Understanding lung cancer: Diagnosis and treatment options
With an estimated 2.2 million new cancer cases and 1.8 million deaths, lung cancer is the second most commonly diagnosed cancer and the leading cause of cancer death in 2020, representing approximately 11.4% of diagnosed cancers and 18.0% of deaths1. Lung cancer is the leading cause of cancer morbidity and mortality in men, whereas, in women, it ranks third for incidence, after breast and colorectal cancer, and second for mortality, after breast cancer 1. Lung cancer mainly affects older people. More than 40% of people diagnosed with lung cancer are aged 75 and older. Although people who have never smoked can develop lung cancer, smoking is the most common cause (accounting for more than 70 % of cases). In many cases, lung cancer goes undetected until it is in advanced stages, or the cancer comes back after initial treatment. Thus, identifying the stage is important for doctors to determine patients’ prognosis and help assess treatment options.
Figure 1: Different types of NSCLC4
The two main types of lung cancer are :
– Small Cell Lung Cancer (SCLC), the more aggressive and fast-growing cancer type representing about 15% of patients
– Non-Small Cell Lung Cancer (NSCLC), which represents 80-85% of patients 2,3.
For decades, NSCLC was considered as a single homogenous disease. Soon after, histological subtyping brought additional information with the identification of adenocarcinoma, squamous cell carcinoma and other subtypes (Figure 1).
Prevalence of drivers in NSCLC in Europe
Today, even more details are available from genotyping characterization, as illustrated by the specific oncogenic driver alterations that are found in NSCLC (Figure 2).
In Europe, KRAS mutations are the most frequently encountered (25%), followed in EGFR (5-15%), MET exon 14 (3%) and BRAF V600E mutations (2-3%).
Gene fusions or rearrangements including ALK, ROS1, RET, NTRK and NRG1 genes represents almost 12% of NSCLC cases.
However, to date, other alterations or unknown drivers still represents most of the NSCLC cases. This underscores the importance of obtaining the most comprehensive molecular profiling to identify the most suitable therapeutic strategy for each patient.
Figure 2: Prevalence of drivers in NSCLC in Europe
The role of biomarker testing in lung cancer treatment
Lung cancer is a diverse disease, characterized by a variety of different genetic and molecular characteristics5. These characteristics, known as biomarkers, can serve as indicators of various types of cancer and many promote tumor growth. Biomarker testing (also known as mutation, genomic, or molecular testing) of tumor tissue allows us to look for abnormalities in the DNA and/or RNA and expression levels of specific proteins. Biomarker testing is critical to learning more about each patient’s tumor type and can be used to help determine treatment options. Based on the test results, patients may be matched with targeted therapies aimed at specific biomarkers present in their genetic profile6.Key biomarkers for personalized NSCLC treatment plans
| Genes | Biomarker types | Atlerations | Recommended detection level | Guidelines recommended testing technologies9,10 |
|---|---|---|---|---|
|
EGFR |
Activating mutations |
Exon 19 deletions Exon 21 (L858R) Others |
DNA |
Any appropriate, validated technology (NGS, real time PCR, Sanger sequencing…) |
|
Resistance mutations |
T790M Exon 20 insertion |
|||
|
ALK |
Rearrangements |
NA |
Protein, DNA and/or RNA |
FISH (historical standard) IHC (stand-alone if scoring 3+ or validated against FISH) RT-PCR; NGS |
|
ROS1 |
Rearrangements |
NA |
Protein, DNA and/or RNA |
FISH trial-validated standard) IHC to select for confirmatory FISH RT-PCR; NGS |
|
NTRK |
Rearrangements |
Gene fusions |
Protein, DNA and/or RNA |
IHC, FISH, RT-PCR, NGS |
|
BRAF |
Activating mutations |
V600E |
DNA |
Any appropriate, validated technology
(NGS, real time PCR, Sanger sequencing…)
|
|
RET |
Rearrangements |
NA |
DNA and/or RNA |
FISH, RT-PCR, NGS |
|
MET |
Activating mutations |
Exon14 Skipping |
DNA and/or RNA |
Any appropriate, validated technology
(NGS, real time PCR, Sanger sequencing…)
|
|
ERBB2/HER2 |
Activating mutations |
NA |
DNA |
