Molecular Targeted Drugs and Biomarkers in NSCLC, the Evolving Role of Individualized Therapy.

Lung cancer first line treatment has been directed from the non-specific cytotoxic doublet chemotherapy to the molecular targeted. The major limitation of the targeted therapies still remains the small number of patients positive to gene mutations. Furthermore, the differentiation between second line and maintenance therapy has not been fully clarified and differs in the clinical practice between cancer centers. The authors present a segregation between maintenance treatment and second line and present a possible definition for the term "maintenance" treatment. In addition, cancer cell evolution induces mutations and therefore either targeted therapies or non-specific chemotherapy drugs in many patients become ineffective. In the present work pathways such as epidermal growth factor, anaplastic lymphoma kinase, met proto-oncogene and PI3K are extensively presented and correlated with current chemotherapy treatment. Future, perspectives for targeted treatment are presented based on the current publications and ongoing clinical trials.

Background

Although cancer therapeutics has achieved several advances in the treatment of lung cancer patients, lung cancer remains the leading cause of cancer-related mortality. Lung cancers are divided into two histological groups: Non-Small Cell lung Cancers (NSCLC) and Small Cell Lung Cancer (SCLC). In addition, 85% of all lung cancers are categorized as NSCLC 1 which is further subdivided into adenocarcinoma, squamous cell carcinoma and large cell carcinoma, roughly accounting for almost 80% of the lung tumors 2. Although lung cancer has been epidemiologically associated largely with cigarette smoking 3, lifestyle, diet, passive smoking, and occupational exposure have also been found to play contributory roles 4-7.

Disease stage determines the treatment of NSCLC which includes surgery, radiation, platinum-based doublet chemotherapy and recently targeted therapies by interrupting signaling pathways responsible for cell proliferation and survival. Earlier stages of the disease benefit from systemic chemotherapy, which is also therapeutic strategy for stages II and III of NSCLC 8-10. Besides, early-stage and localized disease treatment are still maintained by surgery. Moreover, according to some studies, palliative chemotherapy or radiation therapy has shown improvements in survival and quality of life measures in patients with advanced and metastatic disease 11, 12. In general, classical chemotherapy (platinum-doublet, taxanes, gemcitabine, pemetrexed) results in modest efficacy, thus, multimodal therapeutic strategy has become an important treating option for NSCLC patients. In several studies, two or more drug combinations were proven to have superior efficacy but at the expense of added toxicity 13, 14.

Recently, according to the National Cancer Institute Office of Cancer Genomics, enhancement of the understanding of the molecular mechanisms of cancer, acceleration of genomic science and technology development and translation of genomic data to improve cancer prevention, early detection, diagnosis, and treatment are the goals established for the facilitation of personalized cancer medicine 15.

Additionally, until recently the most effective targeted drugs in the management of NSCLC include the epidermal growth factor receptor (EGFR) and the angiogenesis pathway 16. Erlotinib which targets the EGFR and crizotinib which targets EML4/ALK molecular pathway are the only agents currently approved in the United States as third-line therapy for patients with advanced/metastatic NSCLC 17. Furthermore, according to Azzoli et al immediate treatment with an alternative single-agent chemotherapy such as pemetrexed in patients with nonsquamous histology, docetaxel in unselected patients, or erlotinib in unselected patients might be considered for NSCLC patients with stable disease or response after four cycles 18. Among the targeted agents that have undergone evaluation for third-line therapy and beyond are afatinib, apatinib, axitinib, AUY922, pazopanib, sorafenib, sunitinib, and vandetanib 17.

The last decade clinical research is strongly occupied with the identification of mutations and aberrations concerning NSCLC molecular pathways which has enabled a personalized medicine approach to treatment 19. According to The National Institute of Health (NIH) a biomarker is defined as a characteristic that is objectively measured and evaluated as an indicator of normal biologic processes, pathogenic processes, or pharmacologic responses to a therapeutic intervention 20.

Thus, recent studies have focused their efforts into incorporating tumor genotyping into clinical decision-making. To date, molecular biomarkers such as EGFR, is included as standard care for NSCLC patients and K-ras mutations include an emerging tool in NSCLC therapy 21, 22. Besides, currently large-scale testing for somatic alterations in proto-oncogene B-Raf (BRAF), phosphatidylinositol-4,5-bisphosphate 3-kinase, catalytic subunit alpha (PIK3CA), human epidermal growth factor receptor 2 (HER2), and anaplastic lymphoma kinase (ALK) is also feasible and impacts therapeutic decisions 23. As far as gene expression in NSCLC is concerned, the association between COX-2 or p53 overexpression and survival in lung cancer patients has not yet reached a satisfactory clinical interest 24, 25.

Moreover, customizing chemotherapy by histological subtype has been included in researchers' practice such as pemetrexed for nonsquamous tumors 26 or the addition of a monoclonal antibody to the chemotherapy such as bevacizumab 22, 26 and cetuximab 27.

Despite the development of new chemotherapeutics, NSCLC still has a 5-year survival rate in only 14% implying the need for the continuing research for novel treatments 28. In the present review, we are focusing on the ongoing research concerning the treatment of NSCLC patients in clinical trials, including the elucidation of molecular biomarkers and the introduction of novel molecular targeted drugs which are being evaluated as monotherapy or in combination with other treatments.

Molecular pathways and targeted therapies

Targeting epidermal growth factor receptor (EGFR)

EGFR family a tyrosine kinase receptor, (also known as HER or ErbB family) includes four members: epidermal growth factor receptor (EGFR) or HER1/ErbB1, HER2/ErbB2, HER3/ErbB3, HER4/ErbB4. This EGFR family activates two major downstream intracellular pathways in solid tumors, the RAS/RAF/MEK/MARK and the PI3K/AKT/mTOR pathway, which induce cancer cell proliferation, cell growth, invasion, metastatic spread, apoptosis, and tumor angiogenesis 29. EGFR overexpression is found in approximately 40%-80% of the NSCLC patients 1 and has been associated with poor prognosis 30. Thus, EGFR signaling is the most intensively studied of the four family members and one of the major targets of NSCLC treatment. (Figure 1, 2) (Table 1)

Figure 1

IGF-1; insulin growth factor-1, IGF-1R; insulin growth factor receptor-1, EGF; epidermal growth factor, EGFR; epidermal growth factor receptor, VEGF; vascular endothelial growth factor, VEGFR; vascular endothelial growth factor receptor, PI3K; phosphatidylinositide 3-kinase, PTEN; phosphatase and tensin homologue, SHC; Src homology/collagen, SOS; son of sevenless, GRB2; growth factor receptor-bound protein 2, GAP; GTPase activating protein, GDP; guanosine diphosphate, GEF; guanine nucleotide exchange factors, EML4-ALK; echinoderm microtubule-associated protein-like 4 fused with the anaplastic lymphoma kinase, ERK; extracellular signal-regulated kinases, GTP; guanosine trisphate, MEK; mitogen-activated protein kinase, RAF; proto-oncogene serine/threonine-protein kinase, PIP2; phosphatidylinositol 4,5-bisphosphate, PIP3; phosphatidylinositol 3,4,5-triphosphate, RAS; Rat sarcoma, HER2; Human Epidermal Growth Factor Receptor 2. Activation of the growth factors to transmembrane tyrosine kinase receptors finally increases cell growth, proliferation, metabolism and survival.

