Systemic Therapy for Oligoprogression in Patients with Metastatic NSCLC Harboring Activating EGFR Mutations

Simple Summary The oligoprogression concept is characterized by a limited number and/or sites of metastases in which a disease progression appears, and a more indolent tumor biology, raised specifically for oncogene addicted non-small cell lung cancer (NSCLC), including the epidermal growth factor receptor (EGFR)-mutant group. The optimal approach to the diagnosis and management of this disease state is not yet established. In fact, significant gaps still exist in our understanding of patient selection, type of progression, mechanisms responsible of intrinsic and acquired resistance, optimal systemic therapy, and the tumor microenvironment. Some therapeutic approaches are investigated and discussed in this review. Well-designed prospective clinical trials need to facilitate the development of therapeutic strategies beyond progression after first-line EGFR-inhibitor treatment failure. Abstract After a variable period of activity of the epidermal growth factor receptor tyrosine kinase inhibitor (EGFR-TKI) treatment, patients with advanced non-small cell lung cancer (NSCLC) harboring EGFR mutations develop resistance to these TKIs. In some cases, an oligoprogression is diagnosed, and its management is still controversial. The oligoprogression represents an intermediate stage of metastatic NSCLC between localized and widely disseminated disease, and is characterized by a limited number and/or sites of metastases in which a disease progression appears, together with a more indolent tumor biology. Currently, the management of oligoprogressed NSCLC involves local treatment, including radiotherapy and/or surgery, to control the progressive lesions. Systemic therapy should also be a potential approach to boost the activity of EGFR-TKIs. However, considering the lack of large trials addressing this topic, the optimal therapeutic strategies remain undefined and should be evaluated on an individualized basis. In this paper, we review the most relevant scientific evidence of continuing the systemic therapy with the same EGFR-TKI for the management of patients with NSCLC harboring EGFR mutations and oligoprogressed to first-line EGFR-TKIs, also discussing the controversies and potential future directions.


Introduction
The management of advanced stage non-small cell lung cancer (NSCLC) has been revolutionized by the advent of targetable biomarkers. Among these, predictive biomarkers, such as the epidermal growth factor receptor (EGFR) mutations, the anaplastic lymphoma kinase (ALK) and proto-oncogene tyrosine-protein kinase 1 (ROS1) rearrangements, B-RAF proto-oncogene serine/threonine kinase (BRAF) V600E mutations, are included. The oncogeneaddicted group, representing around 25-30% of metastatic NSCLC patients of prevalently non-squamous histology, can be treated with the corresponding oral small molecules tyrosine kinase inhibitors (TKIs) [1,2]. However, after an initial activity of first-line TKIs treatment, lasting around 10-14 months, a disease progression was reported in the majority of patients with the mechanisms of resistance that may vary. From a clinical point of view, in this subgroup, we can identify at least three distinct patterns of progression: isolated central nervous system progression, oligoprogression, and widespread systemic progression [3].
Approximately 20-30% of NSCLC patients with EGFR mutations who received EGFR-TKIs were non-responsive or responded only for a short time due to intrinsic resistance to EGFR-TKIs. In most cases, the progression is due to the onset of acquired resistance to the corresponding TKIs with new genetic alterations arising in the EGFR pathway or other cross-talk pathways, and for which new corresponding inhibitors are already available in early-and late-stage clinical trials [4].
In this article, we review the most relevant scientific evidence of continuing the systemic therapy with the same EGFR-TKI, with or without other agents, for the management of patients with NSCLC harboring EGFR mutations and oligoprogressed to first-line EGFR-TKIs, also discussing the controversies and potential future directions.

Oligoprogressive Disease
The oligoprogression represents an intermediate stage of metastatic NSCLC between localized and widely disseminated disease, and is a relatively new concept that emerged when more effective systemic therapies became available. The consensus definition of oligoprogression is that it is characterized by both a limited number and/or sites of metastases, in which a disease progression appears, typically limited to patients with up to 5 progressive lesions, and a more indolent tumor biology [5]. Several concomitant parameters can modulate the anatomical pattern of treatment failure, such as the molecular evolution of cancer cells and changes in the tumor microenvironment. Oligoprogression is common in oncogene-addicted NSCLC treated with TKIs and developing an acquired resistance representing a model disease for the study of this condition. An appropriate management of oligoprogression has resulted in a median time-to-next-treatment gain and substantial overall survival (OS) improvement [5].
