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Metastatic Non-Small Cell Lung Cancer - Market Insight, Epidemiology and Market Forecast -2032

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    Report

  • 630 Pages
  • November 2023
  • Region: Global
  • DelveInsight
  • ID: 5899393
UP TO OFF until Dec 31st 2024

Key Highlights

  • NSCLC market size has seen a revolutionary change in the last decade owing to the increase in incident case of NSCLC, continuous uptake of approved therapies mainly immune checkpoint inhibitors, expected entry of potential premium price emerging therapies and increasing awareness of mutations like KRAS, BRAF, c-Met and others. The total market size of metastatic NSCLC is estimated to be ~USD 45 billion by 2032 in the 7MM.
  • The real-world treatment trend depicts a drastic shift towards targeted and immunotherapies (from only systemic therapies in the past), which is expected to contribute the most now.
  • The existing NSCLC treatment is mainly dominated by Checkpoint-inhibitors such as KEYTRUDA, and OPDIVO. As far as EGFR- positive NSCLC market size is concerned, we expect third-generation EGFRs such as AstraZeneca's TAGRISSO to dominate.
  • Amgen's LUMAKRAS was approved in 2021 for NSCLC patients harbouring KRASG12C mutation. It is expected to reach approximately USD 1,300 million by the end of the forecast period.
  • ADCs are a class of oncology medications that are among the most rapidly expanding. Despite the outstanding patient responses that conventional ADCs have produced, they have only been tested on patients who have the highest levels of target expression and a narrow number of targets. Although there is only one ADC approved for NSCLC, and it is only for a limited subgroup (HER2m NSCLC), companies are attempting to target a larger NSCLC population, particularly in areas where KEYTRUDA is the market leader. Targeting the non-actionable genomic aberration NSCLC market are DATO-Dxd and TRODELVY. Among the upcoming therapies in the 7MM, Dato-DXd is expected to capture a significant market size of the patients expressing PD-L1.
  • As per the analysis, the total incident cases of NSCLC in the 7MM were approximately 527,000 cases in the year 2022, these cases are estimated to increase by the year 2032.
  • The most common alterations seen in Non-Small Cell Lung Cancer is EGFR and KRAS mutations. EGFR mutations occur in exon 19 - that's a deletion - as well as L858R exon 21.
This “Metastatic Non-small Cell Lung Cancer - Market Insights, Epidemiology and Market Forecast - 2032” report delivers an in-depth understanding of top oncogenic drivers/biomarker in Non-small Cell Lung Cancer (such as EGFR, c-MET, ROS1, KRAS, ALK, BRAF, PD-L1, etc), historical and forecasted epidemiology as well as the Non-small Cell Lung Cancer market trends in the United States, EU4 (Germany, Spain, Italy, and France) and the United Kingdom, and Japan.

Metastatic NSCLC market report provides real world prescription pattern analysis, emerging drugs, market share of individual therapies, and historical and forecasted 7MM Non-small Cell Lung Cancer market size from 2019 to 2032. The report also covers current Non-small Cell Lung Cancer treatment practices/algorithms and unmet medical needs to curate the best opportunities and assess the market's underlying potential.

Geography Covered

  • The United States
  • EU4 (Germany, France, Italy, and Spain) and the United Kingdom
  • Japan
Study Period: 2019-2032

Non-small Cell Lung Cancer Understanding and Treatment Algorithm

Non-small Cell Lung Cancer Overview and Diagnosis

Non-small Cell Lung Cancer is the most common type of lung cancer, accounting for 81% of all lung cancer diagnoses. Early diagnosis offers the best prognosis for Non-Small Cell Lung Cancer. But, Non-Small Cell Lung Cancer and other lung cancers can be difficult to diagnose because, often, these cancers have symptoms that are mistaken for common illnesses or the effects of long-term smoking. Because of this, 80 percent of people diagnosed with Non-Small Cell Lung Cancer have already progressed to advanced stages, making it more difficult to treat. If lung cancer is suspected, the physician will recommend imaging tests (CT, PET, or MRI scans) to identify abnormalities in and around your lungs. The physician may also take a sample of mucus for examination under the microscope.

If these initial tests identify cancer, a lung biopsy can be conducted. A bronchoscopy can also be recommended, which allows the physician to not only visualize but also remove tissue. If lung cancer is confirmed, genetic testing can be done on the lung tissue to identify details about the cancer that can help inform treatment.

Further details related to country-based variations in diagnosis are provided in the report

Non-small Cell Lung Cancer Treatment

Treatment options and recommendations depend on several factors, including the type and stage of cancer, possible side effects, and the patient's preferences and overall health. The most common treatments for non-small cell lung cancer are:
  • Surgery
  • Radiotherapy
  • Chemotherapy
  • Chemotherapy with radiotherapy (chemoradiotherapy)
  • Immunotherapy
  • Targeted cancer drugs
Clinical and Registrational Updates in 2023
  • NDA acceptance of repotrectinib, for the treatment of patients with ROS1-positive locally advanced or metastatic NSCLC. The FDA granted Priority Review and assigned a Prescription Drug User Fee Act (PDUFA) goal date of November 2023.
  • In January 2023, Daiichi Sankyo initiated the TROPION-Lung07 Phase III trial to evaluate datopotamab deruxtecan in combination with pembrolizumab in patients with previously untreated metastatic non-small cell lung cancer.
  • In January 2023, the EMA validated the ENHERTU Type II variation application for the treatment of HER2 mutant metastatic non-small cell lung cancer.

American Society of Clinical Oncology (ASCO) 2023 Key Updates

  • Dizal Pharmaceuticals' Sunvozertinib shines in a groundbreaking WU-KONG6 trial, unveiling remarkable antitumor effectiveness and exceptional safety in previously treated NSCLC with EGFR Exon20 insertions.
  • Updated TROPION-Lung02 results revealed Daiichi Sankyo and AstraZeneca's datopotamab deruxtecan continued success in triggering promising and persistent responses across diverse NSCLC cancer patients.
  • AstraZeneca's rilvegostomig, a TIGIT and PD-1 bispecific, offers hope for advanced PD-L1+ NSCLC after prior treatment resistance.
  • Kelun Pharma's TROP2-targeting ADC, SKB264 exhibited manageable safety and promising antitumor activity in advanced or metastatic NSCLC, with enhanced response in EGFR mutant subtype.
  • Amgen's Sotorasib provides a consistent benefit over docetaxel in the majority of key prespecified molecularly defined subsets pretreated KRAS G12C-mutated NSCLC patients enrolled in the Phase III CodeBreaK 200 trial.
  • Combining pembrolizumab with pemetrexed and platinum-based chemotherapy showed a slight numerical improvement in progression-free survival and overall survival compared to chemotherapy plus placebo. However, this improvement did not reach statistical significance in patients with TKI-resistant, EGFR-mutated, metastatic nonsquamous non-small cell lung cancer.
  • In the Phase III ADAURA trial, adjuvant treatment with AstraZeneca's osimertinib demonstrated a significant improvement in overall survival compared to placebo for patients with resected, EGFR-mutated, stage IB to IIIA non-small cell lung cancer.

Non-small Cell Lung Cancer Epidemiology

The Non-small Cell Lung Cancer epidemiology chapter in the report provides historical as well as forecasted epidemiology segmented by total incident cases of Non-small Cell Lung Cancer, total incident cases of Non-small Cell Lung Cancer by histology, total cases of Non-small Cell Lung Cancer by stages, total incident cases of Non-small Cell Lung Cancer by genetic mutation/biomarkers, total treated cases of Non-small Cell Lung Cancer by line of therapies in the 7MM covering the United States, EU4 countries (Germany, France, Italy, and Spain), United Kingdom, and Japan from 2019 to 2032.
  • In the US for 2022, there are approximately 200,000 new cases of lung cancer (~113,000 in men and ~88,000 in women). The society also reported that most lung cancer statistics include both small cell lung cancer and non-small cell lung cancer. About 10% to 15% of all lung cancers are SCLC, and about 80% to 85% are Non-Small Cell Lung Cancer.
  • The most frequent biomarkers are EGFR, and KRAS.
  • The three main histological subtypes of Non-Small Cell Lung Cancer are Adenocarcinoma, Squamous cell carcinoma, and large cell (undifferentiated) carcinoma. In the United States approximately 57% of all lung cancers are adenocarcinomas. About 25-30% of all lung cancers are Squamous cell carcinoma. Large cell (undifferentiated) carcinoma makes up around 2% of all lung cancers.
  • In 2022, there were ~115,000 metastatic NSCLC cases in the United States.

Non-small Cell Lung Cancer Drug Chapters

The drug chapter segment of the Non-small Cell Lung Cancer report encloses a detailed analysis of Non-small Cell Lung Cancer marketed drugs and late-stage (Phase III and Phase II) pipeline drugs. It also deep dives on the Non-small Cell Lung Cancer pivotal clinical trial details, recent and expected market approvals, patent details, the latest news, and recent deals and collaborations.

Marketed Drugs

KEYTRUDA (pembrolizumab): Merck

KEYTRUDA is an anti-programmed death receptor-1 (PD-1) therapy that works by increasing the ability of the body's immune system to help detect and fight tumor cells. FDA's approval in January 2023, marked the fifth indication for KEYTRUDA in non-small cell lung cancer and the first indication for KEYTRUDA in patients with resected stage IB (T2a =4 cm), II, or IIIA disease following adjuvant chemotherapy. With this approval, KEYTRUDA is the only immunotherapy with an approved option for Non-Small Cell Lung Cancer regardless of PD-L1 expression in both the adjuvant and metastatic settings. Six years ago, KEYTRUDA was the first anti-PD-1 therapy approved for the first-line treatment of metastatic non-small cell lung cancer and has changed the way metastatic disease is treated. The approval of KEYTRUDA is unfavorable for TECENTRIQ, which was the first immunotherapy to receive approval in the adjuvant setting for non-small cell lung cancer patients who underwent surgery in October 2021. KEYTRUDA's approval is more extensive compared to TECENTRIQ's approval, as it encompasses a wider range of cancer stages and PD-L1 statuses. TECENTRIQ has specifically approved for PD-L1-positive patients with stages 2 to 3A lung cancer, whereas KEYTRUDA's approval covers a broader range.