Figure 2

TKI; tyrosine kinase inhibitors, S6K1; 40S ribosomal protein S6 kinase, IRS1/2; insulin receptor substrate, 4E-BP1; 4E binding protein-1, Akt; protein kinase B, mTOR; mammalian target of rapamycin, STRAD; Ste20-like adaptor protein, TSC; tuberous sclerosis complex, AMPK; adenosine mono-phosphate-activated protein kinase, LKB1; liver kinase B1, HGF; hepatocyte growth factor, MET; mesenchymal-epithelial transition factor, Rho; RAS homolog gene family, Rac1; RAS-related C3 botulinum toxin substrate 1, CDC42; cell division cycle 42, Rheb; Ras homolog enriched in brain, MO25; monoclonal antibody, ERBB3; v-erb-b2 erythroblastic leukemia viral oncogene homolog 3. Growth factors when activated trigger the mTOR-signaling pathway finally resulting in increased cell growth, gene transcription and cell proliferation.

Table 1

Targeted therapies

First nameSTUDY	Primary Endpoint/objective	n	PLACE OF STUDY	PHASE/Programme	STAGE OF NSCLC	TREATMENT	EGFR positive	PATIENTS pre-treatment	OBJECTIVE RESPONSE RATE(ORR)%	MEDIAN OVERALL SURVIVAL (OS)	MEDIAN PROGRESSION -FREE SURVIVAL (PFS)
Kris et al 2003	symptomatic and radiographic response	221	USA	II	IIIB or IV	gefitinib	No	Pretreated/ platinum- or taxane-based CT	22	6-7	-
Simon et al 2003	OS	183	USA	prospective landmark analysis	advanced	gefitinib	No	Pretreated	3.8	8.8	3.6
Gaafar et al 2011(EORTC study 08021/ILCP 01/03)	OS	173	Egypt	III	advanced	gefitinib	No	Pretreated/platinum-based CT	-	10.9	4.1
Wang et al 2006	OS	151	China	Expanded Access Programme	IIIb or IV	gefitinib	No	Pretreated/ platinum- or taxane-based CT	29.8	15.3	12.0
Fukuoka et al 2003(The IDEAL 1 Trial)	efficacy and tolerability of two doses	210	Japan	II	advanced NSCLC	Gefitinib (250-mg)	No	Pretreated/platinum- or taxane-based CT	18.4	8.0	2.8
Thatcher et al 2005ISEL	OS	1692	UK	III	IIIB or IV	gefitinib	No	pretreated/platinum- or taxane-based CT	-	5.6	3
Giaccone et al 2004(INTACT 1)	OS	1093	The Netherlands	III	III or IV	Gefitinib + gemcitabine and cisplatin	No	untreated	49.7	9.9	5.5
Herbst et al 2004(INTACT 2)	OS	1037	USA	III	III or IV	Gefitinib + paclitaxel and carboplatin	No	untreated		8.7
Mitsudomi et al 2010 (WJTOG3405)	PFS	177	Japan	III	III or IV	Gefitinib vs cisplatin and docetaxel	Yes	untreated	62.1	30.9	9.2
Fukuoka et al 2011(IPAS)	OS	1217	Japan	III	III or IV	gefitinib vs carboplatin/paclitaxel	Yes	untreated	43	18.8	5.7
Mok et al 2009	PFS	609	Asia	III	III or IV	gefitinib	Yes	untreated	71.2	18.6	5.7
Maemondo et al 2010	PFS	230	Japan	-	III or IV	gefitinib or carboplatin-paclitaxel.	Yes	untreated	73.7	30.5	10.8
Shepherd et al 2005 (BR21)	OS	731	Canada	III	IIIB or IV	erlotinib	No	pretreated	8.9	6.7	2.2
Zhou et al 2011 (OPTIMAL, CTONG-0802)	PFS	154	China	III	IIIB or IV	erlotinib vs gemcitabine plus carboplatin	Yes	untreated	83	-	13.1
Rosell et al 2012 (EURTAC)	PFS	174	Europe	III	Advanced NSCLC	erlotinib vs platinum-based CT	Yes	untreated	54.4	22.9	9.4
Pallis et al 2012	PFS	49	Greece	II	IIIB/IV	erlotinib	No	untreated	24.5	15.5	6.7
Ramalingam et al 2012	PFS	188	USA	II	advanced	erlotinib vs dacomitinib	Yes	pretreated	-	7.44	1.91
Cufer et al 2006(SIGN)	assessment of symptom improvement	141	Slovenia	II	advanced NSCLC	gefitinib vs docetaxel	No	pretreated/platinum- or taxane-based	13.2	7.5	3.0
Miller et al 2012 (LUX-Lung 1)	OS	697	USA	IIb/III	IIIB or IV	afatinib	Yes	pretreated	-	10.8	3.3
Yang et al 2012(LUX-Lung 2)	ORR	129	Taiwan	II	stage IIIb with pleural effusion or stage IV/adenocarcinoma	afatinib	Yes	Pretreated platinum- or taxane-based	61	24.8	10.1
Sequist et al2013 (LUX-Lung 3)	PFS	1269	-	III	IIIB/IV lung adenocarcinoma	afatinib	yes	untreated	-	-	11.1
Sequist et al 2010	ORR	167	USA	II	advanced	neratinib	Yes	pretreated	54	-	15.3weeks
Butts et al 2007	RR	131	Canada	II	IIIB / IV	cetuximab	No	pretreated gemcitabine/platinum	27.7	11.99	5.09
Rosell et al 2008	activity, safety and pharmacokinetics	86	Spain	II	advanced	cetuximab	Yes	pretreated cisplatin and vinorelbine	38	8.3	5.0
Lynch et al 2010 (BMS099)	PFS	676	USA	III	IIIB / IV	cetuximab	No	Pretreated taxane/carboplatin	25.7%	9.69	4.40
Pirker et al 2009(FLEX)	OS	1125	Austria	III	IIIB / IV	cetuximab	No	pretreated cisplatin and vinorelbine	-	11.3	4.8
Hanna et al 2006	RR	66	USA	II	advanced	cetuximab	Yes	Pretreated taxane/carboplatin	5%	8.9	2.3
Ramalingam et al 2011	12-week PFS	172	USA	II	advanced	Erlotinib + R1507 16 mg/kg	No	Pretreated/ taxane/carboplatin	-	12.1	44%
Maruyama et al 2010 V-15-32	OS	489	Japan	III	advanced/metastatic	gefitinib versus docetaxel	No	Pretreated/ taxane/carboplatin	22.5	-	2
Lee et al 2010	PFS	161	Korea	III	advanced/metastatic	gefitinib versus docetaxel	No	Pretreated platinum-based CT	28.1%	-	-
Kim et al 2008(INTEREST)	OS	1466	USA	III	advanced	gefitinib versus docetaxel	No	Pretreated platinum-based regimen	9.1	7.6	2.2
Herbst et al 2005TRIBUTE	OS	1059	USA	III	IIIB/IV	erlotinib + carboplatin and paclitaxel	No	untreated	21.5	10.6	-
Wheatley-Price et al 2008 BR21	PFS, OS, RR, QOL	731	Canada	III	advanced	erlotinib	No	Elderly pretreated 1st line	8.9	6.7	2.2
						VEGF
LeCaer et al(GFPC 0505)	TTP2	100	France	II	IIIB/IV	gemcitabine (G) followed by erlotinib	No	Untreated/elderly	13.6	4.4	-
Niho et al 2012(JO19907)	PFS	180	Japan	II	IIIB, IV or recurrentnon-squamous	bevacizumab	No	Pretreated carboplatin-paclitaxel	60.7	22	-
Reck et al 2009(AVAIL)	OS to PFS	1043	Germany.	III	advanced nonsquamous	bevacizumab	No	Pretreated cisplatin/gemcitabine	30.4	6.7	13.6
Takeda et al 2012(WJOG 5910L)	PFS		Japan	II	advanced nonsquamous	bevacizumab	No	Pretreated 1st line bevacizumab +a platinum-based doublet	40	13.0	5.6
Heymach et al 2007	PFS	127	USA	II	IIIB/IV	vandetanib plus docetaxel	No	Pretreated 1st line platinum-based CT	32	-	11.5
de Boer et al 2011	PFS	534	Australia	III	advanced	vandetanib plus pemetrexed	No	Pretreated-failure 1st line treatment	19	10.5	17.6
Lee et al 2012(ZEPHYR)	OS	924	Korea	III	advanced	Vandetanib	No	Pretreated-treatment failure with an EGFR TKI	2.6	8.5	1.9