Moreover, this clinical evaluation has been partially incorporated in the new TNM classification. In fact, classically, all metastatic NSCLC patients have been grouped in a unique category under the M descriptor (stage IV). In the eighth TNM classification of lung cancer, the M descriptor has been subdivided into three categories: M1a, grouping cases with separate tumor nodule(s) in a contralateral lung lobe, pleural nodules or malignant pleural or pericardial effusion; M1b, grouping cases with single extrathoracic metastasis or involvement of a single distant (non-regional) node; and M1c, including cases with multiple extrathoracic metastases in one or several organs [6]. Considering that about 70% of all new NSCLC diagnosis have advanced disease, it is striking that they may be classified by only three categories according to prognosis. However, this can be considered as the first step to providing a definition for an oligometastatic disease stage in NSCLC to be considered also for defining the oligoprogression.
The hypothesis that the resistant clone progresses clinically, but the non-progressing clone may still be sensitive to TKIs, has led to use a local therapy of progressing lesions to eradicate the resistant clones and allow for the continuation of TKI to control the sensitive clones. Overall, the management of oligoprogression is controversial due to the limited clinical data, and involves mainly radical local treatment, such as radiotherapy or surgery, to achieve disease control.
In many cases, in the presence of a progression, including the oligoprogression, the current line of systemic treatment is discontinued, and a switch to a salvage line of systemic therapy is considered. The alternative strategy for oligoprogression is to continue the systemic treatment beyond progression. The choice varies depending on a number of patient factors, the NSCLC characteristics, and the number of subsequent lines of systemic treatments available. In NSCLC patients with EGFR mutations, a rebound tumor flare, characterized by a sudden marked increase in tumor growth, with the worsening of disease-related symptoms, and increased radiological activity on positron emission tomography/computed tomography (PET-CT) scan, which can occur with the interruption of TKI in about 20% of the patients, may play a role in this choice [7]. Different strategies have been pursued for continuing first-line EGFR-TKIs in patients with EGFR mutated NSCLC after the development of disease oligoprogression, such as continuation on EGFR-TKI alone or with chemotherapy, or with another targeted agent.

Continuing EGFR-TKI Alone
In patients experiencing an oligoprogression after a durable response to EGFR-TKI, the strategy to maintain the inhibition of EGFR inhibitor-sensitive clones, to avoid the potential subsequent rebound tumor flare and symptomatic progression, is frequently used in clinical practice. This goal can be reached through the continuation beyond the oligoprogression of the same EGFR-TKI, in order to continue the control of the disease, including the sites of progression. This approach was evaluated mainly in retrospective analyses (Table 1). NSCLC Japanese patients harboring activating EGFR mutations and radiologically progressed on EGFR-TKI treatment as the first-or second-line setting, were classified into two groups: 39 patients received continuous EGFR-TKI and 25 patients switched to chemotherapy. The median OS was 32.2 months in the patients continuing EGFR-TKI, and 23.0 months in those switching to cytotoxic chemotherapy. In the patients receiving first-line EGFR-TKI treatment, 18 in the continuous group and 9 in the switching group, the median progression-free survival (PFS) was 14.4 and 12.4 months, respectively [8].
Another Japanese retrospective analysis included 134 NSCLC patients harboring EGFR mutations and received gefitinib as first-or second-line treatment. The median duration of continued gefitinib therapy beyond progression was 3.2 months with a median OS of 14.3 months [9].
In a further analysis, despite RECIST defined progression, 49 patients out of 56 who continued on gefitinib or erlotinib beyond progression, the median duration of treatment was 10.1 months. The median time-to-progression (TTP) was 10.8 months in the 49 patients who continued TKI versus 9.2 months in 7 patients who discontinued TKI at progression. However, 15 out of 49 (31%) patients who continued TKI received additional systemic anticancer therapeutic agents while on TKI and mainly chemotherapy-based treatments [10].
