Novel Targets, Novel Treatments: The Changing Landscape of Non-Small Cell Lung Cancer
Abstract
:Simple Summary
Abstract
1. Lung Cancer
Genes | Common Mutations | Mutation Prevalence | Screening Protocol |
---|---|---|---|
EGFR [5,6] | Exon 19 deletion * Exon 20 T790M Exon 21 L858R * (*: Present in 40% of patients) | Adenocarcinoma: 38% Non-adenocarcinoma: 12% Western: 10–15% Asia: 30–40% African-American: 20% Male: 24% Female: 44% | Direct DNA sequencing is the gold standard if sample is more than 50% tumor content. If not, PCR preferred. |
MET [7,8,9,10] | TPR-MET fusion Exon 14 skip c-MET-N375S | Adenosquamous carcinoma: 5% Adenocarcinoma: 3% Squamous cell carcinoma: 2% Western: 12% Asian: 1–4% African-American: 10% | FISH assay is the gold standard; next-generation sequencing is reliable only for a high-level of MET gene amplification. |
ALK [11,12] | Fusion with: -TMP3-TFG-CLTCL1 -ATIC-EML4 * (*: Most common, ~30% of all ALK fusions) | Adenocarcinoma: 5% Western: 5% Asian: 5% | FISH assay is the gold stand; RT-PCR is also FDA-approved for only EML4-ALK fusion. |
RET [13] | RET-KIF5B fusion * RET-CCDC6 fusion RET-NCOA4 fusion (*: Detected in EGFR inhibitor resistant cancers) | All NSCLC: 1.5% Adenocarcinoma: 1.7% Age > 60: 2.0% Age < 60: 1.0% Male: 0.9% Female: 1.7% | Next-generation sequencing and FISH assays are comparable; however, FISH demonstrated lower sensitivity for RET-NCOA4 fusions |
HER2 [14] | Exon 20 12 bp insertion Exon 20 L755S Exon 20 G776C | Adenocarcinoma: 2–4% | Mutation: next-generation sequencing, Amplification: FISH, Overexpression: IHC. |
2. Imaging Lung Cancer
3. Molecular Testing for Lung Cancer
3.1. Next-Generation Sequencing (NGS)
3.2. Polymerase Chain Reaction (PCR)
3.3. Fluorescence In Situ Hybridization (FISH) Assay
4. Checkpoint Inhibitor Immunotherapy for Lung Cancer
4.1. Mechanism of Action
4.2. Clinical Trials and Implementation of ICIs as the New Standard of Care
4.3. ICI Combinations and ICI + Chemoradiotherapy (CRT)
4.4. ICI and Targeted Therapy
4.5. Side Effects of ICIs
4.6. Challenges of ICIs
5. EGFR Inhibitors
5.1. First Generation EGFR Inhibitors
5.2. Second Generation EGFR Inhibitors
5.3. Third Generation EGFR Inhibitors
6. ALK Inhibitors
6.1. First Generation ALK Inhibitors
6.2. Second Generation ALK Inhibitors
6.3. Third Generation ALK Inhibitors
7. MET Inhibitors
8. Other Targeted Inhibitors in NSCLC
8.1. HER2 Targeting in NSCLC
8.2. RET Signaling in NSCLC
8.2.1. Cabozantinib
8.2.2. Vandetanib
8.2.3. Selpercatinib
8.3. ROS1 targeting in NSCLC
9. Emerging Therapies
9.1. Bispecific Antibodies
9.2. CAR T Cell Therapy
9.3. Molecular Targeted Radiotherapy
9.4. Alternate Drug Delivery Systems
9.5. Inhalational Therapy
10. Current State of NSCLC Diagnosis and Treatment
Drug Class | Clinical Trials | Description |
---|---|---|
ICI | Ramucirumab and Atezolizumab After Progression on Any Immune Checkpoint Blocker in NSCLC (RamAtezo-1) [127] | Assessing for a therapeutic advantage to administering ICI and VEGEF inhibitor to patients previously receiving immunotherapy. |
EGFR Inhibitors |
| After administering 3rd generation EGFR-TKIs, SBRT will be given until regression or intolerance. |
ALK Inhibitors |
| Identifying alterations in the ALK gene that may confer benefit from ALK inhibitor therapy. |
MET Inhibitors | Assessment of Anti-tumor and Safety in Glumetinib in Patients With c-MET-positive Non-Small Cell Lung Cancer [130] | Local or metastatic NSCLC patients with a METex14 mutation, not undergoing chemotherapy. |
RET Inhibitors | A Phase I Study of Oral LOXO-260 in Patients With RET Fusion-Positive Solid Tumors, Medullary Thyroid Cancer, and other Tumors with RET Activation Refractory to Selective RET Inhibitors [131] | Testing of a next-generation RET inhibitor, which has exhibited in vitro effect against RET-positive tumors with acquired resistance mutations. |
Bispecific Antibodies | AK112 Neoadjuvant/Adjuvant Treatment for Resectable NSCLC [132] AK104 Monotherapy as Neoadjuvant and Adjuvant Therapy for Resectable Non-small Cell Lung Cancer [133] | Investigating the effect of an anti-PD1 and VEGF bispecific antibody in combination with platin and paclitaxel chemotherapy. AK104 is a tetravalent bispecific antibody targeting PD-1 and CTLA-4; this study aims to evaluate its efficacy and safety profile. |
CAR T Cells | Study of CXCR5 Modified EGFR Targeted CAR-T Cells for Advanced NSCLC [134] | Early Phase I study investigating the pharmacokinetics and anti-tumor effect of a novel CAR T cell. |
11. Conclusions
Author Contributions
Funding
Conflicts of Interest
References
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de Jong, D.; Das, J.P.; Ma, H.; Pailey Valiplackal, J.; Prendergast, C.; Roa, T.; Braumuller, B.; Deng, A.; Dercle, L.; Yeh, R.; et al. Novel Targets, Novel Treatments: The Changing Landscape of Non-Small Cell Lung Cancer. Cancers 2023, 15, 2855. https://doi.org/10.3390/cancers15102855
de Jong D, Das JP, Ma H, Pailey Valiplackal J, Prendergast C, Roa T, Braumuller B, Deng A, Dercle L, Yeh R, et al. Novel Targets, Novel Treatments: The Changing Landscape of Non-Small Cell Lung Cancer. Cancers. 2023; 15(10):2855. https://doi.org/10.3390/cancers15102855
Chicago/Turabian Stylede Jong, Dorine, Jeeban P. Das, Hong Ma, Jacienta Pailey Valiplackal, Conor Prendergast, Tina Roa, Brian Braumuller, Aileen Deng, Laurent Dercle, Randy Yeh, and et al. 2023. "Novel Targets, Novel Treatments: The Changing Landscape of Non-Small Cell Lung Cancer" Cancers 15, no. 10: 2855. https://doi.org/10.3390/cancers15102855
APA Stylede Jong, D., Das, J. P., Ma, H., Pailey Valiplackal, J., Prendergast, C., Roa, T., Braumuller, B., Deng, A., Dercle, L., Yeh, R., Salvatore, M. M., & Capaccione, K. M. (2023). Novel Targets, Novel Treatments: The Changing Landscape of Non-Small Cell Lung Cancer. Cancers, 15(10), 2855. https://doi.org/10.3390/cancers15102855