More specifically, one strategy for the inhibition of EGFR includes EGFR tyrosine kinase inhibitors (TKIs) which target the intracellular tyrosine kinase (TK) domain of EGFR, blocking the downstream signaling of the receptor 31.

EGFR inhibitors include small molecule tyrosine kinase inhibitors (TKIs) such as gefitinib, erlotinib and afatinib and monoclonal antibodies such as cetuximab which have been studied in phase III trials and are currently clinically being used in NSCLC patients. Among these EGFR inhibitors, only erlotinib has been approved in many countries as second-line therapy for advanced NSCLC patients 32. To date, gefitinib (ZD1839; Iressa) and erlotinib (OSI-774; Tarceva) are the most studied of the EGFR TKIs for the treatment of NSCLC.

Several phase II trials 33 34, 35 or phase III trials 36 have favored gefitinib in pretreated patients and even as first line treatment. Indeed, since 2005 several studies included gefitinib monotherapy as first line treatment in untreated NSCLC patients with some efficacy 37-41 or limited results due to interstitial lung disease (ILD) an adverse effect 42, 43. Although the most common adverse events are skin rash and diarrhea, ILD is a more serious co-morbidity of NSCLC associated with gefitinib and other cancer treatments. ILD-type events that were more common in Asian patients, appeared in overall incidence of approximately 1% in gefitinib recipients participating in clinical trials 44.

A Double-blind, randomized phase II trial conducted from November 2000 to April 2001 in 30 US academic and community oncology centers enrolled 221 patients with either stage IIIB or IV NSCLC for which they had received at least two chemotherapy regimens before gefitinib with results favoring gefitinib 33. In a single-center experience, reported by Simon et al 2003, (N=183) gefitinib demonstrated clinically significant antitumor activity and provided good palliation in a predominantly pretreated group of patients 34. In another randomized, double-blind, parallel-group, multicenter phase II trial (N=210), NSCLC patients who were previously treated with one or two chemotherapy regimens (at least one containing platinum) were randomly assigned to receive either 250-mg or 500-mg oral doses of gefitinib once daily, showing clinically meaningful antitumor activity 35.

However, the Iressa Survival Evaluation in Lung Cancer (ISEL), a placebo-controlled phase III study which investigated the effect on survival of gefitinib as second-line or third-line treatment for patients with locally advanced or metastatic NSCLC (N=1692) showed disappointing results 45. Because of this trial's results, even though gefitinib was the first TKI to be approved in 2003 for the third-line treatment of NSCLC, two years later the US FDA allowed its use only within clinical trials or to patients who had already received a clinical benefit.

Furthermore, in phase III trials INTACT 1 and 2 gefitinib either in combination with gemcitabine and cisplatin in chemotherapy-naive patients with advanced NSCLC did not have improved efficacy over gemcitabine and cisplatin alone 46 or in combination with paclitaxel and carboplatin showed any added benefit in survival, time to progression (TTP) or response rate (RR), when compared with standard chemotherapy alone 47.

Overall, gefitinib therapy has not shown the expected response to unselected patients. Recently several research groups identified EGFR gene mutations as predictive factors for drug sensitivity 48-51. EGFR mutations have been identified in larger numbers in Asians, women, non-smokers, and patients with adenocarcinoma, groups. It is a fact that, after the Iressa Pan-Asia Study trial (IPAS), based on progression free survival (PFS) results, gefitinib was approved for the treatment of NSCLC with certain EGFR mutations in all lines of therapy identifying the highly gefitinib-sensitive clinical subset 52.

These mutations lead to increased growth factor signaling and confer susceptibility to the inhibitor. Screening for such mutations in lung cancers identifies patients who will have a clinical responsiveness to gefitinib 48, 53. Since the existence of EGFR gene mutations (exon 19 deletions or the exon 21 L858R) were reported as a predictive factor for sensitivity to EGFR-TKIs, several studies based their research on this conclusion 54, 55. Indeed, a lot of studies concluded that gefitinib was superior to carboplatin-paclitaxel 56-58 or cisplatin-docetaxel 51, 52 as an initial treatment, that improved PFS and that the presence in the tumor of a mutation of the EGFR gene was a strong predictor of a better outcome with gefitinib.

As for erlotinib, it was approved by FDA in 2004, based on the results of the BR21 trial, a phase III international, randmized, double-blind, placebo-controlled trial that compared erlotinib (150 mg daily) plus best supportive care (BSC) with BSC alone in second- and third-line settings in 731 unselected patients with no EGFR mutation testing concluded 21.

Erlotinib as first line treatment when compared with chemotherapy improved Quality of life (QoL) 59 and conferred a significant PFS 60 not only in Chinese patients with advanced EGFR mutation-positive NSCLC in OPTIMAL (CTONG-0802), an open-label, randomized phase III trial, but also in European patients in EURTAC, another multicentre, open-label, randomized phase 3 trial 61. More specifically, in EURTAC trial (NCT00446225) erlotinib was compared with standard chemotherapy for first-line treatment of European patients (N=174) with advanced EGFR-mutation positive NSCLC 61. Patients received oral erlotinib per day or 3 week cycles of standard intravenous chemotherapy of cisplatin on day 1 plus docetaxel or gemcitabine on days 1 and 8. Their findings strengthened the rationale for routine baseline tissue-based assessment of EGFR mutations in patients with NSCLC and for treatment of mutation-positive patients with EGFR tyrosine-kinase inhibitors.

Besides, in recent phase II clinical trials it was suggested that the use of clinical (smoking status) and pathologic (adenocarcinoma) criteria might identify a subgroup of patients with advanced/metastatic NSCLC who can benefit from front-line treatment with erlotinib when mutation testing is not feasible 62, 63.