LIBTAYO (cemiplimab-rwlc): Regeneron Pharmaceuticals

LIBTAYO is a fully human monoclonal antibody targeting the immune checkpoint receptor PD-1 on T-cells and was invented using Regeneron's proprietary VelocImmune technology. In November 2022, Regeneron Pharmaceuticals announced that the US FDA has approved the PD-1 inhibitor LIBTAYO in combination with platinum-based chemotherapy for the first-line treatment of adult patients with advanced non-small cell lung cancer with no EGFR, ALK, or ROS1 aberrations. This second FDA approval for cemiplimab-rwlc in advanced non-small cell lung cancer greatly broadens the scope in which a cemiplimab-rwlc-based regimen can be prescribed to encompass a wide range of patients, either as a single agent in those with PD-L1 =50% or now in combination with chemotherapy irrespective of PD-L1 expression or tumor histology. LIBTAYO, alongside KEYTRUDA, is the only other PD-1/L1 inhibitor that can be used in combination with chemotherapy for first-line treatment of non-small cell lung cancer in the United States, irrespective of PD-L1 levels or histology. This approval complements the previous approval of LIBTAYO as a monotherapy for patients with high expression of PD-L1. However, having a similar indication to KEYTRUDA does not automatically imply that LIBTAYO will divide the market equally with the leading PD-1 inhibitor from Merck.

Note: Detailed current therapies assessment will be provided in the full report of Non-small Cell Lung Cancer

Emerging Drugs

Telisotuzumab Vedotin (Teliso-V): AbbVie

Teliso-V is an investigational antibody-drug conjugate targeting c-Met, a receptor tyrosine kinase that is overexpressed in tumors including Non-small Cell Lung Cancer. Teliso-V has the potential to become an important new treatment option in non-small cell lung cancer; with an anticipated approval in 2L+ Non-Small Cell Lung Cancer in 2024. In January 2022, AbbVie announced that the FDA granted Breakthrough Therapy Designation to investigational telisotuzumab vedotin for the treatment of patients with advanced/ metastatic epidermal growth factor receptor wild type, nonsquamous non-small cell lung cancer with high levels of c-Met overexpression whose disease has progressed on or after platinum-based therapy. In May 2022, AbbVie initiated a Phase III clinical trial to evaluate Teliso-V versus docetaxel for the treatment of patients with previously treated c-Met overexpressing, epidermal growth factor receptor wild type, advanced/metastatic non-squamous non-small cell lung cancer.

Datopotamab deruxtecan (Dato-DXd): AstraZeneca and Daiichi Sankyo

Datopotamab deruxtecan (Dato-DXd) is an investigational TROP2-directed ADC. Designed using Daiichi Sankyo's proprietary DXd ADC technology, datopotamab deruxtecan is one of the most advanced programs in AstraZeneca's ADC scientific platform and one of the three leading ADCs in the oncology pipeline of Daiichi Sankyo. In January 2023, a Phase III clinical trial in combination with immune checkpoint inhibitors for the first-line treatment for Non-Small Cell Lung Cancer without actionable genomic alterations, PD-L1 < 50% (trial name: TROPION-Lung07) was initiated. No TROP2-directed therapies are currently approved for the treatment of patients with Non-Small Cell Lung Cancer. AstraZeneca and Daiichi Sankyo are interrogating Dato-DXd in 1L non-driver mutation patients with TROPION-Lung08 (trying to knock off the Keynote-024 regimen) and with TROPION-Lung07 (trying to dethrone Keynote-189 regimen, the most important indication for Merck's KEYRTUDA), as well as covering all comer 2L and 3L patients in with TROPION-Lung01.

Note: Detailed emerging therapies assessment will be provided in the final report.

Drug Class Insights

The existing Non-small Cell Lung Cancer treatment is mainly dominated by targeted therapies for mutations such as EGFR-sensitizing mutations, EGFR exon 20 insertions, ALK fusions, ROS1 fusions, BRAFV600E mutation, MET exon 14 skipping mutations, RET fusions, and KRASG12C mutation.

Epidermal growth factor receptor (EGFR) mutations and anaplastic lymphoma kinase (ALK) rearrangements are well-known genetic abnormalities that drive the development of Non-small Cell Lung Cancer. The use of tyrosine kinase inhibitors (TKIs) as a treatment approach has shown better results in terms of patient outcomes when compared to chemotherapy.

EGFR mutations are frequently observed, EGFR exon 19 deletions and EGFR exon 21 L858R mutations. The FDA has approved various tyrosine kinase inhibitors (TKIs) to treat these mutations, with TAGRISSO (osimertinib) considered the standard treatment. GILOTRIF (afatinib) is approved for patients with other EGFR sensitivity mutations like S768I, L861Q, and G719X. However, approximately 8% to 10% of EGFR mutations involve exon 20 insertions, which do not respond to treatments targeting exon 19 or 21 alterations, including osimertinib. Currently, two targeted therapies, RYBREVANT (amivantamab) and EXKIVITY (mobocertinib) are approved for this particular mutation but only as a second-line option following platinum-based chemotherapy. These mutations represent an area of unmet medical need in Non-small Cell Lung Cancer. While treatment with EGFR TKIs effectively eliminates the majority of cancer cells, a small population of drug-tolerant cells may persist. These cells can remain inactive and undetectable for extended periods but eventually resume growth and spread to other parts of the body.

Moving onto ALK rearrangements, which are present in around 5% of Non-Small-Cell Lung Cancer cases, primarily in adenocarcinomas, and represent a distinct molecular subtype of lung cancer. The first ALK inhibitor approved for treatment was crizotinib, and subsequently, several other ALK inhibitors have received approval, including ceritinib, alectinib, brigatinib, and lorlatinib. A direct comparison among all the ALK TKIs is still lacking, but researchers are actively developing new ALK TKIs to overcome resistance to the currently available ones. This suggests the possibility of a sequential treatment strategy involving different ALK TKIs in this specific disease.

While tumors with ROS1 rearrangements, known as ROS1-positive tumors, are not common, the similarities between ROS1 and ALK receptors, as well as the similarities between ROS1-positive and ALK-positive Non-small Cell Lung Cancer, have led to the repurposing of ALK inhibitors for the treatment of ROS1-positive disease. XALKORI (crizotinib), which is already approved for treating patients with ALK fusions, became the first drug specifically indicated for patients with ROS1-positive Non-small Cell Lung Cancer in 2016.

In the treatment of patients with BRAF V600E mutations, the combination of dabrafenib and trametinib is approved. However, it is worth noting that BRAF mutations are relatively uncommon in Non-small Cell Lung Cancer compared to other cancers such as melanoma.

Even though numerous MET inhibitors with different mechanisms of action have failed to demonstrate significant effectiveness in clinical trials, the FDA has approved MET inhibitors like TABRECTA (capmatinib) and TEPMETKO (tepotinib) for treating patients with advanced Non-small Cell Lung Cancer that have MET exon 14 skipping mutations.

When treating RET alterations, Pralsetinib and selpercatinib have received approval for the same. It's important to note that RET fusions, also referred to as RET gene rearrangements, are distinct from RET mutations as they do not involve changes in the gene itself.

Currently, TRK inhibitors have demonstrated promising effectiveness and good tolerability in patients with solid tumors carrying NTRK fusions, regardless of the tumor's histology. The first-generation TRK inhibitors, such as larotrectinib and entrectinib, are recommended as the initial treatment for patients with locally advanced or metastatic Non-Small Cell Lung Cancer who have confirmed NTRK fusion. However, resistance to TRK inhibitors can eventually emerge due to various mechanisms, either directly targeting the TRK protein or through other indirect means. Interestingly, NTRK fusion has been identified as a potential resistance mechanism to EGFR-TKIs, suggesting that combining EGFR-TKIs with TRK inhibitors could be a potential treatment option for patients experiencing EGFR-TKI resistance mediated by NTRK fusion.

Considering that HER2 has emerged as a notable targetable oncogenic driver and lung cancer is of particular interest due to the significant occurrence of mutations in the tyrosine kinase domain of the HER2 gene. In August 2022, ENHERTU (fam-trastuzumab deruxtecan-nxki) received approval for the treatment of Non-Small Cell Lung Cancer patients with an activating HER2 mutation.

Targeting KRAS represents a significant advancement in the field of oncology in recent times. KRAS is the most frequently mutated oncogene in human cancer, with the highest occurrence in non-small-cell lung cancer, colorectal cancer, and pancreatic cancer. In lung cancer, the most prevalent KRAS mutation is G12C. In the past, KRAS was considered "undruggable" due to the absence of conventional drug-binding sites. However, the approval of KRAS G12C inhibitors, such as sotorasib and adagrasib, for the treatment of locally advanced or metastatic Non-Small Cell Lung Cancer, has revolutionized the approach to treating cancers with KRAS G12C mutations. Currently, numerous other KRAS players such as Gritstone Bio and Elicio Therapeutics, both are evaluating their respective Pan-KRAS Vaccines in Phase I/II along with Immuneering Corporation with its KRASG12S in early stage trial.

Targeted therapies targeting NRG1 alterations have also entered early clinical studies. Currently, there are no approved treatments specifically targeting NRG1-positive cancer. However, zenocutuzumab presents promising potential as a new standard of care. Below is a glimpse of US FDA approved therapies for NSCLC

Non-Small Cell Lung Cancer Market Outlook

As more targetable mutations are discovered and new targeted drugs are developed, patients and oncologists will have an expanding array of treatment options. Given the rapid pace of drug approvals, it is important to pause and ensure that there is sufficient data supporting the use of specific agents in the appropriate treatment settings, including adjuvant, consolidation, first-line, or subsequent therapy.

Previously, molecular-based treatments were limited to advanced-stage Non-small Cell Lung Cancer. However, recent findings have demonstrated their efficacy in early-stage and locally advanced disease as well. New studies have explored therapies that target a wider range of oncogenes, aiming to overcome drug resistance and provide treatment options for patients who were previously excluded from clinical trials for advanced-stage lung cancer. The emerging data from these ongoing trials are expected to influence future treatment guidelines and foster the adoption of personalized medicine. As a result, a continuous evolution of the treatment landscape is anticipated, ultimately leading to improved survival rates and enhanced quality of life for lung cancer patients.

Key players, such as AstraZeneca, Bristol-Myers-Squibb, AbbVie, Roche, Merck, Novartis, Pfizer, Takeda, Eli Lilly, Immutep, Sanofi, GlaxoSmithKline, and others are evaluating their lead candidates in different stages of clinical development, respectively. They aim to investigate their products for the treatment of Non-Small Cell Lung Cancer.

The total market size of PD-L1 expressing NSCLC is estimated to be ~USD 20 billion by 2032 in the 7MM followed by EGFR and KRAS.

Non-Small Cell Lung Cancer Drugs Uptake

This section focuses on the uptake rate of potential drugs expected to be launched in the market during 2019-2032, which depends on the competitive landscape, safety, and efficacy data along with order of entry. It is important to understand that the key players evaluating their novel therapies in the pivotal and confirmatory trials should remain vigilant when selecting appropriate comparators to stand the greatest chance of a positive opinion from regulatory bodies, leading to approval, smooth launch and rapid uptake.

Further detailed analysis of emerging therapies drug uptake in the report…

Non-Small Cell Lung Cancer Activities

The report provides insights into different therapeutic candidates in Phase III and Phase II stages. It also analyzes key players involved in developing targeted therapeutics.