Interestingly, in these analyses, patients who discontinued TKI at progression and receiving chemotherapy, were significantly younger compared to those who continued TKI beyond progression. The reason might be the feeling of investigators who preferred to change therapy in younger patients avoiding the risk of a further burden progression of disease with a worsening of general conditions that should preclude any other therapies.
A prospective phase II study, the ASPIRATION trial, investigated the efficacy of firstline erlotinib therapy in patients with NSCLC with activating EGFR mutations and postprogression erlotinib therapy. A total of 207 patients were enrolled, with 171 progressive disease events diagnosed while on erlotinib. Of these patients, clinicians chose to continue erlotinib in 93 (54%) patients beyond progression. The primary endpoint was PFS1, while for patients who were allowed to continue erlotinib therapy post-progression until the investigator's decision, PFS2 was also evaluated. Moreover, an important outcome relevant to clinical practice was the extension of PFS with treatment beyond progression (the difference between PFS1 and PFS2, which was conducted as a post hoc analysis). The median PFS1 was 10.8 months for the 207 patients, while the median PFS2 was 14.1 months for the 93 patients who continued erlotinib therapy following progression. Post hoc exploratory analyses showed that the median PFS1 of the 93 patients who had treatment beyond PD was 11.0 months, with a difference between PFS1 and PFS2 of 3.1 months [11].

Continuing EGFR-TKI Plus Chemotherapy
The addition of cytotoxic chemotherapy to the continuation of EGFR-TKI may be a more effective antitumor treatment strategy to overcome molecular mechanisms of acquired resistance for selected patients.
A retrospective study analyzed 78 EGFR mutant NSCLC patients who developed an acquired drug resistance, according to the Jackman criteria [12]. These patients were treated at progression with either continuing erlotinib plus chemotherapy or chemotherapy alone. In the group treated with erlotinib plus chemotherapy, the objective response rate (ORR) was 41% versus 18% reported by the chemotherapy group. Although no significant survival improvement was observed, these data suggest better clinical activity with the addition of chemotherapy to continuing erlotinib [13].
The prospective IMPRESS trial addressing this question showed that the continuation of gefitinib with platinum-based chemotherapy versus chemotherapy alone, after radiological disease progression on first-line gefitinib, did not prolong PFS in patients. In fact, 265 patients were randomized to receive cisplatin/pemetrexed regimen plus gefitinib or placebo. The median PFS was 5.4 months in both groups. No differences between the treatment groups for the other outcomes were reported, including the quality of life [14].
In the IMPRESS trial, the T790M status tested on plasma circulating free tumor-derived DNA using a quantitative emulsion (BEAMing) digital PCR assay (Sysmex), conducted at a central laboratory (positivity defined as 0.02% mutant DNA fraction), was available for 247 (93.2%) patients. The median PFS for the T790M mutation-positive subgroup was 4.6 versus 5.3 months for the gefitinib plus chemotherapy and placebo plus chemotherapy groups, respectively. The median PFS for the T790M mutation-negative subgroup was 6.7 versus 5.4 months, respectively [15]. These interesting results firstly suggest that, following acquired resistance to first-line gefitinib, there appear to be two distinct patient populations defined by the T790M genotype, regarding first-line first-and second-generation EGFR-TKIs. For plasma T790M-positive patients, gefitinib should not be continued, while, for plasma T790M-negative patients, the continuation of gefitinib in combination with platinum-based doublet chemotherapy may potentially offer some clinical benefits ( Table 2). A deeper knowledge of the mechanisms of resistance to EGFR-TKIs therapy and the development of osimertinib, third-generation EGFR-TKI, led to the definition of the strategic approach for T790M-positive patients [16]. For other mechanisms of resistance, for which no specific therapeutic strategy is available, the combination of chemotherapy plus continuing first-line EGFR-TKI might be a potential strategic approach, but this requires further confirmation in a prospective randomized placebo-controlled study.