Even though plenty clinical trials showed good response rates and PFS 64, 65 in NSCLC patients with EGFR mutations, acquired resistance in these patients responsive to EGFR-TKIs is a major clinical problem 66. Phase III randomized controlled trials of NSCLC EGFR mutated patients receiving EGFR TKIs as front line treatment versus platinum doublets carboplatin and paclitaxel have shown a benefit in response and progression-free survival, but not in overall survival 56. Thus, EGFR gene mutation currently cannot be considered a reliable biomarker for consistent response in NSCLC.

Since gefitinib or erlotinib can provide temporary success only, the need of novel treatments is crucial. To overcome secondary EGFR-TKI resistance, both preclinical and clinical evidence suggest that irreversible TKIs such as afatinib or PF00299804, or combined approaches using multiple kinase inhibition 67 and vertical inhibition combining small molecules and anti-EGFR antibodies such as cetuximab (chimeric human-mouse anti-EGFR) 68 69 seem to be more promising for the near future.

More specifically, afatinib an irreversible HER2 kinase inhibitor BIBW 2992, has been evaluated in Phase I studies 70 71. The determination of the maximum-tolerated dose for Phase II (50 mg/day) has been accomplished 71 and is currently being used in phase II clinical trials 72 (LUX-Lung clinical trial program). In a recent study by Hirsh et al results from LUX-Lung 1 trial were evaluated concerning symptom and Quality of Life benefit of afatinib in advanced NSCLC patients previously treated with erlotinib or gefitinib. They reported that the addition of afatinib to best supportive care (BSC) significantly improved NSCLC-related symptoms (cough, dyspnea, and pain), fatigue, physical functioning, and Health-Related Quality of Life (HRQoL) and significantly delayed time to deterioration of cough 73. Afatinib has shown activity in the treatment of patients with advanced lung adenocarcinoma with EGFR mutations, especially in patients with deletion 19 or L858R mutations 74. In a phase 2b/3 randomised trial (LUX-Lung 1), afatinib versus placebo for NSCLC patients was evaluated, suggesting that afatinib could be benefit for patients with advanced lung adenocarcinoma who have failed at least 12 weeks of previous EGFR TKI treatment 75. After these studies of afatinib that have shown high RR and PFS in EGFR mutation-positive lung adenocarcinoma, recently the LUX-Lung 3 study reported that afatinib was associated with prolongation of PFS when compared with standard doublet chemotherapy (cisplatin plus pemetrexed) in patients with advanced lung adenocarcinoma and EGFR mutations 76.

Rossi et al in their review supported also the hypothesis that gefitinib, erlotinib and afatinib are ideal drugs for NSCLC patients carrying EGFR mutations 77.

In addition, according to several phase II and III clinical trials, chemoradiotherapy (CRT) has only extended survival to 18 to 20 months 78-83. Other clinical trials have investigated the combination of gefitinib and erlotinib with radiation alone or chemoradiotherapy for stage III NSCLC reporting well tolerated and feasible results 84-86. Results of a phase II study, (cancer and leukemia group B (CALEB) 30106) showed that survival of poor-risk patients with wild type or mutated EGFR receiving sequential CRT with gefitinib was promising where-as survival for good-risk patients receiving concurrent CRT plus gefitinib was disappointing even for tumors with activating EGFR mutations 85. A prospective study showed that concur-rent EGFR-TKIs with individualized radiotherapy had a favorable safety profile and promising outcome 87. An Asian study also reported that the combination of first-line TKI therapy with early multi-target radiotherapy were very effective in selected patients that respond to TKI, when the EGFR mutation status are not known before the treatment 88. A more recently published study, compared the time-to-response between radiothera-py and EGFR-TKIs, concluding that EGFR-TKIs accomplished tumor shrinkage earlier than radiotherapy did in NSCLC patients with a sensitive EGFR mutation, suggesting that EGFR-TKIs might be useful for early symptom improvement in these patients 89.

Other new pharmaceutical agents that bind irreversibly to EGFR tyrosine kinase include neratinib (HKI-272) and dacomitinib (PF-00299804) which have been evaluated in phase II clinical trials 90 91. Sequist et al that studied neratinib to overcome T790M resistance mutation reported responses in G719X EGFR mutation, supporting the need of genetic information on trials of targeted agents 90. According to Ramalingam et al, dacomitinib demonstrated significantly improved PFS versus erlotinib, with acceptable toxicity 91.

Moreover, cetuximab (marketed as Erbitux®; Dako, Copenhagen, Denmark) is a 152 kDa chimeric monoclonal antibody of the immunoglobulin G1 subclass produced in mammalian cell culture by mouse myeloma cells 92. Cetuximab plus gemcitabine/platinum 93 or plus cisplatin/vinorelbine 94 has been evaluated in randomized phase II clinical trials as first-line therapy with promising results in unselected NSCLC patients.

However in a multicenter, open-label, phase III study of 676 chemotherapy-naïve NSCLC patients, paclitaxel or docetaxel and carboplatin, with or without cetuximab were evaluated as first-line treatment, resulting in no notable differences between them 95. Analysis of potential predictive markers of cetuximab benefit of this phase III trial reported that efficacy parameters did not appear to correlate with K-ras mutation status or any of the EGFR-related biomarkers evaluated 96. In contrast, Hirsch et al in their study were the first to suggest that EGFR gene copy number detected by fluorescent in situ hybridization (FISH) is a predictive factor for selection of NSCLC patients for cetuximab plus chemotherapy 97.

In another multinational, multicentre, open-label, phase III trial, (FLEX study) chemotherapy-naive patients (>or=18 years) with advanced EGFR-expressing histologically or cytologically proven stage wet IIIB or stage IV NSCLC were randomly assigned in a 1:1 ratio to chemotherapy plus cetuximab or just chemotherapy 98. The FLEX study reported that overall and median survival rates were also higher in the chemotherapy plus cetuximab group as compared to the chemotherapy alone group in patients with high EGFR expression 98.

Other studies have also favored cetuximab in NSCLC patients. In an open label phase II clinical trial in pretreated NSCLC patients, cetuximab was evaluated as monotherapy resulting in disease control rates and OS comparable to that of pemetrexed, docetaxel, and erlotinib in similar groups of patients 99. Lin et al in a meta-analysis of four trials enrolling 2018 previously untreated NSCLC patients, showed that the addition of cetuximab to chemotherapy improved OS and overall response rate (ORR) 100. Overall, as most studies have reported, cetuximab can offer a clinical benefit in NSCLC patients but warrants further investigation.

Recently, acquired resistance to TKIs has been reported to include mechanisms such as secondary mutation of the EGFR gene, amplification of the MET gene, and overexpression of hepatocyte growth factor (HGF) 66.

Met is the tyrosine kinase (TK) receptor of the HGF and has been associated with a worse prognosis in NSCLC, activating the ERBB3/PI3K/AKT and GRB2-associated binding protein 1(GAB1) signaling in EGFR-mutant lung cancers 101. According to Ma et al the Met/HGF pathway is functional and often mutated in SCLC and NSCLC (53).

MetMAb (Oartuzumab) is a monovalent monoclonal antibody (MoAb), a promising agent to overcome this resistance. A completed phase II study with results included the combination of MetMAb with erlotinib in patients with advanced and previously treated NSCLC patients improving PFS and OS in those patients whose tumors overexpressed Met by immunohistochemistry (IHC; 'Met high') 102. After these encouraging results, a similar phase III clinical trial has been launched since 2011 to evaluate the efficacy and safety of MetMab and is still recruiting patients.