Pipeline Development Activities

The report covers information on collaborations, acquisitions and mergers, licensing, and patent details for Non-Small Cell Lung Cancer emerging therapies.

KOL Views

To keep up with the real world scenario in current and emerging market trends, we take opinions from Key Industry leaders working in the domain through primary research to fill the data gaps and validate our secondary research. Industry Experts contacted for insights on evolving treatment landscape, patient reliance on conventional therapies, patient's therapy switching acceptability, and drug uptake along with challenges related to accessibility, including Medical/scientific writers, Medical Oncologists, Pulmonologists and Professors, Chief of the Thoracic Service at the Memorial Sloan Kettering Cancer Center, and Others.

The analysts connected with 40+ KOLs to gather insights; however, interviews were conducted with 18+ KOLs in the 7MM. Centers such as MD Anderson Cancer Center, Texas, UT Southwestern Medical Center in Dallas, Cancer Research UK Barts Centre in London, LUNGevity Foundation, etc., were contacted. Their opinion helps understand and validate current and emerging therapy treatment patterns or Non-Small Cell Lung Cancer market trends.

Qualitative Analysis

The publisher performed qualitative and market Intelligence analysis using various approaches, such as SWOT analysis. In SWOT analysis, strengths, weaknesses, opportunities, and threats in terms of gaps in disease diagnosis, patient awareness, physician acceptability, competitive landscape, cost-effectiveness, and geographical accessibility of therapies are provided.

Market Access and Reimbursement

The cost of treating Non-Small Cell Lung Cancer has shown significant increases over time, irrespective of the stage of the disease. This is particularly true for younger patients treated in the outpatient setting, according to real-world findings. Although first-generation epidermal growth factor receptor tyrosine kinase inhibitors were reimbursed and available in all countries, for other registered therapies - even for ALK inhibitors and checkpoint inhibitors in first-line - there were apparent gaps in availability and/or reimbursement.

The report further provides detailed insights on the country-wise accessibility and reimbursement scenarios, cost-effectiveness scenario of approved therapies, programs making accessibility easier and out-of-pocket costs more affordable, insights on patients insured under federal or state government prescription drug programs, etc.

Scope of the Report

  • The report covers a segment of key events, an executive summary, descriptive overview of Non-Small Cell Lung Cancer, explaining its causes, signs and symptoms, pathogenesis, and currently available therapies.
  • Comprehensive insight has been provided into the epidemiology segments and forecasts, the future growth potential of diagnosis rate, disease progression along with treatment guidelines.
  • Additionally, an all-inclusive account of both the current and emerging therapies, along with the elaborative profiles of late-stage and prominent therapies, will have an impact on the current treatment landscape.
  • A detailed review of the Non-Small Cell Lung Cancer market, historical and forecasted market size, market share by therapies, detailed assumptions, and rationale behind our approach is included in the report, covering the 7MM drug outreach.
  • The report provides an edge while developing business strategies, by understanding trends, through SWOT analysis and expert insights/KOL views, patient journey, and treatment preferences that help in shaping and driving the 7MM Non-Small Cell Lung Cancer market.

Non-Small Cell Lung Cancer Report Insights

  • Patient Population
  • Therapeutic Approaches
  • Non-Small Cell Lung Cancer Pipeline Analysis
  • Non-Small Cell Lung Cancer Market Size and Trends
  • Existing and future Market Opportunity

Non-Small Cell Lung Cancer Report Key Strengths

  • Ten Years Forecast
  • 7MM Coverage
  • Non-Small Cell Lung Cancer Epidemiology Segmentation
  • Key Cross Competition
  • Conjoint analysis
  • Drugs Uptake and Key Market Forecast Assumptions

Non-Small Cell Lung Cancer Report Assessment

  • Current Treatment Practices
  • Unmet Needs
  • Pipeline Product Profiles
  • Market Attractiveness
  • Qualitative Analysis (SWOT and Conjoint Analysis)

FAQs

  • What is the historical and forecasted Non-Small Cell Lung Cancer patient pool in the United States, EU4 (Germany, France, Italy, and Spain), the United Kingdom, and Japan?
  • What was the Non-Small Cell Lung Cancer total market size, the market size by therapies, market share (%) distribution in 2019, and what would it look like in 2032? What are the contributing factors for this growth?
  • How will different NSCLC target class affect the treatment paradigm of Non-Small Cell Lung Cancer?
  • What will be the impact of KEYTRUDA's expected patent expiry?
  • How will KEYTRUDA compete with other therapies in the first- and second lines?
  • Which class is going to be the largest contributor in 2032?
  • What are the pricing variations among different geographies for approved and off-label therapies?
  • How would the market drivers, barriers, and future opportunities affect the market dynamics and subsequent analysis of the associated trends?
  • Although multiple expert guidelines recommend testing for targetable mutations prior to therapy initiation, why do barriers to testing remain high?
  • What are the current and emerging options for the treatment of Non-Small Cell Lung Cancer?
  • How many companies are developing therapies for the treatment of Non-Small Cell Lung Cancer?
  • What are the recent novel therapies, targets, mechanisms of action, and technologies developed to overcome the limitation of existing therapies?
  • Patient acceptability in terms of preferred treatment options as per real-world scenarios?
  • What are the country-specific accessibility issues of expensive, recently approved therapies?

Reasons to Buy

  • The report will help in developing business strategies by understanding the latest trends and changing treatment dynamics driving the Non-Small Cell Lung Cancer Market.
  • Insights on patient burden/disease prevalence, evolution in diagnosis, and factors contributing to the change in the epidemiology of the disease during the forecast years
  • Understand the existing market opportunity in varying geographies and the growth potential over the coming years.
  • Distribution of historical and current patient share based on real-world prescription data along with reported sales of approved products in the US, EU4 (Germany, France, Italy, and Spain), the United Kingdom, and Japan.
  • Identifying strong upcoming players in the market will help devise strategies to help get ahead of competitors.
  • Highlights of access and reimbursement policies of approved therapies, barriers to accessibility of expensive off-label therapies, and patient assistance programs.
  • To understand Key Opinion Leaders' perspectives around the accessibility, acceptability, and compliance-related challenges of existing treatment to overcome barriers in the future.
  • Detailed insights on the unmet need of the existing market so that the upcoming players can strengthen their development and launch strategy