Continuing EGFR-TKI Plus Other Targeted Agents
The continuing improvements in the knowledge of the acquired EGFR-independent mechanisms of resistance to EGFR-TKIs, including oncogenic gene fusions, gene amplification, mutations affecting gene encoding for cell-cycle proteins, the activation of the epithelial-to-mesenchymal transition (EMT), as well as the NSCLC to SCLC histologic transformation, led to the investigation of the combination of additional targeted agents against identified secondary resistance to the previous EGFR-TKI, to bypass pathways or genetic aberrations [17]. The FLOWER observational multicenter study, performed on patients with EGFR-mutant advanced NSCLC receiving first-line osimertinib, investigated the type and pattern of disease progression with osimertinib. In this study, progressive disease (PD) was reported in 34.9% of patients (n = 44/126), of whom 18.2% (n = 8/44) had isolated PD, considered as the appearance or growth of 1 lesion; 20.5% (n = 9/44) had oligoprogression, considered as the onset of ≤3 lesions in 2 organs; and 54.5% (n = 24/44) had systemic progression, evaluated as the appearance or progression in >3 lesions, and in 6.8% (n = 3/44) of the cases an unknown type of progression was reported. The most frequent PD sites were the lung, bone and brain [18].
Combination regimens investigated EGFR-TKIs with other targeted agents reporting, in some cases, disappointing results [7], but also the interesting strategies and data that are discussed here.
The mesenchymal-epithelial transition receptor (MET) gene amplification is detected in approximately 5-22% of NSCLC patients who progress on first-line treatment EGFR-TKIs, and is associated with poor prognosis. It leads to the EGFR-independent phosphorylation of the ErbB3 receptor, resulting in the subsequent bypass activation of the PI3K/Akt/mTOR pathway. MET gene amplification is the most common cause of bypass pathway activation involved in acquired resistance to EGFR-TKIs [19,20]. Preclinical results show the efficacy of combined MET-EGFR inhibition in overcoming resistance to EGFR-TKIs. This is a potential treatment strategy for EGFR-mutant advanced/metastatic NSCLC patients who progress to EGFR-TKI treatment due to the acquisition of MET aberrations [21]. Most trials evaluated the combination of an EGFR-TKI, which was not always used in the previous treatment, plus a MET inhibitor, savolitinib, capmatinib or tepotinib. Considering that it was not possible to extrapolate the data concerning the continuation of the first-line EGFR-TKI with the addition of the MET inhibitor, these studies are beyond the scope of this review [22][23][24][25][26][27][28].
The phase II ongoing ORCHARD open label, multicenter, biomarker-directed, platform study is evaluating the resistance mechanisms of first-line osimertinib identifying optimal post-progression therapies. The interim analysis reported the preliminary results concerning the administration of osimertinib plus savolitinib in EGFR-mutant NSCLC and MET amplification. The investigators reported an ORR, the primary endpoint in the first 17 evaluable patients, of 41%. Grade ≥ 3 adverse events, most commonly pneumonia and a decreased neutrophil count, and serious adverse events were reported in 30% each. A total of 3 patients (15%) discontinued combination treatment due to adverse events (Table 3) [29]. A further exploration of this combination is underway in the SAVANNAH phase II study. Eligible patients will have histologically/cytologically confirmed EGFR-mutant NSCLC, and MET amplification disease by central fluorescence in situ hybridization (FISH), central immunohistochemistry (IHC), or local next generation sequencing (NGS-retrospectively confirmed by central FISH/IHC). The primary objective is ORR [30]. The combination of osimertinib plus tepotinib, an oral, highly selective, potent MET tyrosine kinase inhibitor, is being assessed in the ongoing INSIGHT2 international, open-label, multicenter phase II trial in patients with advanced/metastatic EGFR-mutant NSCLC and acquired resistance to first-line osimertinib, and MET amplification determined centrally by FISH (gene copy number ≥ 5 and/or MET/CEP7 ≥ 2) at the time of progression. The primary end point is ORR [31].