Other ongoing randomized, phase II, multicenter, double-blind, placebo-controlled studies are investigating MetMab in combination with paclitaxel plus cisplatin/carboplatin (NCT00854308) and in combination with bevacizumab plus platinum plus paclitaxel/pemetrexed plus platinum as first-line treatment (NCT01496742), both in untreated non-squamous NSCLC patients (http://www.clinicaltrials.gov/ct2/results?term=MetMAb+NSCLC&Search=Search).

Tivantinib (ARQ 197), a selective, oral, non-ATP-competitive, small-molecule inhibitor of the MET receptor tyrosine kinase was evaluated in a phase 1 dose-escalation trial 103 or in combination with erlotinib 104 showing good tolerability and encouraging clinical activity. Recently, studies have been designed such as MARQUEE, a phase III trial to evaluate the combination of ARQ 197 plus erlotinib versus placebo plus erlotinib in treated nonsquamous, NSCLC previously patients 105 based on the available evidence that dual inhibition of MET and EGFR might overcome resistance to EGFR inhibitors.

Another emerging tool for the implementation of personalized medicine includes the K-ras gene mutation. The K-ras gene functions in the downstream domain of EGFR-induced cell signaling by encoding a 21-kDa G-protein with GTPase activity and has a mutation frequency of 3-35% in lung cancer 106, 107. In particular, K-ras mutations have been found in approximately 17% of all NSCLC, and are seen in 27%-34% of adenocarcinomas and non-squamous tumors, but are rarely seen in squamous cell carcinomas 108, 109. These mutations are located at codons 12 and 13 and rarely at codons 59 and 61 110. Moreover, a meta-analysis of studies in advanced NSCLC provided empirical evidence that K-ras mutations are highly specific negative predictors of response (de-novo resistance) to single-agent EGFR TKIs 111.

Other groups reported that the clinical usefulness of K-ras mutation as a selection marker either for EGFR-TKIs or cetuximab sensitivity in NSCLC is limited 112 113.

In a French prospective cohort (ERMETIC project--part 2) by Cadranel et al 114 in NSCLC patients treated by erlotinib, was reported that EGFR and K-ras status independently impact outcomes in advanced NSCLC patients treated with EGFR-TKI. However, EGFR status impacts both PFS and OS, whereas K-ras only impacts OS. These findings supported the nationwide use of EGFR status for patient selection before EGFR-TKI therapy. Although there are some studies in the literature investigating the EGFR and K-ras mutations in NSCLC tumor samples simultaneously 111, the role of K-ras mutations remains to be elucidated. Overall, all these data suggest the possible existence of two different molecular pathways one associated (K-ras mutation) and another not associated with smoking (EGFR mutation).

The PI3K/AKT/mTOR pathway is also being investigated via inhibited targeted agents in the setting of pathway-activating mutations and for their ability to restore sensitivity to upstream signaling targeted agents 115.

Drugs interfering with the mTOR pathway include rapamycin (sirolimus), and its derivatives cell cycle inhibitor (CCI)-779 (temsirolimus) and RAD001 (everolimus) 116 which have been investigated in phase I and II clinical trials. Although mTOR inhibitors such as everolimus in combination with EGFR inhibitors appear to be well tolerated, with some evidence suggesting antitumor activity 117, optimization of the therapeutic impact of mTOR inhibitors in NSCLC will be further defined when reliable predictive factors are identified. The most recent study conducted by Ramalingam et al 118 included a phase II trial of docetaxel in combination with everolimus for salvage therapy of NSCLC patients with relatively modest efficacy in this unselected population. Furthermore, since EGFR-TKIs therapy includes primary or acquired resistance, a preclinical study in NSCLC lines concluded that the use of everolimus might enhance the efficacy of gefitinib in EGFR-TKI-resistant patients 119. Besides another study indicated that transient blockade of PI3K/Akt pathway might overcome EGFR TKIs resistance and restore sensitivity to agents well tolerated, thereby providing clinical benefit in NSCLC patients 120. The PI3K/AKT/mTOR pathway includes Akt, one of the most frequently activated protein kinases in human cancer 115.

Overall, mTOR pathway currently can only be considered for second or third-line treatment 118, 121. More biomarkers and novel biological agents are required to be tested in clinical trials for mTOR pathway to play a crucial role in NSCLC therapy in the future 122.

The investigation for other genetic abnormalities has led to the identification of anaplastic lymphoma kinase (ALK) gene rearrangements which occurs independently of EGFR and KRAS gene mutations. This genetic change is consisted in a chromosome 2 inversion leading to a fusion with the echinoderm microtubule-associated protein like 4 (EML4) gene, which results in the abnormal expression and activation of this tyrosine kinase in the cytoplasm of cancer cells 123.

EML4-ALK (anaplastic lymphoma kinase) fusion which is a rare abnormality appeared in 4-5% of NSCLC patients 124 is most common in adenocarcinomas and never or light smokers 125, 126.

In pretreated NSCLC patients that carry the ALK-translocation, Met and ALK inhibitor crizotinib (PF- 02341066) appears to be a favorable treatment option, which significantly can improve activity, efficacy and symptoms control versus chemotherapy 127. Crizotinib showed good tolerability with rapid, durable responses in the first-in-man phase I study for patients with EML4-ALK fusion 128. In another phase 1-2 study crizotinib was well tolerated and highly active in patients with advanced ALK-rearranged NSCLC 129.

At present phase III clinical trials (NCT01639001) evaluate the efficacy and safety of crizotinib versus pemetrexed/cisplatin or pemetrexed/carboplatin in previously untreated East Asian patients with non-squamous carcinoma of the lung harboring a translocation or inversion event involving the ALK Gene Locus.

Based on these results and those from an ongoing phase II trial (NCT00932451), crizotinib has received accelerated approval in the USA 130. However, the evaluation of crizotinib in combination with other therapeutic modalities including ionizing radiation remains to be investigated, since resistance to crizotinib might also be a fact 123. Also, an interesting conclusion in vitro was reported recently in a study that crizotinib overcame hepatocyte growth factor-mediated resistance to gefitinib in EGFR-mutant non-small-cell lung cancer cells 131.

Another important signaling pathway in NSCLC includes type I insulin-like growth factor receptor (IGF-1R) 132 which is a heterotetrameric receptor (two extracellular 125-kDa α chains and two transmembrane 95-kDa β chains) that auto-phosphorylates after ligand binding and activates other downstream signaling pathways such as PI3K and MAPK 133. IGF-1R-targeted agents include monoclonal antibodies such as cixutumumab (IMC-A12), figitumumab (CP-751,871), AMG-479, AVE1642, BIIB022, dalotuzumab (MK-0646), and robatumumab (Sch717454), the ligand neutralizing antibody Medi-573, and the small molecule inhibitors BMS-754807, linsitinib (OSI-906), XL228, and AXL1717.

Since IGF-1R and EGFR appear to be similar receptors in their signaling mechanisms, there is a possibility that IGF-1R signaling might be involved in tumor resistance to EGFR-TKIs as suggested in several studies in vitro 134 135. Based on this possibility, several trials have been designed such as the combinations of erlotinib with cixutumumab 136 or figitumumab combined with carboplatin and paclitaxel 137, all reported very limited results. Given the unsatisfactory results further development of this combination in unselected patients is not recommended. However, the identification of elevated baseline free IGF-1 levels in patients with longer PFS than in those with lower levels in several studies 134, 136-139 might represent a potential biomarker for optimal patient preselection for IGF-1R inhibitors in the future.