Table of Contents

1. Key Insights2. Report Introduction3. Executive Summary
4. NSCLC Market Overview at a Glance
4.1. Market Share (%) Distribution by Line of Therapies in 2019
4.2. Market Share (%) Distribution by Line of Therapies in 2032
5. Key Events6. Epidemiology and Market Forecast Methodology
7. Disease Background and Overview
7.1. Introduction
7.1.1. Cellular Classification of NSCLC
7.1.2. Signs and Symptoms of NSCLC
7.1.3. Risk Factors of Lung Cancer
7.1.4. Causes of NSCLC
7.1.5. Disease Biology: NSCLC
8. Diagnosis of NSCLC
8.1. Stages of NSCLC
8.2. Staging System
9. Current Treatment Practices: NSCLC
9.1. Chemotherapy
9.2. Targeted Therapy
9.3. Immunotherapy
9.4. Surgery
9.5. Radiation Therapy
9.6. Stage-wise Treatment Options of NSCLC
10. Treatment Guidelines and Recommendations for Non-small Cell Lung Cancer (NSCLC)
10.1. NCCN Guideline for NSCLC
10.2. ESMO Guideline for Non-small Cell Lung Cancer (NSCLC)
10.2.1. Non-oncogene-addicted metastatic Non-small-cell lung cancer: ESMO Clinical Practice Guidelines for Treatment.
10.2.2. Oncogene-addicted Metastatic Non-small-cell Lung Cancer: ESMO Clinical Practice Guidelines for Treatment.
10.3. Japanese Guidelines for Non-small Cell Lung Cancer (NSCLC)
10.4. Biomarkers Testing Recommendations
11. Epidemiology and Patient Population
11.1. Key Findings
11.2. Assumptions and Rationale: The 7MM
11.3. Total Incident Cases of NSCLC in the 7MM
11.4. United States Epidemiology
11.4.1. Total Incident Cases of NSCLC in the United States
11.4.2. Gender-specific Cases of NSCLC in the United States
11.4.3. Age-specific Cases of NSCLC in the United States
11.4.4. Total Incident Cases of NSCLC by Histology in the United States
11.4.5. Total Incident Cases of NSCLC by Stage (at diagnosis) in the United States
11.4.6. Total Cases of NSCLC by Genetic Mutations/Biomarkers in the United States
11.5. EU4 and the UK
11.5.1. Total Incident Cases of NSCLC in EU4 and the UK
11.5.2. Gender-specific Cases of NSCLC in EU4 and the UK
11.5.3. Age-specific Cases of NSCLC in EU4 and the UK
11.5.4. Total Incident Cases of NSCLC by Histology in EU4 and the UK
11.5.5. Total Incident Cases of NSCLC by Stage (at diagnosis) in EU4 and the UK
11.5.6. Total Cases of NSCLC by Genetic Mutations/Biomarkers in EU4 and the UK
11.6. Japan Epidemiology
11.6.1. Total Incident Cases of NSCLC in Japan
11.6.2. Gender-specific Cases of NSCLC in Japan
11.6.3. Age-specific Cases of NSCLC in Japan
11.6.4. Total Incident Cases of NSCLC by Histology in Japan
11.6.5. Total Incident Cases of NSCLC by Stage (at diagnosis) in Japan
11.6.6. Total Cases of NSCLC by Genetic Mutations/Biomarkers in Japan
12. Patient Journey13. Key Endpoints in NSCLC
14. Marketed Drugs
14.1. Key Competitors
14.2. Gilotrif/GIOTRIF (Afatinib): Boehringer Ingelheim
14.2.1. Product Description
14.2.1. Regulatory Milestones
14.2.2. Other Developmental Activities
14.2.3. Pivotal Clinical Trial
14.2.4. Current Pipeline Activity
14.2.5. Safety and Efficacy
14.2.6. Product Profile
14.3. LIBTAYO (Cemiplimab): Regeneron/Sanofi
14.3.1. Product Description
14.3.2. Regulatory Milestones
14.3.3. Other Developmental Activities
14.3.4. Pivotal Clinical Trials
14.3.5. Current Pipeline Activity
14.3.6. Safety and Efficacy
14.3.7. Product Profile
14.4. TEPMETKO (Tepotinib): EMD Serono; Merck KGaA
14.4.1. Product Description
14.4.2. Regulatory Milestones
14.4.3. Other Developmental Activities
14.4.4. Pivotal Clinical Trial
14.4.5. Current Pipeline Activity
14.4.6. Safety and Efficacy
14.4.7. Product Profile
14.5. RETEVMO (Selpercatinib): Eli Lilly
14.5.1. Product Description
14.5.2. Regulatory Milestones
14.5.3. Other Developmental Activities
14.5.4. Pivotal Clinical Trial
14.5.5. Current Pipeline Activity
14.5.6. Safety and Efficacy
14.5.7. Product Profile
14.6. KEYTRUDA (Pembrolizumab): MSD
14.6.1. Product Description
14.6.2. Regulatory Milestones
14.6.3. Other Developmental Activities
14.6.4. Pivotal Clinical Trial
14.6.5. Current Pipeline Activity
14.6.6. Safety and Efficacy
14.6.7. Product Profile
14.7. RYBREVANT (amivantamab): Janssen
14.7.1. Product Description
14.7.2. Regulatory Milestones
14.7.3. Other Developmental Activities
14.7.4. Pivotal Clinical Trial
14.7.5. Current Pipeline Activity
14.7.6. Safety and Efficacy
14.7.7. Product Profile
14.8. EXKIVITY (mobocertinib): Takeda
14.8.1. Product Description
14.8.2. Regulatory Milestones
14.8.3. Other Developmental Activities
14.8.4. Pivotal Clinical Trial
14.8.5. Current Pipeline Activity
14.8.6. Safety and Efficacy
14.8.7. Product Profile
14.9. PORTRAZZA (necitumumab): Eli Lilly
14.9.1. Product Description
14.9.2. Regulatory Milestones
14.9.3. Other Developmental Activities
14.9.4. Pivotal Clinical Trial
14.9.5. Current Pipeline Activity
14.9.6. Safety and Efficacy
14.9.7. Product Profile
14 .9. OPDIVO (nivolumab): Bristol-Myers Squibb/Ono Pharmaceutical 191
14.9.8. Product Description
14.9.9. Regulatory Milestones
14.9.10. Other Developmental Activities
14.9.11. Pivotal Clinical Trial
14.9.12. Current Pipeline Activity
14.9.13. Safety and Efficacy
14.9.14. Product Profile
14.10. TECENTRIQ (atezolizumab): Genentech/Hoffmann-La Roche
14.10.1. Product Description
14.10.2. Regulatory Milestones
14.10.3. Other Developmental Activities
14.10.4. Pivotal Clinical Trial
14.10.5. Current Pipeline Activity
14.10.6. Safety and Efficacy
14.10.7. Product Profile
14.11. LORBRENA/LORVIQUA (lorlatinib): Pfizer
14.11.1. Product Description
14.11.2. Regulatory Milestones
14.11.3. Pivotal Clinical Trial
14.11.4. Current Pipeline Activity
14.11.5. Safety and Efficacy
14.11.6. Product Profile
14.12. GAVRETO (pralsetinib): Blueprint Medicines/Hoffmann-La Roche
14.12.1. Product Description
14.12.2. Regulatory Milestones
14.12.3. Other Developmental Activities
14.12.4. Pivotal Clinical Trial
14.12.5. Current Pipeline Activity
14.12.6. Product Profile
14.13. ALUNBRIG (brigatinib): Takeda Pharmaceuticals (ARIAD Pharmaceuticals)
14.13.1. Product Description
14.13.2. Regulatory Milestones
14.13.3. Other Developmental Activities
14.13.4. Pivotal Clinical Trial
14.13.5. Current Pipeline Activity
14.13.6. Safety and Efficacy
14.13.7. Product Profile
14.14. ALECENSA (Alectinib): Genentech/Hoffmann-La Roche/Chugai Laboratories
14.14.1. Product Description
14.14.2. Regulatory Milestones
14.14.3. Other Developmental Activities
14.14.4. Pivotal Clinical Trial
14.14.5. Current Pipeline Activity
14.14.6. Safety and Efficacy
14.14.7. Product Profile
14.15. IMFINZI (durvalumab): AstraZeneca
14.15.1. Product Description
14.15.2. Regulatory Milestones
14.15.3. Other Developmental Activities
14.15.4. Pivotal Clinical Trial
14.15.5. Current Pipeline Activity
14.15.6. Safety and Efficacy
14.15.7. Product Profile
14.16. LUMAKRAS/LUMYKRAS (sotorasib): Amgen
14.16.1. Product Description
14.16.2. Regulatory Milestones
14.16.3. Other Developmental Activities
14.16.4. Pivotal Clinical Trial
14.16.5. Current Pipeline Activity
14.16.6. Safety and Efficacy
14.16.7. Product Profile
14.17. KRAZATI (adagrasib): Mirati Therapeutics
14.17.1. Product Description
14.17.2. Regulatory Milestones
14.17.3. Other Developmental Activities
14.17.4. Pivotal Clinical Trial
14.17.5. Current Pipeline Activity
14.17.6. Safety and Efficacy
14.17.7. Product Profile
14.18. TABRECTA (capmatinib): Novartis
14.18.1. Product Description
14.18.2. Regulatory Milestones
14.18.3. Other Developmental Activities
14.18.4. Pivotal Clinical Trial
14.18.5. Current Pipeline Activity
14.18.6. Safety and Efficacy
14.18.7. Product Profile
14.19. ENHERTU (trastuzumab deruxtecan): Daiichi Sankyo/AstraZeneca
14.19.1. Product Description
14.19.2. Regulatory Milestones
14.19.3. Other Developmental Activities
14.19.4. Pivotal Clinical Trials
14.19.5. Current Pipeline Activity
14.19.6. Safety and Efficacy
14.19.7. Product Profile
14.2. TAFINLAR (dabrafenib) + MEKINIST (trametinib): Novartis
14.20.1. Product Description
14.20.2. Regulatory Milestones
14.20.3. Other Developmental Activities
14.20.4. Pivotal Clinical Trial
14.20.5. Product Profile
14.21. TAGRISSO (osimertinib): AstraZeneca
14.21.1. Product Description
14.21.2. Regulatory Milestones
14.21.3. Other Developmental Activities
14.21.4. Pivotal Clinical Trials
14.21.5. Current Pipeline Activity
14.21.6. Safety and Efficacy
14.21.7. Product Profile
14.22. VIZIMPRO (dacomotinib): Pfizer
14.22.1. Product Description
14.22.2. Regulatory Milestones
14.22.3. Other Developmental Activities
14.22.4. Pivotal Clinical Trials
14.22.5. Safety and Efficacy
14.22.6. Product Profile
14.23. ROZLYTREK (entrectinib): Roche (Genentech)
14.23.1. Product Description
14.23.2. Regulatory Milestones
14.23.3. Other Developmental Activities
14.23.4. Pivotal Clinical Trials
14.23.5. Product Profile
14.24. VITRAKVI (larotrectinib): Bayer/Loxo Oncology
14.24.1. Product Description
14.24.2. Regulatory Milestones
14.24.3. Other Developmental Activities
14.24.4. Pivotal Clinical Trials
14.24.5. Current Pipeline Activity
14.24.6. Safety and Efficacy
14.24.7. Product Profile
15. Emerging Drugs
15.1. Key Competitors
15.2. Ociperlimab: BieGene
15.2.1. Product Description
15.2.2. Other Developmental Activities
15.2.3. Clinical Development
15.2.4. Safety and Efficacy
15.3. Datopotamab Deruxtecan: Daiichi Sankyo/AstraZeneca
15.3.1. Product Description
15.3.2. Other Developmental Activities
15.3.3. Clinical Development
15.3.4. Safety and Efficacy
15.4. Domvanalimab: Arcus Biosciences
15.4.1. Product Description
15.4.2. Other Developmental Activities
15.4.3. Clinical Development
15.4.4. Safety and Efficacy
15.5. Tiragolumab: Hoffmann-La Roche/Genentech
15.5.1. Product Description
15.5.2. Other Developmental Activities
15.5.3. Clinical Development
15.5.4. Safety and Efficacy
15.6. Zejula (Niraparib): GlaxoSmithKline
15.6.1. Product Description
15.6.2. Other Developmental Activities
15.6.3. Clinical Development
15.6.4. Safety and Efficacy
15.7. Pyrotinib: Jiangsu HengRui Medicine
15.7.1. Product Description