Central Nervous System Oligoprogression
Central nervous system (CNS) progression was estimated to be the first site of recurrence in about 33% of cases, independent of disease control elsewhere, in EGFR-mutated NSCLC patients who respond to EGFR-TKI therapy. Studies have demonstrated lower cerebrospinal fluid (CSF) concentrations of EGFR-TKIs compared to plasma concentrations, leading to consider the inadequate penetration of EGFR-TKI into the CSF, as one of the potential resistance mechanisms responsible for CNS disease progression [32,33].
In the presence of CNS metastases, the treatment decisions depend on the degree of progression both intracranially and extracranially, and on the systemic treatment options remaining for the patient. Symptomatic CNS metastases require corticosteroid treatment and a referral to radiation oncology and/or neurosurgery, regardless of the presence of a driver alteration. In asymptomatic CNS progression in oncogene-driven NSCLC, in the context of widespread progression, a change of systemic therapy should be considered and, in particular, the availability of another targeted agent with CNS activity should be prioritized. In patients with CNS oligoprogression alone, either the continuation of the current targeted therapy plus local brain treatment, or another targeted agent with proven CNS activity to withhold local brain therapy, and switching to another targeted agent, with careful brain surveillance, could also be considered [34].
In this context, the third-generation EGFR-TKIs, osimertinib and almonertinib, showed remarkable activity against brain metastases. The AURA3 trial randomized EGFR-mutant NSCLC patients who progressed to first-generation EGFR-TKIs, due to the acquired EGFR-T790M mutation, to receive osimertinib or platinum-pemetrexed chemotherapy. In the subgroup of patients with CNS metastases, osimertinib improved the median CNS PFS with respect to the chemotherapy group (11.7 vs. 5.6 months, respectively). These results were reported regardless of prior brain radiotherapy [35]. Similarly, the FLAURA study, comparing first-line osimertinib versus first-generation EGFR-TKIs, gefitinib or erlotinib, confirmed that osimertinib reduced the risk of CNS progression (20% vs. 39%, respectively), as well as the onset of new brain metastases (12% vs. 30%, respectively). These further data highlight the protective role of osimertinib in the control of CNS lesions [36].
Almonertinib is a novel orally available, pyrimidine-based, third-generation EGFR-TKI with high selectivity and potent inhibitory activity against both EGFR-sensitizing and EGFR-T790M mutations. In the APOLLO study, patients who developed an EGFR-T790M mutation after progression to first-or second-generation EGFR-TKIs, received almonertinib. The median PFS in patients with CNS lesions was 10.8 months with a CNS ORR of 60.9% [37]. Almonertinib is being investigated as first-line therapy for EGFR-mutant NSCLC patients with CNS metastases, in the phase II ACHIEVE trial (NCT04808752).

Discussion
The disease progression with EGFR-TKIs shows distinct patterns of growth: isolated central nervous system progression, oligoprogression or widespread systemic progression [3], upon which the therapeutic decisions should be taken. Oligoprogression is considered in a situation in which an EGFR-mutant advanced NSCLC patient develops disease progression in one or a limited number of sites after an EGFR-TKI period of stable disease or an ORR. The consensus definition of oligoprogression describes up to 5 progressive lesions and can be estimated with a frequency ranging from 15% to 47% during EGFR-TKI treatment. Oligoprogression is related to tumor heterogeneity, and the development of an isolated resistant subclone at only 1 or few metastatic site(s) [5,34].
A common approach for treating oligoprogression in EGFR-mutant advanced NSCLC patients is to continue the EGFR-TKI that is controlling the greater proportion of the disease, while using local ablative therapy to eradicate the resistant clones in the area or areas of progression. This therapeutic approach is supported by several, mainly retrospective, case series [34].
In this article, we reviewed the available data for continuing first-line EGFR-TKI in patients with EGFR-mutant NSCLC after the development of disease progression. The retrospective and prospective data show that continuing first-line EGFR-TKI over progression alone, or in combination with other systemic treatment, such as chemotherapy or other targeted agents, seems useful at least in a well-defined population. In those for which the progression is driven by the onset of a new molecular alteration, the combination of continuing first-line EGFR-TKI and the addition of the specific inhibitor is under investigation, in particular, the combination of osimertinib and MET inhibitor. The population who may gain a greater benefit from the continuation of first-line EGFR-TKI plus chemotherapy is represented by the patients in which a specific molecular alteration responsible for the progression is not targetable or is not found. All these considerations are relevant, providing that the patient has progressed without a bulky disease and with a good general clinical condition without severe symptoms. In this regard, we have to also consider that by stopping the EGFR-TKI treatment due to the progression of the disease, there is a risk of a rebound tumor flare, which can occur in about 20% of the patients, and may play a role in treatment choice.