Targeted agents versus docetaxel

Plenty of studies revealed the superiority of gefitinib versus platinum-based and docetaxel chemotherapies. However, some of the following studies were conducted in unselected patients, thus precluding a true analysis of the real efficacy of targeted therapy in EGFR patients. Some study groups have compared gefitinib to docetaxel as second-line therapy in pre-treated patients with at least one prior chemotherapy regimen (platinum- or taxane-based) for advanced/metastatic NSCLC 140. The majority of the studies concluded similar or superior efficacy for gefitinib compared with docetaxel, supporting gefitinib as an effective treatment in NSCLC 141-145. (Table 2.) Herein, we summarize, the high lightened studies that have reported results concerning the comparison between EGFR TKIs and docetaxel.

Table 2

Combination of targeted agents in NSCLC.

First author/Study	Primary Endpoint/objective	Place	n	Targeted agents	Inhibition of molecular pathways	PHASE	STAGE/PATIENTS	Comments
Herbst et al 2011(BeTa)	OS	USA	636	bevacizumab plus erlotinib vs erlotinib alone	EGFR + VEGFR	III	recurrent or refractory/pretreated 1st line treatment	not improved OS
Papadimitrakopoulou et al 2012	feasible dosages of combination therapy	Greece	94	erlotinib + everolimus as 2nd and 3rd line	EGFR + mTOR	I	refractory advanced/pretreated platinum-taxanes based CT	acceptable tolerability and disease control
Scagliotti et al 2012	OS	Italy	960	Sunitinib Plus Erlotinib	EGFR + VEGFR	III	Pretreated/ at least one platinum-based regimen	significantly longerPFS and greater ORR
Boutsikou et al 2013	OS	Greece	229	erlotinib and/or bevacizumab	EGFR + VEGFR	III	IIIb/IV non-squamous/ pretreated docetaxel-carboplatin	promising but not improved OS
Falchook et al 2013	Evaluation of this combination treatment for the first time	USA	34	erlotinib, cetuximab, and bevacizumab	EGFR + VEGFR	I	advanced/pretreated	well-tolerated, antitumor activity

In the largest phase III INTEREST trial, 1.466 pretreated patients with advanced NSCLC were randomly assigned to receive gefitinib or docetaxel 146. They suggested that gefitinib is a valid treatment for these pretreated patients. Two years later, other researchers from the same institute, prospectively analyzed available tumor biopsies of these NSCLC patients, to investigate the relationship between biomarkers and clinical outcomes 147. They suggested that gefitinib can provide similar OS to docetaxel in patients across a broad range of clinical subgroups and that EGFR biomarkers such as mutation status may additionally identify which patients are likely to gain greatest PFS and ORR benefit from gefitinib.

Another international randomised multicentre, open-label, phase III study (TITAN-NCT00556322) which was conducted at 77 sites in 24 countries assessed the efficacy and safety of erlotinib versus chemotherapy in second-line treatment of NSCLC patients (N=2590). Although no significant differences in efficacy were noted between patients treated with erlotinib and those treated with docetaxel or pemetrexed, the toxicity profiles of erlotinib and chemotherapy differed. Therefore, they concluded that second-line treatment decisions should take into account patient preference and specific toxicity risk profiles 32.

A cost-effectiveness analysis was conducted which concluded that costs and effectiveness in patients who received second-line erlotinib compared with those who received docetaxel were equal 148. They also suggested that the choice of whether to use erlotinib or docetaxel should be based on factors relating to patient preference. Besides, another study by Krawczyk et al (N=204) suggested that the qualification of docetaxel or erlotinib for second-line therapy should be based on clinical and molecular predictive factors 149.

Gefitinib and Erlotinib

Recently several studies have compared the efficacies of gefitinib and erlotinib as potent EGFR TKIs with antitumor activity in NSCLC patients 14. In a randomized, single-center, non-comparative phase II trial, by Kim et al the efficacy and safety of gefitinib and erlotinib was evaluated as second-line therapy for advanced NSCLC (N=96) with promising results for both of them 150. In a taiwanese retrospective multicenter study (N=1122) was reported that patients treated with erlotinib showed higher disease control rate, longer PFS, and OS compared with patients treated with gefitinib 151. Shao et al compared the efficacies of gefitinib and erlotinib as third-line therapy for advanced non-small-cell lung cancer inTaiwan (N=984) resulting in similar efficacies 152.

Recently completed trials involved erlotinib as monotherapy (BR.21 study) after the failure of first-line or second-line chemotherapy 21 or in combination with standard chemotherapeutic regimens such as carboplatin and paclitaxel 153 (TRIBUTE trials) for the treatment of NSCLC. TRIBUTE results concluded that never smokers treated with erlotinib and chemotherapy seemed to experience an improvement in survival.

Conversely, erlotinib has exhibited overall survival benefits when used as monotherapy (BR.21 study) 21.

EGFR TKIs gefitinib and erlotinib have also been studied versus other inhibitors and other chemotherapeutics regimens. Natale et al 154 in a two-part phase II study, compared the efficacy and safety of vandetanib a once-daily oral inhibitor of VEGFR, with that of gefitinib, (N = 168). The primary efficacy objective was achieved, with vandetanib demonstrating a significant prolongation of PFS versus gefitinib.

Furthermore, Hong et al 155 compared the efficacy and safety of pemetrexed, gefitinib, and erlotinib administration in previously treated patients with NSCLC. The superior PFS and OS of EGFR TKIs with more favorable baseline clinical characteristics than those of pemetrexed suggested the impact of baseline clinicopathological factors.

Moreover, some study groups investigated erlotinib as salvage treatment after failure of gefitinib with limited results, suggesting the need of the identification of molecular biomarkers in tumors to understand and overcome acquired resistance to gefitinib 156-159. (Table 1)

In a systematic review of 28 trials with a total of 6171 NSCLC patients and 30 treatments arms, they found that there was a significant relationship between Response Rate (RR) and Median Survival Time (MST) in these clinical trials with EFGR-TKIs by using a linear progression model 160. They suggested that RR could be an independent surrogate marker for MST in the current response criteria in the clinical trials of gefitinib and erlotinib. Overall, gefitinib and erlotinib appear to show a lot of similarities in NSCLC treatment and no superiority is obvious.

EGFR TKIs and elderly patients

Several efforts have been made towards the evaluation of the activity and toxicity profile of gefitinib in NSCLC patients aged 70 years or older. Since 2004, several studies reported that gefitinib is safe and well tolerated in elderly pretreated NSCLC patients 161 162 163.

Furthermore, in a phase II Simon et al reported that docetaxel (75 mg/m(2) every 3 weeks) combined with gefitinib (250 mg orally, daily) is active and well tolerated in elderly patients 164. However, in studies of Stinchcombe et al in a phase I/II trial of weekly docetaxel and gefitinib in these patients with stage IIIB/IV NSCLC, unexpected toxicity was observed 165, 166.

A phase II, open-label, parallel-group study compared gefitinib with vinorelbine in chemotherapy-naïve elderly patients with advanced NSCLC was conducted by Crinò et al 167. They reported no statistical difference between gefitinib and vinorelbine in efficacy in these patients, but there was better tolerability with gefitinib.