15.7.2. Clinical Development
15.8. Volrustomig: AstraZeneca
15.8.1. Product Description
15.8.2. Other Developmental Activities
15.8.3. Clinical Development
15.9. Zimberelimab: Arcus Biosciences/Gilead Sciences
15.9.1. Product Description
15.9.2. Other Developmental Activities
15.9.3. Clinical Development
15.9.4. Safety and Efficacy
15.1. Fianlimab: Regeneron Pharmaceuticals
15.10.1. Product Description
15.10.2. Other Developmental Activities
15.10.3. Clinical Development
15.11. HLX10: Shanghai Henlius Biotech
15.11.1. Product Description
15.11.2. Other Developmental Activities
15.11.3. Clinical Development
15.12. Cobolimab: GlaxoSmithKline
15.12.1. Product Description
15.12.2. Other Developmental Activities
15.12.3. Clinical Development
15.13. BRAFTOVI (encorafenib) + MEKTOVI (binimetinib): Pfizer
15.13.1. Product Description
15.13.2. Other Developmental Activities
15.13.3. Clinical Development
15.13.4. Safety and Efficacy
15.14. Telisotuzumab Vedotin: AbbVie
15.14.1. Product Description
15.14.2. Other Developmental Activities
15.14.3. Clinical Development
15.14.4. Safety and Efficacy
15.15. Savolitinib: AstraZeneca
15.15.1. Product Description
15.15.2. Other Developmental Activities
15.15.3. Clinical Development
15.15.4. Safety and Efficacy
15.16. Taletrectinib (DS-6051b; AB-106): AnHeart Therapeutics
15.16.1. Product Description
15.16.2. Other Developmental Activities
15.16.3. Clinical Development
15.16.4. Safety and Efficacy
15.17. Repotrectinib (TPX-0005): Bristol-Myers Squibb
15.17.1. Product Description
15.17.2. Other Developmental Activities
15.17.3. Clinical Development
15.17.4. Safety and Efficacy
15.18. NVL-520: Nuvalent
15.18.1. Product Description
15.18.2. Other Developmental Activities
15.18.3. Clinical Development
15.18.4. Safety and Efficacy
15.19. Zipalertinib (CLN-081/TAS6417): Cullinan Oncology/Taiho Pharma
15.19.1. Product Description
15.19.2. Other Developmental Activities
15.19.3. Clinical Development
15.19.4. Safety and Efficacy
15.2. Patritumab Deruxtecan: Daiichi Sankyo
15.20.1. Product Description
15.20.2. Other Developmental Activities
15.20.3. Clinical Development
15.20.4. Safety and Efficacy
15.21. Furmonertinib: ArriVent BioPharma
15.21.1. Product Description
15.21.2. Other Developmental Activities
15.21.3. Clinical Development
15.21.4. Safety and Efficacy
15.22. Naptumomab Estafenatox (NAP) + Docetaxel Following Obinutuzumab: NeoTX Therapeutics
15.22.1. Product Description
15.22.2. Other Developmental Activity
15.22.3. Clinical Development
15.23. AB-16B5 + Docetaxel: Alethia Biotherapeutics
15.23.1. Product Description
15.23.2. Other Developmental Activities
15.23.3. Clinical Development
15.24. Ceralasertib: AstraZeneca
15.24.1. Product Description
15.24.2. Other Developmental Activities
15.24.3. Clinical Development
15.25. ZYNYZ (retifanlimab/INCMGA00012) + Chemotherapy: Incyte/Macrogenics
15.25.1. Product Description
15.25.2. Other Developmental Activities
15.25.3. Clinical Development
15.25.4. Safety and Efficacy
15.26. Gotistobart (BNT316 /ONC-392):
15.26.1. Product Description
15.26.2. Other Developmental Activities
15.26.3. Clinical Development
15.26.4. Safety and Efficacy
15.27. Tusamitamab ravtansine: Sanofi
15.27.1. Product Description
15.27.2. Other Developmental Activities
15.27.3. Clinical Development
15.27.4. Safety and Efficacy
15.28. NVL-655: Nuvalent
15.28.1. Product Description
15.28.2. Other Developmental Activities
15.28.3. Clinical Development
15.29. Ensartinib: Xcovery
15.29.1. Product Description
15.29.2. Other Developmental Activities
15.29.3. Clinical Development
15.29.4. Safety and Efficacy
15.3. LY3537982: Eli Lilly and Company
15.30.1. Product Description
15.30.2. Other Developmental Activities
15.30.3. Clinical Development
15.30.4. Safety and Efficacy
15.31. JDQ443: Novartis
15.31.1. Product Description
15.31.2. Other Developmental Activities
15.31.3. Clinical Development
15.31.4. Safety and Efficacy
15.32. Divarasib: Roche (Genentech)
15.32.1. Product Description
15.32.2. Other Developmental Activities
15.32.3. Clinical Development
15.32.4. Safety and Efficacy
15.33. RMC-4630: Revolution Medicines
15.33.1. Product Description
15.33.2. Other Developmental Activities
15.33.3. Clinical Development
15.33.4. Safety and Efficacy
15.34. SLATE-KRAS: Gritstone bio
15.34.1. Product Description
15.34.2. Other Developmental Activities
15.34.3. Clinical Development
15.34.4. Safety and Efficacy
15.35. Aumolertinib: EQRx
15.35.1. Product Description
15.35.2. Other Developmental Activity
15.35.3. Clinical Development
15.35.4. Safety and Efficacy
15.36. Eftilagimod alpha: Immutep/ Merck Sharp & Dohme Corp
15.36.1. Product Description
15.36.2. Other Developmental Activities
15.36.3. Clinical Development
15.36.4. Safety and Efficacy
15.37. Ivonescimab: Akeso Biopharma
15.37.1. Product Description
15.37.2. Other Developmental Activity
15.37.3. Clinical Development
15.37.4. Safety and Efficacy
15.38. Sunvozertinib: Dizal Pharmaceutical
15.38.1. Product Description
15.38.2. Other Developmental Activities
15.38.3. Clinical Development
15.38.4. Safety and Efficacy
16. NSCLC : 7MM Market Analysis
16.1. Key Findings
16.1.1. Total Market Size of NSCLC in the 7MM
16.2. Market Outlook
16.2.1. PD-L1 expressions
16.2.2. EGFR Mutation
16.2.3. ALK Mutation
16.2.4. KRAS Mutation
16.2.5. BRAF Mutation
16.2.6. MET Mutation
16.2.7. Others NSCLC Mutations
16.3. Key Market Forecast Assumptions
16.3.1. PD-L1-mutated NSCLC
16.3.2. EGFR-mutated NSCLC
16.3.3. ALK-mutated NSCLC
16.3.4. HER2-mutated NSCLC
16.4. United States Market Size
16.4.1. Total Market Size of PD-L1 NSCLC in the United States
16.4.2. Market Size of PD-L1 NSCLC by Therapies in the United States
16.4.3. Total Market Size of EGFR NSCLC in the United States
16.4.4. Market Size of EGFR NSCLC by Therapies in the United States
16.4.5. Total Market Size of ALK NSCLC in the United States
16.4.6. Market Size of ALK NSCLC by Therapies in the United States
16.4.7. Total Market Size of KRAS NSCLC in the United States
16.4.8. Market Size of KRAS NSCLC by Therapies in the United States
16.4.9. Total Market Size of ROS-1 NSCLC in the United States
16.4.10. Market Size of ROS-1 NSCLC by Therapies in the United States
16.4.11. Total Market Size of BRAF NSCLC in the United States
16.4.12. Market Size of BRAF NSCLC by Therapies in the United States
16.4.13. Total Market Size of MET NSCLC in the United States
16.4.14. Market Size of MET NSCLC by Therapies in the United States
16.4.15. Total Market Size of HER2 NSCLC in the United States
16.4.16. Market Size of HER2 NSCLC by Therapies in the United States
16.4.17. Total Market Size of RET NSCLC in the United States
16.4.18. Market Size of RET NSCLC by Therapies in the United States
16.4.19. Total Market Size of NTRK NSCLC in the United States
16.4.20. Market Size of NTRK NSCLC by Therapies in the United States
16.5. EU4 and the UK Market Size
16.5.1. Total Market Size of PD-L1 NSCLC in EU4 and the UK
16.5.2. Market Size of PD-L1 NSCLC by Therapies in EU4 and the UK
16.5.3. Total Market Size of EGFR NSCLC in EU4 and the UK
16.5.4. Market Size of EGFR NSCLC by Therapies in EU4 and the UK
16.5.5. Total Market Size of ALK NSCLC in EU4 and the UK
16.5.6. Market Size of ALK NSCLC by Therapies in EU4 and the UK
16.5.7. Total Market Size of KRAS NSCLC in EU4 and the UK
16.5.8. Market Size of KRAS NSCLC by Therapies in EU4 and the UK
16.5.9. Total Market Size of ROS-1 NSCLC in EU4 and the UK
16.5.10. Market Size of ROS-1 NSCLC by Therapies in EU4 and the UK
16.5.11. Total Market Size of BRAF NSCLC in EU4 and the UK
16.5.12. Market Size of BRAF NSCLC by Therapies in EU4 and the UK
16.5.13. Total Market Size of MET NSCLC in EU4 and the UK
16.5.14. Market Size of MET NSCLC by Therapies in EU4 and the UK
16.5.15. Total Market Size of HER2 NSCLC in EU4 and the UK
16.5.16. Market Size of HER2 NSCLC by Therapies in EU4 and the UK
16.5.17. Total Market Size of RET NSCLC in EU4 and the UK
16.5.18. Market Size of RET NSCLC by Therapies in EU4 and the UK
16.5.19. Total Market Size of NTRK NSCLC in EU4 and the UK
16.5.20. Market Size of NTRK NSCLC by Therapies in EU4 and the UK
16.6. Japan Market Size
16.6.1. Total Market Size of PD-L1 NSCLC in Japan
16.6.2. Market Size of PD-L1 NSCLC by Therapies in Japan
16.6.3. Total Market Size of EGFR NSCLC in Japan
16.6.4. Market Size of EGFR NSCLC by Therapies in Japan
16.6.5. Total Market Size of ALK NSCLC in Japan
16.6.6. Market Size of ALK NSCLC by Therapies in Japan
16.6.7. Total Market Size of KRAS NSCLC in Japan
16.6.8. Market Size of KRAS NSCLC by Therapies in Japan
16.6.9. Total Market Size of ROS-1 NSCLC in Japan
16.6.10. Market Size of ROS-1 NSCLC by Therapies in Japan
16.6.11. Total Market Size of BRAF NSCLC in Japan
16.6.12. Market Size of BRAF NSCLC by Therapies in Japan
16.6.13. Total Market Size of MET NSCLC in Japan
16.6.14. Market Size of MET NSCLC by Therapies in Japan
16.6.15. Total Market Size of HER2 NSCLC in Japan
16.6.16. Market Size of HER2 NSCLC by Therapies in Japan
16.6.17. Total Market Size of RET NSCLC in Japan
16.6.18. Market Size of RET NSCLC by Therapies in Japan
16.6.19. Total Market Size of NTRK NSCLC in Japan
16.6.20. Market Size of NTRK NSCLC by Therapies in Japan
17. Unmet Needs18. SWOT Analysis19. KOL Views
20. Market Access and Reimbursement
20.1. Patient Access Program
20.2. Institute for Quality and Efficiency in Health Care (IQWiG): Germany
20.3. NSCLC Reimbursement in France
20.4. Italian Medicines Agency (AIFA): Italy
20.5. NSCLC Reimbursement in Spain
20.6. National Institute for Health and Care Excellence (NICE): The UK
20.7. Reimbursement Status of Lung Cancer Drugs in Japan
21. Appendix
21.1. Bibliography
21.2. Report Methodology
22. Publisher Capabilities23. Disclaimer24. About the Publisher
List of Tables
Table 1: TNM Staging of NSCLC
Table 2: Standard Treatment Options of NSCLC (Stage-wise)
Table 3: Molecular and Biomarker-directed Therapy for Advanced or Metastatic Disease