Any appropriate, validated technology
(NGS, real time PCR, Sanger sequencing…)
|
|
KRAS |
Activating mutations |
G12C |
DNA |
|
|
PD-L1 |
Expression levels |
NA |
Protein |
IHC |
|
MSI |
Genomic signaturesb |
Unstable |
DNA |
NGS |
|
TMB |
Genomic signatures b |
High |
DNA |
NGS |
|
NRG1 |
Rearrangementsa |
NA |
DNA and/or RNA |
NGS |
Table 1. Established and emerging biomarkers for NSCLC
a Emerging biomarkers
b Emerging biomarkers in Europe (FDA approved)
| Genes | Biomarkers types | Atlerations | FDA-approved therapy (first line) | EMA-approved therapy (first line) |
|---|---|---|---|---|
|
EGFR |
Activating mutations |
Exon 19 deletions Exon 21 (L858R) Others |
Afatiniba, Dacomitinibb, Erlotinib b, Gefitinib b, Osimertinib b,c, Mobocertinib d, Amivantamab d |
Afatinib a, Dacomitinib a, Erlotinib aGefitinib a, Osimertinib a,c, Amivantamab d |
|
Resistance mutations |
T790M Exon 20 insertion |
|||
|
ALK |
Rearrangements |
NA |
Alectinib, Brigatinib, Ceritinib, Crizotinib, Lorlatinib |
Alectinib, Brigatinib, Ceritinib, Crizotinib, Lorlatinib e |
|
ROS1 |
Rearrangements |
NA |
Crizotinib, Entrectinib |
Crizotinib, Entrectinib |
|
NTRK |
Rearrangements |
Gene fusions |
Entrectinib, larotrectinib |
Entrectinib, Larotrectinib |
|
BRAF |
Activating mutations |
V600E |
Dabrafenif + Trametinib |
Dabrafenif + Trametinib |
|
RET |
Rearrangements |
NA |
Praseltinib, Selpercatinib |
Praseltinib, Selpercatinib |
|
MET |
Activating mutations |
Exon14 Skipping |
Capmatinib, Tepotinib |
Capmatinib, Tepotinib |
|
ERBB2/HER2 |
Activating mutations |
NA |
Fam-trastuzumab |
Fam-trastuzumab |
|
KRAS |
Activating mutations |
G12C |
Adagrasib, Sotorasib |
Adagrasib, Sotorasib |
|
PD-L1 |
Expression levels |
NA |
Immune checkpoint inhibitors |
Immune checkpoint inhibitors |
|
MSI |
Genomic signaturesb |
Unstable |
Pembrolizumab |
None |
|
TMB |
Genomic signatures |
High |
DNA |
NGS |
|
TMB |
Genomic signatures |
High |
Pembrolizumab |
None |
a Approved for all activating mutation / b Approved only for exon 19 deletions and L858R / c Approved for T790M mutation-positive (second line) / d Approved for Exon 20 insertions / e Conditional approval / f Specific waiver
OncoDEEP® Test: Enhancing NSCLC treatment with precision medicine
Comprehensive biomarker testing is often used for diagnosed lung cancer patients, particularly in NSCLC for the development of patient’s treatment plan; as it looks for large number of genetic alterations and levels of specific proteins. The result of comprehensive biomarker testing helps determine whether any of the US Food and Drug Administration (FDA) or European Medicines Agency (EMA) approved lung cancer targeted therapies, or a particular immunotherapy drug is right as part of the patient’s treatment plan. It is the first step in precision medicine, ensuring that a patient gets matched to the right treatment at the right time, based on the patient’s biomarker status. Furthermore, testing results will also provide information about biomarkers that identify patients who are eligible for current clinical trial recruitment. ASCO, ESMO and NCCN also recommends the routine use of next-generation sequencing (NGS) in advanced non-squamous NSCLC, and that large multi-gene panels could be used if additional costs are considered acceptable compared versus small panels 12,13,14. Our OncoDEEP® test is designed to detect all the biomarkers as mentioned in Table 1 and 2 (and more!). We understand the challenges in detecting large array of biomarkers from low quantity and poor-quality tumor genetic material; hence with a team of experts, we have developed, optimized and validated OncoDEEP® test to be able to detect low level of biomarker in difficult to analyse tumor biopsy. Our test is sensitive enough to detect allelic frequency of 5%, and even down to 1% for FDA and EMA-approved biomarkers! Upon detecting any of the biomarkers that are associated with treatment options or recruiting clinical trials, a report will be generated to help oncologists work out the most suitable cancer treatment plan for their patients.1. World Health Organization. Globocan 2020 Fact Sheet. Available at: https://gco.iarc.fr/today/data/factsheets/populations/900-world-fact-sheets.pdf. Accessed September 2021.