Finally studies to verify safety and efficacy of first-line treatment with gefitinib in elderly patients having advanced NSCLC with promising results were reported by Maemondo et al and Ebi et al 168, 169.

In addition, erlotinib was evaluated mostly in phase II clinical trials in vulnerable elderly NSCLC patients with feasible results 170 166, 171-173. In particular, the GFPC 0505 study a multicenter phase II randomized trial of gemcitabine followed by erlotinib at progression, versus the reverse sequence, in vulnerable elderly patients with advanced NSCLC selected with a comprehensive geriatric assessment (the GFPC 0505 study) was reported that both strategies were feasible but had modest efficacy 170. Moreover, Wheatley-Price et al 174 analyzed the influence of age on outcomes in National Cancer Institute of Canada Clinical Trials Group Study BR.21. They reported that elderly patients treated with erlotinib gain similar survival and QoL benefits as younger patients but experience greater toxicity.

Targeting vascular endothelial growth factor receptor (VEGFR)

Vascular endothelial growth factor (VEGF) family of proteins includes VEGF-A, B, C, D, and E, and placental growth factor 1 and 2 175. VEGF an endothelial cell-specific mitogen is the major regulator of angiogenesis in normal and malignant tissue 176, 177. The VEGF pathway includes; i) monoclonal antibodies against VEGF such as bevacizumab which has been approved for the treatment of metastatic nonsquamous NSCLC in combination with carboplatin and paclitaxel and has shown increased survival 178, ii) VEGF receptors such as aflibercept and pazopanib and iii) small molecule TKIs such as sunitinib and sorafenib that target the TK domain of VEGF receptor 179. (Table 1.)

Bevacizumab is a recombinant humanized monoclonal antibody (MoAb) that binds to and neutralizes human vascular endothelial growth factor (VEGF) 180. The first trial to establish the combination of bevacizumab and cytotoxic chemotherapy as a new standard of care for eligible NSCLC patients was ECOG 22 resulting in significant survival benefit with the risk of increased treatment-related deaths. Another study (JO19907) demonstrated that the addition of bevacizumab to first-line carboplatin-paclitaxel significantly improved PFS in Japa-nese patients with advanced non-squamous NSCLC 178. A Phase III trial (AVAil) of cisplatin plus gemcitabine with either placebo or bevacizumab as first-line therapy for nonsquamous NSCLC significantly improved PFS and ORR 181.

Recently, an open randomized clinical trial (WJOG 5910L) has been designed to evaluate whether the addition of bevacizumab to docetaxel alone (the standard second-line treatment for NSCLC) might improve PFS when administered as second-line treatment in NSCLC patients who have progressed after first-line treatment with bevacizumab plus a platinum based doublet 182.

Approvals for bevacizumab, were based upon the results of the two large phase III studies the North American Eastern Cooperative Oncology Group (ECOG) 4599 22 and the European AVAiL 21 concerning the improvement in RR and PFS. Overall, bevacizumab plus platinum-based chemotherapy offers clinical benefit for bevacizumab-eligible patients with advanced NSCLC. As a result to the exciting role of bevacizumab in NSCLC, other anti-angiogenic agents, including small molecule TKIs targeting the vascular endothelial growth factor receptor (VEGFR) have developed and are currently being explored.

The latest goal of the researchers is the evaluation of antiangiogenics in combination with radiotherapy. Data do not support the combination of bevacizumab and radiation 183. Aflibercept a recombinant human fusion protein targeting the VEGF is either well tolerated in phase II trials with platinum- and erlotinib-resistant lung adenocarcinoma 184 or disappointing results in phase III clinical trials 185 in nonsquamous NSCLC patients.

In a phase III trial that investigated OS for sunitinib, a VEGFR TKI plus erlotinib versus placebo plus erlotinib in patients with refractory NSCLC, concluded that the combination of sunitinib plus erlotinib was associated with a statistically significantly longer PFS and greater ORR 186. Another VEGFR TKI, sorafenib inhibits the Ras/Raf pathway, which is overactive in cancer patients with a K-ras mutation, showed relevant clinical activity in a phase II study 187. However, a Phase III, randomized, double-blind, placebo-controlled trial of gemcitabine/cisplatin alone or with sorafenib for the first-line treatment of advanced, nonsquamous NSCLC did not meet its primary end point of improved OS 188.

Furthermore, Motesanib is a selective oral inhibitor of VEGF receptors-1, 2, and 3, platelet-derived growth factor receptor (PDGFR) that showed encouraging results in a phase II trial 189 in combination with carboplatin/paclitaxel as frontline therapy in NSCLC which led to the development of the MONET1 study. However, this phase III trial failed to achieve its primary endpoint of OS when adding a VEGFR TKI to first-line chemotherapy 190.

Another VEGR inhibitor is pazopanib (GW786034; GlaxoSmithKline, Philadelphia) which has been evaluated as monotherapy in phase II trial with favorable results. Several clinical trials that are currently ongoing or recruiting or even completed, include pazopanib in combination with erlotinib (NCT01027598) or with vinorelbine (NCT01060514), in combination (NCT00871403) and in comparison to pemetrexed (NCT01313663) and data are keenly awaited. http://www.clinicaltrials.gov/ct2/results?term=Pazopanib+NSCLC&Search=Search

Additionally, Vandetanib (AstraZeneca, Macclesfield, UK, ZACTIMA™ ZD6474) is a once-daily oral anticancer drug, a dual inhibitor of vascular endothelial growth factor receptor (VEGFR) and epidermal growth factor receptor(EGFR) signaling 191, 192. Phase I 193 and Phase II studies have favored vandetanib in pre-treated NSCLC patients plus docetaxel (ZODIAC) 191, versus gefitinib154, as monotherapy 194 or as first line treatment alone or with paclitaxel and carboplatin 195. Recently, after these encouranging data, phase III have been initiated including vandetanib plus pemetrexed for the second-line treatment 196 resulting in acceptable safety profile. However, in other phase III trials vandetanib was evaluated versus erlotinib 197 or versus placebo (ZEPHYR) 198 in pretreated patients with disappointing results.

Overall, except for bevacizumab, the part of other agents targeting VEGFR that are under clinical development is still limited today since several issues such as predictive biomarkers of response to antiangiogenic therapy and mechanisms of resistance to these agents remain to be elucidated.

Maintenance treatment (MT) for NSCLC

The current practice of first-line therapy for advanced NSCLC is four to six cycles of platinum-based combination chemotherapy followed by treatment break in non-progressive status 199. Moreover, only approximately 60% of patients would experience disease control at 8 weeks 200 and the median OS observed in recent trials of platinum-based double-agent chemotherapy has been 10 to 13 months 201, 202. Therefore, researchers have tried to prolong disease control obtained with first-line chemotherapy by additional therapy, in an attempt to improve OS, with preserved QoL. This additional chemotherapy is called maintenance treatment which can be consisted of a drug included in the induction regimen (so-called “continuation” MT) or early introduction of another non-cross-resistant agent (“switch” or consolidation MT) 203. We performed an electronic clinical trial search through PubMed data base including the following studies that state clearly in their title the application of maintenance treatment in NSCLC patients. (Table 3.) Although until a few years ago, no MT studies have shown an OS benefit, recently several studies have revealed the clinical benefit of maintenance therapy 203, 204.