Table 4: Molecular and biomarker-directed therapy for advanced or metastatic disease
Table 5: PD-L1 =50% First-line Therapy
Table 6: PD-L1 =1-49% First-line Therapy
Table 7: PD-L1 =50% Continuation Maintenance
Table 8: PD-L1 =1-49% Continuation Maintenance
Table 9: Primary Treatment for EGFR Gene Mutation-positive: Exon 19 Deletion or L858R Mutation-positive
Table 10: First-line Treatment for EGFR Mutation-positive: Exon 18-21 mutations (Excluding Exon 19 Deletion and L858R Mutation)
Table 11: After Second-line Treatment for EGFR Mutation-positive
Table 12: Primary Treatment for ALK Fusion Gene Positivity
Table 13: After Second-line Treatment for ALK Fusion Gene-positive Patients
Table 14: MET Gene Mutation Positive
Table 15: RET Fusion Gene Positive
Table 16: KRAS Gene G12C Mutation Positive
Table 17: Driver gene mutation/translocation negative
Table 18: Driver Gene Mutation/Translocation Negative, PD-L1 TPS 1-49% Primary Treatment
Table 19: Driver Gene Mutation/Translocation Negative, PD-L1 TPS < 1% Primary Treatment
Table 20: Driver Mutation/Translocation Negative, PS 2 First-line Treatment
Table 21: Primary Treatment for Poor PS Cases
Table 22: First-line Treatment Regimen
Table 23: Second-line and Beyond Regimens
Table 24: Non-Small-Cell Lung Cancer Immune/Molecular Biomarker
Table 25: Tumor Biomarker Testing Rate
Table 26: Total Incident Cases of NSCLC in the 7MM (2019-2032)
Table 27: Total Incident Cases of NSCLC in the United States (2019-2032)
Table 28: Gender-specific Cases of NSCLC in the United States (2019-2032)
Table 29: Age-specific Cases of NSCLC in the United States (2019-2032)
Table 30: Total Incident Cases of NSCLC by Histology in the United States (2019-2032)
Table 31: Total Incident Cases of NSCLC by Stage in the United States (2019-2032)
Table 32: Total Incident Cases of Advanced/Metastatic NSCLC in the United States (2019-2032)
Table 33: Total Cases of NSCLC by Genetic Mutations/Biomarkers in the United States (2019-2032)
Table 34: Total Incident Cases of NSCLC in EU4 and the UK (2019-2032)
Table 35: Gender-specific Cases of NSCLC in EU4 and the UK (2019-2032)
Table 36: Age-specific Cases of NSCLC in EU4 and the UK (2019-2032)
Table 37: Total Incident Cases of NSCLC by Histology in EU4 and the UK (2019-2032)
Table 38: Total Incident Cases of NSCLC by Stage (at diagnosis) in EU4 and the UK (2019-2032)
Table 39: Total Incident Cases of Advanced/Metastatic NSCLC in the EU4 and the UK (2019-2032)
Table 40: Total Cases of NSCLC by Genetic Mutations/Biomarkers in EU4 and the UK (2019-2032)
Table 41: Total Incident Cases of NSCLC in Japan (2019-2032)
Table 42: Gender-specific Cases of NSCLC in Japan (2019-2032)
Table 43: Age-specific Cases of NSCLC in Japan (2019-2032)
Table 44: Total Incident Cases of NSCLC by Histology in Japan (2019-2032)
Table 45: Total Incident Cases of NSCLC by Stage(at diagnosis) in Japan (2019-2032)
Table 46: Total Cases of NSCLC by Genetic Mutations/Biomarkers in Japan (2019-2032)
Table 47: Marketed Drug Key Competitors
Table 48: Gilotrif/GIOTRIF (Afatinib): Clinical Trial Description, 2023
Table 49: LIBTAYO (Cemiplimab) : Clinical Trial Description, 2023
Table 50: TEPMETKO (Tepotinib) : Clinical Trial Description, 2023
Table 51: RETEVMO (Selpercatinib): Clinical Trial Description, 2023
Table 52: KEYTRUDA (pembrolizumab), Clinical Trial Description, 2023
Table 53: Recommended Dose of RYBREVANT Based on Baseline Body Weight and Dosing Schedule for RYBREVANT
Table 54: RYBREVANT (Amivantamab): Clinical Trial Description, 2023
Table 55: Recommended EXKIVITY Dose Reductions
Table 56: EXKIVITY (Mobocertinib): Clinical Trial Description, 2023
Table 57: PORTRAZZA (Necitumumab) : Clinical Trial Description, 2023
Table 58: OPDIVO (Nivolumab): Clinical Trial Description, 2023
Table 59: TECENTRIQ (Atezolizumab): Clinical Trial Description, 2023
Table 60: LORBRENA/LORVIQUA (Lorlatinib): Clinical Trial Description, 2023
Table 61: GAVRETO (pralsetinib): Clinical Trial Description, 2023
Table 62: ALUNBRIG (Brigatinib): Clinical Trial Description, 2023
Table 63: ALECENSA (Alectinib): Clinical Trial Description, 2023
Table 64: IMFINZI (Durvalumab): Clinical Trial Description, 2023
Table 65: LUMAKRAS/LUMYKRAS, Clinical Trial Description, 2023
Table 66: KRAZATI, Clinical Trial Description, 2023
Table 67: Patent and Exclusivity for N213591
Table 68: TABRECTA: Clinical Trial Description, 2023
Table 69: ENHERTU: Clinical Trial Description, 2023
Table 70: TAGRISSO: AstraZeneca: Clinical Trial Description, 2023
Table 71: VITRAKVI (larotrectinib): Clinical Trial Description, 2023
Table 72: Ociperlimab (anti-TIGIT) + Tislelizumab, Clinical Trial Description, 2023
Table 73: Datopotamab Deruxtecan + Pembrolizumab ± Platinum Chemotherapy, Clinical Trial
Table 74: Domvanalimab + Zimberelimab, Clinical Trial Description, 2023
Table 75: Tiragolumab, Clinical Trial Description, 2023
Table 76: Niraparib, Clinical Trial Description, 2023
Table 77: Pyrotinib, Clinical Trial Description, 2023
Table 78: Volrustomig, Clinical Trial Description, 2023
Table 79: Zimberelimab, Clinical Trial Description, 2023
Table 80: Fianlimab (higher dose) + cemiplimab + platinum-doublet chemotherapy, Clinical
Table 81: HLX10, Clinical Trial Description, 2023
Table 82: Cobolimab, Clinical Trial Description, 2023
Table 83: BRAFTOVI (encorafenib) + MEKTOVI (binimetinib): Clinical Trial Description, 20
Table 84: Telisotuzumab vedotin (Teliso-V): Clinical Trial Description, 2023
Table 85: Savolitinib: Clinical Trial Description, 2023
Table 86: Taletrectinib (DS-6051b; AB-106): Clinical Trial Description, 2023
Table 87: Repotrectinib (TPX-0005): Clinical Trial Description, 2023
Table 88: NVL-520: Clinical Trial Description, 2023
Table 89: Zipalertinib (CLN-081/TAS6417): Clinical Trial Description, 2023
Table 90: Patritumab Deruxtecan: Clinical Trial Description, 2023
Table 91: Furmonertinib: Clinical Trial Description, 2023
Table 92: Naptumomab estafenatox (NAP) + docetaxel: Clinical Trial Description, 2023
Table 93: AB-16B5 + docetaxel: Clinical Trial Description, 2023
Table 94: Ceralasertib: Clinical Trial Description, 2023
Table 95: ZYNYZ (retifanlimab/INCMGA00012): Clinical Trial Description, 2023
Table 96: Gotistobart (BNT316/ONC-392): Clinical Trial Description, 2023
Table 97: Tusamitamab ravtansine: Clinical Trial Description, 2023
Table 98: NVL-655: Clinical Trial Description, 2023
Table 99: Ensartinib: Clinical Trial Description, 2023
Table 100: LY3537982: Clinical Trial Description, 2023
Table 101: JDQ443: Clinical Trial Description, 2023
Table 102: Divarasib: Clinical Trial Description, 2023
Table 103: RMC-4630: Clinical Trial Description, 2023
Table 104: SLATE-KRAS: Clinical Trial Description, 2023
Table 105: Aumolertinib: Clinical Trial Description, 2023
Table 106: Eftilagimod alpha: Clinical Trial Description, 2023
Table 107: Ivonescimab: Clinical Trial Description, 2023
Table 108: Sunvozertinib: Clinical Trial Description, 2023
Table 109: Key Market Forecast Assumption of PD-L1-mutated NSCLC in the United States
Table 110: Key Market Forecast Assumption of PD-L1-mutated NSCLC in EU4 and the UK
Table 111: Key Market Forecast Assumption of PD-L1-mutated NSCLC in Japan
Table 112: Key Market Forecast Assumption of EGFR-mutated NSCLC in the US
Table 113: Key Market Forecast Assumption of EGFR-mutated NSCLC in EU4 and the UK
Table 114: Key Market Forecast Assumption of EGFR-mutated NSCLC in Japan
Table 115: Key Market Forecast Assumption of ALK-mutated NSCLC in the US
Table 116: Key Market Forecast Assumption of ALK-mutated NSCLC in EU4 and the UK
Table 117: Key Market Forecast Assumption of ALK-mutated NSCLC in Japan
Table 118: Key Market Forecast Assumption of HER2-mutated NSCLC in the US
Table 119: Key Market Forecast Assumption of HER2-mutated NSCLC in EU4 and the UK
Table 120: Key Market Forecast Assumption of HER2-mutated NSCLC in Japan
Table 121: Key Market Forecast Assumption of RET-mutated NSCLC in the US
Table 122: Key Market Forecast Assumption of RET-mutated NSCLC in EU4 and the UK
Table 123: Key Market Forecast Assumption of RET-mutated NSCLC in Japan
Table 124: Key Market Forecast Assumption of NTRK-mutated NSCLC in the US
Table 125: Key Market Forecast Assumption of NTRK-mutated NSCLC in EU4 and the UK
Table 126: Key Market Forecast Assumption of NTRK-mutated NSCLC in Japan
Table 127: Key Market Forecast Assumption of ROS-1 -mutated NSCLC in the US
Table 128: Key Market Forecast Assumption of ROS-1 -mutated NSCLC in EU4 and the UK
Table 129: Key Market Forecast Assumption of ROS-1 -mutated NSCLC in Japan
Table 130: Key Market Forecast Assumption of MET -mutated NSCLC in the US
Table 131: Key Market Forecast Assumption of MET- mutated NSCLC in EU4 and the UK
Table 132: Key Market Forecast Assumption of MET -mutated NSCLC in Japan
Table 133: Total Market Size of PD-L1 NSCLC in the United States, in USD million
Table 134: Market Size of PD-L1 NSCLC by Therapies in the United States, in USD million
Table 135: Total Market Size of EGFR NSCLC in the United States, in USD million
Table 136: Market Size of EGFR NSCLC by Therapies in the United States, in USD million
Table 137: Total Market Size of ALK NSCLC in the United States, in USD million
Table 138: Market Size of ALK NSCLC by Therapies in the United States, in USD million
Table 139: Total Market Size of KRAS NSCLC in the United States, in USD million
Table 140: Market Size of KRAS NSCLC by Therapies in the United States, in USD million
Table 141: Total Market Size of ROS-1 NSCLC in the United States, in USD million
Table 142: Market Size of ROS-1 NSCLC by Therapies in the United States, in USD million
Table 143: Total Market Size of BRAF NSCLC in the United States, in USD million
Table 144: Market Size of BRAF NSCLC by Therapies in the United States, in USD million
Table 145: Total Market Size of MET NSCLC in the United States, in USD million