A limitation of the results available is that the studies do not report the burden of disease progression, with no specification if the patients enrolled are oligo or widespread progressors. However, both these studies showed a delay in switching to a salvage line of systemic therapy and avoiding the potential risk of flares.
A portion of EGFR-mutant NSCLC patients, treated with the third-generation of EGFR-TKIs, progresses due to the onset, as an acquired mechanism of resistance, of a tertiary EGFR-C797S mutation. A novel class of allosteric fourth generation EGFR-TKIs is in an advanced stage of development, with the intent to overcome acquired resistance to third-generation EGFR-TKIs. These drugs targeting the allosteric site of the EGFR receptor which, being situated away from the ATP binding site commonly targeted by the other EGFR-TKIs, is not affected by the EGFR-T790M and EGFR-C797S mutations [38,39].
Among the fourth generation EGFR-TKIs, EAI045 is the first allosteric EGFR inhibitor designed to target drug resistant EGFR-T790M and EGFR-C797S mutants [40]. JBJ-04-125-02 is another allosteric EGFR-TKI appearing to be more potent than EAI045 [41]. Preclinical in vitro and in vivo data are very interesting and promising for their investigation in early-stage clinical development. However, both EAI045 and JBJ-04-125-02 cannot overcome the resistance mediated by the Ex19del/T790M/C797S triple mutant. On the other hand, CH7233163, TQB3804 and BBT-176 are novel fourth-generation EGFR-TKIs, which are capable of overcoming the resistance mediated by the Ex19del/T790M/C797S and L858R/T790M/C797S triple mutation. BLU-945, another fourth-generation EGFR-TKI, achieved in vitro robust inhibition of Ex19del/T790M/C797S and L858R/T790M/C797S triple mutation, rather than the EGFR wild-type, as well [42]. This continuing increase in knowledge of the genomic profiling of patient tissue at greater speeds and at lower costs allowed for the development of NGS platforms and targeted gene panels. The therapeutic strategy to use for EGFR-mutant advanced NSCLC patients progressed to first-line EGFR-TKI may use NGS analysis to detect early signals of drug resistance, to potentially direct the switching to an alternative antitumor drug or combination to overcome relevant subclonal progression. In this context and considering that in lung cancer the tumor is often difficult to reach and may need an invasive and potentially harmful procedure, the continuing development of the analyses of liquid biopsies can noninvasively detect any targetable genomic alteration and guide corresponding targeted therapy. Moreover, liquid biopsy might help in monitoring the response to treatment and exploring the genetic changes at resistance, overcoming spatial and temporal heterogeneity [43,44].

Conclusions
The understanding and treatment of metastatic NSCLC has seen significant advances within the last few years. Oncogene-addicted NSCLC includes several subgroups of patients who can greatly benefit from specific inhibitors. The continuous research and development of new generation inhibitors is changing this scenario. However, significant gaps still exist in our understanding of patient selection, type of progression, mechanisms responsible of intrinsic and acquired resistance, optimal systemic therapy, and the tumor microenvironment.
Oligoprogression is a recently acknowledged pattern of disease progression on systemic anti-cancer therapy raised specifically for oncogene addicted NSCLC, including the EGFR-mutant group. The optimal approach to the diagnosis and management of this disease state has not yet been established. The pattern of progression and time to EGFR-TKI response are relevant factors to be taken into account at the time of progression, in order to select the patients who are candidates for a therapeutic switch or rechallenge. Some approaches were investigated and discussed in this review, and can be summarized by Figure 1. However, the validation of these results is required with well-designed prospective clinical trials to facilitate the development of therapeutic strategies beyond progression after first-line EGFR-TKI treatment failure.