2. American Cancer Society. What is Lung Cancer? Available at: http://www.cancer.org/cancer/lung-cancer/about/what-is.html. Accessed September 2021.
3. National Cancer Institute. NCI Dictionary – Small Cell Lung Cancer. Available at: https://www.cancer.gov/publications/dictionaries/cancer-terms/def/small-cell-lung-cancer. Accessed September 2021.
4. Wistuba I, Brambilla E, Noguchi M. Chapter 17: Classic Anatomic Pathology and Lung Cancer. In: Pass HI, Ball D, Scagliotti GV, eds. IASLC Thoracic Oncology, Second Edition. Philadelphia, PA: Elsevier; 2018:143-146. Accessed February 10, 2021.
5. KorpantyG, et al. Biomarkers that currently affect clinical practice in lung cancer: EGFR, ALK, MET, ROS-1, and KRAS. Frontiers in Oncology. 2014(4).
6. AwadM and Hammerman P. Durable Responses With PD-1 Inhibition in Lung and Kidney Cancer and the Ongoing Search for Predictive Biomarkers. J Clin Oncol. 2015; 33.
7. E. Smolle, K. Leithner, H. OlschewskiOncogene addiction and tumor mutational burden in non-small-cell lung cancer: clinical significance and limitations Thorac. Cancer, 11 (2) (2020), pp. 205-215
8. L. Tan, M. Alexander, A. Officer, M, et al. Survival difference according to mutation status in a prospective cohort study of Australian patients with metastatic non-small-cell lung carcinoma Int. Med. J., 48 (1) (2018), pp. 37-44
9. European Society for Medical Oncology. Metastatic Non-Small-Cell Lung Cancer: ESMO Clinical Practice Guidelines for Diagnosis, Treatment and Follow-Up
10. Herbst RS, Tsuboi M, John T, et al. Osimertinib as adjuvant therapy in patients (pts) with stage IB-IIIA EGFR mutation positive (EGFRm) NSCLC after complete tumor resection: ADAURA. J Clin Oncol. 2020;38(suppl 15):LBA5. doi:10.1200/JCO.2020.38.18_suppl.LBA5
11. Masahiro Tsuboi, Roy S. Herbst, Thomas John, Terufumi Kato, Margarita Majem, Christian Grohé, Jie Wang, Jonathan W. Goldman, Shun Lu, Wu-Chou Su, Filippo de Marinis, Frances A. Shepherd, et al., for the ADAURA Investigators*. Overall Survival with Osimertinib in Resected EGFR-Mutated NSCLC. N Engl J Med. 2023 Jun 4
12. NCCN Non-Small Cell Lung Cancer Version 3.2023 — April 13, 2023
13. Debyani Chakravarty, Amber Johnson, Jeffrey Sklar, Neal I. Lindeman, Kathleen Moore, Shridar Ganesan, Christine M. Lovly, Jane Perlmutter, Stacy W. Gray, Jimmy Hwang, Christopher Lieu, Fabrice André, Nilofer Azad, Mitesh Borad, Laura Tafe, Hans Messersmith, Mark Robson, and Funda Meric-Bernstam. Somatic Genomic Testing in Patients With Metastatic or Advanced Cancer: ASCO Provisional Clinical Opinion. Journal of Clinical Oncology 2022 40:11, 1231-1258
14. F. Mosele, J. Remon, J. Mateo, et al. Recommendations for the use of next-generation sequencing (NGS) for patients with metastatic cancers: a report from the ESMO Precision Medicine Working Group Ann. Oncol., 31 (11) (2020), pp. 1491-1505