Table 146: Market Size of MET NSCLC by Therapies in the United States, in USD million
Table 147: Total Market Size of HER2 NSCLC in the United States, in USD million
Table 148: Market Size of HER2 NSCLC by Therapies in the United States, in USD million
Table 149: Total Market Size of RET NSCLC in the United States, in USD million
Table 150: Market Size of RET NSCLC by Therapies in the United States, in USD million
Table 151: Total Market Size of NTRK NSCLC in the United States, in USD million
Table 152: Market Size of NTRK NSCLC by Therapies in the United States, in USD million
Table 153: Total Market Size of PD-L1 NSCLC in EU4 and the UK, in USD million
Table 154: Market Size of PD-L1 NSCLC by Therapies in EU4 and the UK, in USD million
Table 155: Total Market Size of EGFR NSCLC in EU4 and the UK, in USD million
Table 156: Market Size of EGFR NSCLC by Therapies in EU4 and the UK, in USD million
Table 157: Total Market Size of ALK NSCLC in EU4 and the UK, in USD million
Table 158: Market Size of ALK NSCLC by Therapies in EU4 and the UK, in USD million
Table 159: Total Market Size of KRAS NSCLC in EU4 and the UK, in USD million
Table 160: Market Size of KRAS NSCLC by Therapies in EU4 and the UK, in USD million
Table 161: Total Market Size of ROS-1 NSCLC in EU4 and the UK, in USD million
Table 162: Market Size of ROS-1 NSCLC by Therapies in EU4 and the UK, in USD million
Table 163: Total Market Size of BRAF NSCLC in EU4 and the UK, in USD million
Table 164: Market Size of BRAF NSCLC by Therapies in EU4 and the UK, in USD million
Table 165: Total Market Size of MET NSCLC in EU4 and the UK, in USD million
Table 166: Market Size of MET NSCLC by Therapies in EU4 and the UK, in USD million
Table 167: Total Market Size of HER2 NSCLC in EU4 and the UK, in USD million
Table 168: Market Size of HER2 NSCLC by Therapies in EU4 and the UK, in USD million
Table 169: Total Market Size of RET NSCLC in EU4 and the UK, in USD million
Table 170: Market Size of RET NSCLC by Therapies in EU4 and the UK, in USD million
Table 171: Total Market Size of NTRK NSCLC in EU4 and the UK, in USD million
Table 172: Market Size of NTRK NSCLC by Therapies in EU4 and the UK, in USD million
Table 173: Total Market Size of PD-L1 NSCLC in Japan, in USD million
Table 174: Market Size of PD-L1 NSCLC by Therapies in Japan, in USD million
Table 175: Total Market Size of EGFR NSCLC in Japan, in USD million
Table 176: Market Size of EGFR NSCLC by Therapies in Japan, in USD million
Table 177: Total Market Size of ALK NSCLC in Japan, in USD million
Table 178: Market Size of ALK NSCLC by Therapies in Japan, in USD million
Table 179: Total Market Size of KRAS NSCLC in Japan, in USD million
Table 180: Market Size of KRAS NSCLC by Therapies in Japan, in USD million
Table 181: Total Market Size of ROS-1 NSCLC in Japan, in USD million
Table 182: Market Size of ROS-1 NSCLC by Therapies in Japan, in USD million
Table 183: Total Market Size of BRAF NSCLC in Japan, in USD million
Table 184: Market Size of BRAF NSCLC by Therapies in Japan, in USD million
Table 185: Total Market Size of MET NSCLC in Japan, in USD million
Table 186: Market Size of MET NSCLC by Therapies in Japan, in USD million
Table 187: Total Market Size of HER2 NSCLC in Japan, in USD million
Table 188: Market Size of HER2 NSCLC by Therapies in Japan, in USD million
Table 189: Total Market Size of RET NSCLC in Japan, in USD million
Table 190: Market Size of RET NSCLC by Therapies in Japan, in USD million
Table 191: Total Market Size of NTRK NSCLC in Japan, in USD million
Table 192: Market Size of NTRK NSCLC by Therapies in Japan, in USD million
Table 193: IQWiG Assessment for NSCLC Therapies
Table 194: Haute Autorité de santé (HAS) Decisions for NSCLC Therapies
Table 195: AIFA Assessment for NSCLC Therapies
Table 196: Difficulties on the Access to Innovative-targeted Therapies for Lung Cancer in
Table 197: NICE Assessment for NSCLC Therapies
Table 198: Reimbursement Statement for 13 Drug and Indication Combinations for Seven Targeted Lung Cancer Therapies
List of Figures
Figure 1: TNM Staging of NSCLC
Figure 2: Standard Treatment Options of NSCLC (Stage-wise)
Figure 3: Molecular and Biomarker-directed Therapy for Advanced or Metastatic Disease
Figure 4: Molecular and biomarker-directed therapy for advanced or metastatic disease
Figure 5: PD-L1 =50% First-line Therapy
Figure 6: PD-L1 =1-49% First-line Therapy
Figure 7: PD-L1 =50% Continuation Maintenance
Figure 8: PD-L1 =1-49% Continuation Maintenance
Figure 9: Primary Treatment for EGFR Gene Mutation-positive: Exon 19 Deletion or L858R Mutation-positive
Figure 10: First-line Treatment for EGFR Mutation-positive: Exon 18-21 mutations (Excluding Exon 19 Deletion and L858R Mutation)
Figure 11: After Second-line Treatment for EGFR Mutation-positive
Figure 12: Primary Treatment for ALK Fusion Gene Positivity
Figure 13: After Second-line Treatment for ALK Fusion Gene-positive Patients
Figure 14: MET Gene Mutation Positive
Figure 15: RET Fusion Gene Positive
Figure 16: KRAS Gene G12C Mutation Positive
Figure 17: Driver gene mutation/translocation negative
Figure 18: Driver Gene Mutation/Translocation Negative, PD-L1 TPS 1-49% Primary Treatment
Figure 19: Driver Gene Mutation/Translocation Negative, PD-L1 TPS < 1% Primary Treatment
Figure 20: Driver Mutation/Translocation Negative, PS 2 First-line Treatment
Figure 21: Primary Treatment for Poor PS Cases
Figure 22: First-line Treatment Regimen
Figure 23: Second-line and Beyond Regimens
Figure 24: Non-Small-Cell Lung Cancer Immune/Molecular Biomarker
Figure 25: Tumor Biomarker Testing Rate
Figure 26: Total Incident Cases of NSCLC in the 7MM (2019-2032)
Figure 27: Total Incident Cases of NSCLC in the United States (2019-2032)
Figure 28: Gender-specific Cases of NSCLC in the United States (2019-2032)
Figure 29: Age-specific Cases of NSCLC in the United States (2019-2032)
Figure 30: Total Incident Cases of NSCLC by Histology in the United States (2019-2032)
Figure 31: Total Incident Cases of NSCLC by Stage in the United States (2019-2032)
Figure 32: Total Incident Cases of Advanced/Metastatic NSCLC in the United States (2019-2032)
Figure 33: Total Cases of NSCLC by Genetic Mutations/Biomarkers in the United States (2019-2032)
Figure 34: Total Incident Cases of NSCLC in EU4 and the UK (2019-2032)
Figure 35: Gender-specific Cases of NSCLC in EU4 and the UK (2019-2032)
Figure 36: Age-specific Cases of NSCLC in EU4 and the UK (2019-2032)
Figure 37: Total Incident Cases of NSCLC by Histology in EU4 and the UK (2019-2032)
Figure 38: Total Incident Cases of NSCLC by Stage (at diagnosis) in EU4 and the UK (2019-2032)
Figure 39: Total Incident Cases of Advanced/Metastatic NSCLC in the EU4 and the UK (2019-2032)
Figure 40: Total Cases of NSCLC by Genetic Mutations/Biomarkers in EU4 and the UK (2019-2032)
Figure 41: Total Incident Cases of NSCLC in Japan (2019-2032)
Figure 42: Gender-specific Cases of NSCLC in Japan (2019-2032)
Figure 43: Age-specific Cases of NSCLC in Japan (2019-2032)
Figure 44: Total Incident Cases of NSCLC by Histology in Japan (2019-2032)
Figure 45: Total Incident Cases of NSCLC by Stage(at diagnosis) in Japan (2019-2032)
Figure 46: Total Cases of NSCLC by Genetic Mutations/Biomarkers in Japan (2019-2032)
Figure 47: Key Market Forecast Assumption of PD-L1-mutated NSCLC in the United States
Figure 48: Key Market Forecast Assumption of PD-L1-mutated NSCLC in EU4 and the UK
Figure 49: Key Market Forecast Assumption of PD-L1-mutated NSCLC in Japan
Figure 50: Key Market Forecast Assumption of EGFR-mutated NSCLC in the US
Figure 51: Key Market Forecast Assumption of EGFR-mutated NSCLC in EU4 and the UK
Figure 52: Key Market Forecast Assumption of EGFR-mutated NSCLC in Japan
Figure 53: Key Market Forecast Assumption of ALK-mutated NSCLC in the US
Figure 54: Key Market Forecast Assumption of ALK-mutated NSCLC in EU4 and the UK
Figure 55: Key Market Forecast Assumption of ALK-mutated NSCLC in Japan
Figure 56: Key Market Forecast Assumption of HER2-mutated NSCLC in the US
Figure 57: Key Market Forecast Assumption of HER2-mutated NSCLC in EU4 and the UK
Figure 58: Key Market Forecast Assumption of HER2-mutated NSCLC in Japan
Figure 59: Key Market Forecast Assumption of RET-mutated NSCLC in the US
Figure 60: Key Market Forecast Assumption of RET-mutated NSCLC in EU4 and the UK
Figure 61: Key Market Forecast Assumption of RET-mutated NSCLC in Japan
Figure 62: Key Market Forecast Assumption of NTRK-mutated NSCLC in the US
Figure 63: Key Market Forecast Assumption of NTRK-mutated NSCLC in EU4 and the UK
Figure 64: Key Market Forecast Assumption of NTRK-mutated NSCLC in Japan
Figure 65: Key Market Forecast Assumption of ROS-1 -mutated NSCLC in the US
Figure 66: Key Market Forecast Assumption of ROS-1 -mutated NSCLC in EU4 and the UK
Figure 67: Key Market Forecast Assumption of ROS-1 -mutated NSCLC in Japan
Figure 68: Key Market Forecast Assumption of MET -mutated NSCLC in the US
Figure 69: Key Market Forecast Assumption of MET- mutated NSCLC in EU4 and the UK
Figure 70: Key Market Forecast Assumption of MET -mutated NSCLC in Japan
Figure 71: Total Market Size of PD-L1 NSCLC in the United States, in USD million
Figure 72: Market Size of PD-L1 NSCLC by Therapies in the United States, in USD million
Figure 73: Total Market Size of EGFR NSCLC in the United States, in USD million
Figure 74: Market Size of EGFR NSCLC by Therapies in the United States, in USD million
Figure 75: Total Market Size of ALK NSCLC in the United States, in USD million
Figure 76: Market Size of ALK NSCLC by Therapies in the United States, in USD million
Figure 77: Total Market Size of KRAS NSCLC in the United States, in USD million
Figure 78: Market Size of KRAS NSCLC by Therapies in the United States, in USD million
Figure 79: Total Market Size of ROS-1 NSCLC in the United States, in USD million
Figure 80: Market Size of ROS-1 NSCLC by Therapies in the United States, in USD million