Table 3

Maintenance treatment in NSCLC, Disease Control Rate (DCR), Progression Free Survival PFS)

First author/Study	n	Place	Primary Endpoint	Phase	STAGE	MAINTENANCE TREATMENT	Patients
Pallis et al 2007	41	Greece	DCR	II	IIIB/IV	gefitinib as salvage treatment	Pretreated platinum- or taxane-based
Kelly et al 2008 (SWOG S0023)	243	USA	-	III	III	gefitinib or placebo	Pretreated concurrent chemoradiotherapy and docetaxel
Patel et al 2009	50	USA	PFS	II	IIIB/IV nonsquamous	pemetrexed and bevacizumab	Untreated 1st line pemetrexed, carboplatin, and bevacizumab
Zhang et al 2012 (INFORM; C-TONG 0804)	296	China	PFS	III	IIIb or IV	Gefitinib versus placebo	Pretreated 1st-line platinum-based doublet
Cappuzzo et al 2010 (SATURN; BO18192)	884	Italy	PFS	III	advanced	erlotinib	Pretreated 1st line/four cycles of platinum-based chemotherapy

Agents that have recently been licensed as maintenance therapy for advanced NSCLC by the US Food and Drug Administration include erlotinib and pemetrexed 205. However this new setting still remains controversial as there is no certainty that maintenance treatment is superior to second or third line therapy 206.

The first agent to be integrated into the treatment regimen was gefitinib, as a MT. Kelly et al in a phase III trial of maintenance gefitinib or placebo after concurrent chemoradiotherapy and docetaxel consolidation in inoperable stage III NSCLC (SWOG S0023, N=243) reported that gefitinib did not improve survival 207. However, the latest study included a multicentre, double-blind randomised phase 3 trial (INFORM; C-TONG 0804, N=296) reported by Zhang et al 208. They concluded that MT with gefitinib significantly prolonged PFS when compared with placebo in patients from East Asia with advanced NSCLC who achieved disease control after first-line chemotherapy.

Cappuzzo et al designed a phase III, placebo-controlled Sequential Tarceva in Unresectable NSCLC (SATURN; BO18192) study to assess the use of erlotinib as MT in patients with non-progressive disease following first-line platinum-doublet chemotherapy 209. They reported that MT with erlotinib is well tolerated and significantly prolongs PFS compared with placebo and it could be considered in NSCLC patients who do not progress after four cycles of chemotherapy.

Furthermore, recently, Zhang et al 204 evaluated the efficacy and safety of erlotinib as MT in patients with unresectable NSCLC by evidence-based methodology from six eligible studies including 4372 patients. They reported that erlotinib produced significant clinical benefits with acceptable toxicity as a maintenance strategy in these patients, particularly when sequentially administered with chemotherapy but further suggested the comparison of the efficacy of erlotinib used as MT with second-line treatment.

Finally, a phase II study of bevacizumab plus pemetrexed and carboplatin followed by maintenance bevacizumab in patients with advanced, nonsquamous NSCLC was well tolerated and displayed remarkable activity in these patients 26. Another phase II study of pemetrexed and carboplatin plus bevacizumab with maintenance pemetrexed and bevacizumab as first-line therapy concerning the same group of patients resulted in acceptable toxicity and relatively long survival 210.

After the 6 cycles of platinum chemotherapy, the patient may achieve no response and remain symptomatic or achieve response and become asymptomatic. In the first case, the big question concerns whether the subsequent therapy is “maintenance” or “early second-line therapy”, and in the second case it concerns whether “maintenance therapy” is always better than “watch and wait”. Overall, as the era of personalized therapy is emerging these decisions should be made on the underlying molecular profile of the individual patient. It is evident that combined treatments or not followed by MT of biological agents justify further investigation in NSCLC patients.

Future perspectives

All targeted agents mentioned in this review are directed toward key components in several signaling pathways. It is a fact that here is an increasing interest in using combinations of targeted agents to inhibit more than one pathway; for example, inhibition of VEGFR + EGFR 211. Indeed, when dual inhibition was compared with VEGF or EGFR blockade alone, resulted in the reduction of tumor endothelial proliferation 212.

A phase I clinical trial included dual EGFR inhibition in combination with anti-VEGF treatment in NSCLC patients 213. They concluded that the combination of erlotinib, cetuximab, and bevacizumab was well-tolerated and demonstrated antitumor activity in heavily pretreated NSCLC patients. Similarly, in another phase I study, it was demonstrated that combination therapy with ertotinib plus cetuximab was well tolerated 214.

Additionally, Boutsikou et al in a four-arm Phase III trial in patients with NSCLC reported the administration of bevacizumab and erlotinib in combination with first-line chemotherapy, followed by bevacizumab and erlotinib monotherapy as maintenance 215. They showed promising results, with reduced toxicity as compared with chemotherapy alone, but there was no longer OS. Moreover, in a double-blind, placebo-controlled, randomised phase III trial (BeTa), addition of bevacizumab to erlotinib did not improve survival in patients with recurrent or refractory NSCLC 216.

Recently, Biomarker-integrated Approaches of Targeted Therapy for Lung Cancer Elimination (BATTLE) trial included the first completed prospective, biopsy-mandated, biomarker-based, adaptively randomized study in 255 pretreated lung cancer patients receiving erlotinib, vandetanib, erlotinib plus bexarotene, or sorafenib 217. The targeted treatment in this trial was based on relevant molecular biomarkers analyzed in fresh core needle biopsy specimens. They reported an impressive benefit from sorafenib among mutant-Kras patients.

It is evident that in the near future, researchers will investigate the majority of the agents in combination with other therapies, either conventional chemotherapy or targeted therapy and even produce multiple pathway inhibitors such as XL 184 (Cabozantinib). XL 184 is a multiple TKIs agent for MET and VEGFR2 which is currently being investigated in several clinical trials either alone or in combination with other agents such as erlotinib (http://www.clinicaltrials.gov/ct2/results?term=XL+184+NSCLC&Search=Search).

Apart from identifying the most appropriate combinations in selected NSCLC patient subgroups, the definition of the optimal treatment doses is also crucial for the achievement of the best therapeutic index and perhaps not the performance of large trials in unselected patients. Besides it is also important even in negative trials to identify biomarkers of response although to avoid negative results, researchers need to produce more preclinical and early clinical data before large clinical trials are initiated.

Available targeted therapy should be given to patients presenting the target. To date, EGFR TKIs, bevacizumab and ALK inhibitors include the most successful targeted agents in NSCLC. Besides, a few biological agents have shown better response in certain histologic subtypes of NSCLC leading to the involvement of histology to guide therapy.

At this point, several novel therapeutic targets are currently being investigated in laboratories and in clinical trials. Furthermore, in order to accelerate the identification of individualized targets, the accomplishment of cheap next-generation sequencing technologies for adequate parts of the genome is at large.

In conclusion, a step towards the realization of personalized therapy has been accomplished in NSCLC, concerning the identification of molecular biomarkers. Thus, the therapeutic goal concerns as much possible molecular information for every patient. However, the physician should primarily take into account patient's profile and individual characteristics and of course patient's response to therapy given the multiple subsets of NSCLC each with its own molecular abnormalities.