |
| |||
MEDIUM FIT |
| |||
Localized Disease, Microsatellite Instability | ||||
Rectal Cancer, Neoadjuvant Setting | ||||
FIT or MEDIUM FIT |
| |||
Colon Cancer, Adjuvant Setting | ||||
Stage II | ||||
FIT or MEDIUM FIT |
| |||
Stage III | ||||
FIT |
| |||
MEDIUM FIT |
| |||
Metastatic Disease | ||||
Resectable | ||||
FIT |
| |||
MEDIUM FIT |
| |||
Borderline Resectable | ||||
FIT |
| |||
MEDIUM FIT |
| |||
Palliative Setting, First-Line | ||||
FIT |
| |||
MEDIUM FIT |
| |||
Palliative Setting, Later Lines | ||||
FIT or MEDIUM FIT |
|
Study | Phase (n) | Inclusion Criteria (Median Age) | Intervention | Efficacy | Comments |
---|---|---|---|---|---|
RESPECT (JCOG1018) [121] | III (251) | mCRC, Age 70–74 with PS2 or ≥75 with PS 0-2, first-line (79) | A: FOLFOX/CAPOX plus bevacizumab B: 5-FU/Capecitabine plus bevacizumab | 1°: OS: 21.3 vs. 19.7 m HR 1.054 (0.810–1.372) PFS: 9.4 vs. 9.3 m; p = 0.086 ORR: 47.7% vs. 29.5% |
|
PANDA [10] | II (183) | mCRC, first-line, RAS/BRAF-wild type, age 70–75 with PS < 2, or age > 75 years with PS < 1 (77) | A: FOLFOX plus panitumumab B: 5-FU plus panitumumab | 1°: Non-comparator trial, to reject null hypothesis of PFS < 6 m; p < 0.001 in each arm PFS: 9.6 vs. 9.1 m, p = 0.611 (unplanned comparison) OS: 23.5 vs. 22.0 m, p = 0.986 ORR: 69% vs. 52%; p = 0.182 |
|
SOLSTICE [122] | III (856) | mCRC, first-line, not candidates for full-dose doublet or triplet chemotherapy (73) | A: TAS-102 plus bevacizumab B: Capecitabine plus bevacizumab | 1°: PFS 9.4 vs. 9.3 m; p = 0.464 OS: immature ORR: 36% vs. 42%; p = 0.092 |
|
AVEX [118] | III (280) | mCRC, first-line, age ≥ 70, not candidates for doublet chemotherapy (76) | A: Capecitabine plus bevacizumab B: Capecitabine | 1°: PFS: 9.1 vs. 5.1 m; p < 0.001 OS: 20.7 vs. 16.8 m; p = 0.18 ORR: 19% vs. 10%; p = 0.04 |
|
MRC FOCUS2 [61] | Randomized 2X2 factorial trial (459) | mCRC, first-line, not candidates for full-dose doublet chemotherapy (74) | A: FOLFOX (80% dose, with bolus) B: CAPOX (80% dose) C: 5-FU (80% dose) D: Capecitabine (80% dose) | 1°: PFS: [A vs. C] + [B vs. D] 5.8 vs. 4.5 m; p = 0.07 OS: No evidence of benefit with oxaliplatin ORR: 41.2% vs. 12.1% |
|
FFCD 2001-02 [113] | III, Randomized 2X2 factorial (282) | mCRC, first-line, age ≥ 75 (80) | A,B: 5-FU + irinotecan arms C,D: 5-FU arms | 1°: PFS: 7.3 vs. 5.2 m; p = 0.15 OS: 13.3 vs. 15.2 m; p = 0.77 ORR: 25.6% vs. 37.1%; p = 0.04 |
|
PRODIGE 42/GERICO 12 [41] | III (103) | Locally advanced rectal cancer (very low cT2 or at least cT3), age ≥ 75 (80) | A: Long-course chemoradiation B: short-course radiation | 1°: R0 resection rate: 95.6% vs. 88.0%; p = 0.49, non-inferiority not reached 1°: Deterioration of autonomy at 12 months: 28.6% vs. 29.2%; not statistically significant OS: HR 0.28; p = 0.05 favoring short-course radiation RFS: HR 0.99; p = 1 pCR: 17.4% vs. 6.1%; p = 0.16 |
|
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© 2024 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
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O’Donnell, C.D.J.; Hubbard, J.; Jin, Z. Updates on the Management of Colorectal Cancer in Older Adults. Cancers 2024, 16, 1820. https://doi.org/10.3390/cancers16101820
O’Donnell CDJ, Hubbard J, Jin Z. Updates on the Management of Colorectal Cancer in Older Adults. Cancers. 2024; 16(10):1820. https://doi.org/10.3390/cancers16101820
Chicago/Turabian StyleO’Donnell, Conor D. J., Joleen Hubbard, and Zhaohui Jin. 2024. "Updates on the Management of Colorectal Cancer in Older Adults" Cancers 16, no. 10: 1820. https://doi.org/10.3390/cancers16101820
APA StyleO’Donnell, C. D. J., Hubbard, J., & Jin, Z. (2024). Updates on the Management of Colorectal Cancer in Older Adults. Cancers, 16(10), 1820. https://doi.org/10.3390/cancers16101820