Figure 81: Total Market Size of BRAF NSCLC in the United States, in USD million
Figure 82: Market Size of BRAF NSCLC by Therapies in the United States, in USD million
Figure 83: Total Market Size of MET NSCLC in the United States, in USD million
Figure 84: Market Size of MET NSCLC by Therapies in the United States, in USD million
Figure 85: Total Market Size of HER2 NSCLC in the United States, in USD million
Figure 86: Market Size of HER2 NSCLC by Therapies in the United States, in USD million
Figure 87: Total Market Size of RET NSCLC in the United States, in USD million
Figure 88: Market Size of RET NSCLC by Therapies in the United States, in USD million
Figure 89: Total Market Size of NTRK NSCLC in the United States, in USD million
Figure 90: Market Size of NTRK NSCLC by Therapies in the United States, in USD million
Figure 91: Total Market Size of PD-L1 NSCLC in EU4 and the UK, in USD million
Figure 92: Market Size of PD-L1 NSCLC by Therapies in EU4 and the UK, in USD million
Figure 93: Total Market Size of EGFR NSCLC in EU4 and the UK, in USD million
Figure 94: Market Size of EGFR NSCLC by Therapies in EU4 and the UK, in USD million
Figure 95: Total Market Size of ALK NSCLC in EU4 and the UK, in USD million
Figure 96: Market Size of ALK NSCLC by Therapies in EU4 and the UK, in USD million
Figure 97: Total Market Size of KRAS NSCLC in EU4 and the UK, in USD million
Figure 98: Market Size of KRAS NSCLC by Therapies in EU4 and the UK, in USD million
Figure 99: Total Market Size of ROS-1 NSCLC in EU4 and the UK, in USD million
Figure 100: Market Size of ROS-1 NSCLC by Therapies in EU4 and the UK, in USD million
Figure 101: Total Market Size of BRAF NSCLC in EU4 and the UK, in USD million
Figure 102: Market Size of BRAF NSCLC by Therapies in EU4 and the UK, in USD million
Figure 103: Total Market Size of MET NSCLC in EU4 and the UK, in USD million
Figure 104: Market Size of MET NSCLC by Therapies in EU4 and the UK, in USD million
Figure 105: Total Market Size of HER2 NSCLC in EU4 and the UK, in USD million
Figure 106: Market Size of HER2 NSCLC by Therapies in EU4 and the UK, in USD million
Figure 107: Total Market Size of RET NSCLC in EU4 and the UK, in USD million
Figure 108: Market Size of RET NSCLC by Therapies in EU4 and the UK, in USD million
Figure 109: Total Market Size of NTRK NSCLC in EU4 and the UK, in USD million
Figure 110: Market Size of NTRK NSCLC by Therapies in EU4 and the UK, in USD million
Figure 111: Total Market Size of PD-L1 NSCLC in Japan, in USD million
Figure 112: Market Size of PD-L1 NSCLC by Therapies in Japan, in USD million
Figure 113: Total Market Size of EGFR NSCLC in Japan, in USD million
Figure 114: Market Size of EGFR NSCLC by Therapies in Japan, in USD million
Figure 115: Total Market Size of ALK NSCLC in Japan, in USD million
Figure 116: Market Size of ALK NSCLC by Therapies in Japan, in USD million
Figure 117: Total Market Size of KRAS NSCLC in Japan, in USD million
Figure 118: Market Size of KRAS NSCLC by Therapies in Japan, in USD million
Figure 119: Total Market Size of ROS-1 NSCLC in Japan, in USD million
Figure 120: Market Size of ROS-1 NSCLC by Therapies in Japan, in USD million
Figure 121: Total Market Size of BRAF NSCLC in Japan, in USD million
Figure 122: Market Size of BRAF NSCLC by Therapies in Japan, in USD million
Figure 123: Total Market Size of MET NSCLC in Japan, in USD million
Figure 124: Market Size of MET NSCLC by Therapies in Japan, in USD million
Figure 125: Total Market Size of HER2 NSCLC in Japan, in USD million
Figure 126: Market Size of HER2 NSCLC by Therapies in Japan, in USD million
Figure 127: Total Market Size of RET NSCLC in Japan, in USD million
Figure 128: Market Size of RET NSCLC by Therapies in Japan, in USD million
Figure 129: Total Market Size of NTRK NSCLC in Japan, in USD million
Figure 130: Market Size of NTRK NSCLC by Therapies in Japan, in USD million
Figure 131: IQWiG Assessment for NSCLC Therapies
Figure 132: Haute Autorité de santé (HAS) Decisions for NSCLC Therapies
Figure 133: AIFA Assessment for NSCLC Therapies
Figure 134: Difficulties on the Access to Innovative-targeted Therapies for Lung Cancer in
Figure 135: NICE Assessment for NSCLC Therapies
Figure 136: Reimbursement Statement for 13 Drug and Indication Combinations for Seven Targeted Lung Cancer Therapies
Figure 137: Market Size of ALK NSCLC by Therapies in the United States, in USD million
Figure 138: Total Market Size of KRAS NSCLC in the United States, in USD million
Figure 139: Market Size of KRAS NSCLC by Therapies in the United States, in USD million
Figure 140: Total Market Size of ROS-1 NSCLC in the United States, in USD million
Figure 141: Market Size of ROS-1 NSCLC by Therapies in the United States, in USD million
Figure 142: Total Market Size of BRAF NSCLC in the United States, in USD million
Figure 143: Market Size of BRAF NSCLC by Therapies in the United States, in USD million
Figure 144: Total Market Size of MET NSCLC in the United States, in USD million
Figure 145: Market Size of MET NSCLC by Therapies in the United States, in USD million
Figure 146: Total Market Size of HER2 NSCLC in the United States, in USD million
Figure 147: Market Size of HER2 NSCLC by Therapies in the United States, in USD million
Figure 148: Total Market Size of RET NSCLC in the United States, in USD million
Figure 149: Market Size of RET NSCLC by Therapies in the United States, in USD million
Figure 150: Total Market Size of NTRK NSCLC in the United States, in USD million
Figure 151: Market Size of NTRK NSCLC by Therapies in the United States, in USD million
Figure 152: Total Market Size of PD-L1 NSCLC in EU4 and the UK, in USD million
Figure 153: Market Size of PD-L1 NSCLC by Therapies in EU4 and the UK, in USD million
Figure 154: Total Market Size of EGFR NSCLC in EU4 and the UK, in USD million
Figure 155: Market Size of EGFR NSCLC by Therapies in EU4 and the UK, in USD million
Figure 156: Total Market Size of ALK NSCLC in EU4 and the UK, in USD million
Figure 157: Market Size of ALK NSCLC by Therapies in EU4 and the UK, in USD million
Figure 158: Total Market Size of KRAS NSCLC in EU4 and the UK, in USD million
Figure 159: Market Size of KRAS NSCLC by Therapies in EU4 and the UK, in USD million
Figure 160: Total Market Size of ROS-1 NSCLC in EU4 and the UK, in USD million
Figure 161: Market Size of ROS-1 NSCLC by Therapies in EU4 and the UK, in USD million
Figure 162: Total Market Size of BRAF NSCLC in EU4 and the UK, in USD million
Figure 163: Market Size of BRAF NSCLC by Therapies in EU4 and the UK, in USD million
Figure 164: Total Market Size of MET NSCLC in EU4 and the UK, in USD million
Figure 165: Market Size of MET NSCLC by Therapies in EU4 and the UK, in USD million
Figure 166: Total Market Size of HER2 NSCLC in EU4 and the UK, in USD million
Figure 167: Market Size of HER2 NSCLC by Therapies in EU4 and the UK, in USD million
Figure 168: Total Market Size of RET NSCLC in EU4 and the UK, in USD million
Figure 169: Market Size of RET NSCLC by Therapies in EU4 and the UK, in USD million
Figure 170: Total Market Size of NTRK NSCLC in EU4 and the UK, in USD million
Figure 171: Market Size of NTRK NSCLC by Therapies in EU4 and the UK, in USD million
Figure 172: Total Market Size of PD-L1 NSCLC in Japan, in USD million
Figure 173: Market Size of PD-L1 NSCLC by Therapies in Japan, in USD million
Figure 174: Total Market Size of EGFR NSCLC in Japan, in USD million
Figure 175: Market Size of EGFR NSCLC by Therapies in Japan, in USD million
Figure 176: Total Market Size of ALK NSCLC in Japan, in USD million
Figure 177: Market Size of ALK NSCLC by Therapies in Japan, in USD million
Figure 178: Total Market Size of KRAS NSCLC in Japan, in USD million
Figure 179: Market Size of KRAS NSCLC by Therapies in Japan, in USD million
Figure 180: Total Market Size of ROS-1 NSCLC in Japan, in USD million
Figure 181: Market Size of ROS-1 NSCLC by Therapies in Japan, in USD million
Figure 182: Total Market Size of BRAF NSCLC in Japan, in USD million
Figure 183: Market Size of BRAF NSCLC by Therapies in Japan, in USD million
Figure 184: Total Market Size of MET NSCLC in Japan, in USD million
Figure 185: Market Size of MET NSCLC by Therapies in Japan, in USD million
Figure 186: Total Market Size of HER2 NSCLC in Japan, in USD million
Figure 187: Market Size of HER2 NSCLC by Therapies in Japan, in USD million
Figure 188: Total Market Size of RET NSCLC in Japan, in USD million
Figure 189: Market Size of RET NSCLC by Therapies in Japan, in USD million
Figure 190: Total Market Size of NTRK NSCLC in Japan, in USD million
Figure 191: Market Size of NTRK NSCLC by Therapies in Japan, in USD million
Figure 192: IQWiG Assessment for NSCLC Therapies
Figure 193: Haute Autorité de santé (HAS) Decisions for NSCLC Therapies
Figure 194: AIFA Assessment for NSCLC Therapies
Figure 195: Difficulties on the Access to Innovative-targeted Therapies for Lung Cancer in
Figure 196: NICE Assessment for NSCLC Therapies
Figure 197: Reimbursement Statement for 13 Drug and Indication Combinations for Seven Targeted Lung Cancer Therapies

Companies Mentioned (Partial List)

A selection of companies mentioned in this report includes, but is not limited to:

  • AbbVie
  • Akeso Biopharma
  • Alethia Biotherapeutics
  • AnHeart Therapeutics
  • Arcus Biosciences
  • ArriVent BioPharma
  • AstraZeneca
  • BieGene
  • Bristol-Myers Squibb
  • Cullinan Oncology
  • Daiichi Sankyo
  • Dizal Pharmaceutical
  • Eli Lilly and Company
  • EQRx
  • Genentech
  • Gilead Sciences
  • GlaxoSmithKline
  • Gritstone bio
  • Hoffmann-La Roche
  • Immutep
  • Incyte
  • Jiangsu HengRui Medicine
  • Macrogenics
  • Merck Sharp & Dohme Corp
  • NeoTX Therapeutics
  • Novartis
  • Nuvalent
  • Pfizer
  • Regeneron Pharmaceuticals
  • Revolution Medicines
  • Roche (Genentech)
  • Sanofi
  • Shanghai Henlius Biotech
  • Taiho Pharma
  • Xcovery