Ignite Creation Date:
2025-12-25 @ 1:28 AM
Ignite Modification Date:
2025-12-27 @ 10:49 PM
Study NCT ID:
NCT06933394
Status:
RECRUITING
Last Update Posted:
2025-04-18
First Post:
2025-02-07
Is NOT Gene Therapy:
True
Has Adverse Events:
False
Brief Title:
Arsenic Trioxide With MAPK Inhibitors and Chemotherapy for Stage 4/M Neuroblastoma
Sponsor:
Sun Yat-Sen Memorial Hospital of Sun Yat-Sen University
Organization:
Study Overview
Official Title:
A Prospective, Single-arm, Multicentre Phase II Clinical Study of Arsenic Trioxide in Combination With Chemotherapy and MAPK Pathway Inhibitors for Stage 4/M Neuroblastoma
Status:
RECRUITING
Status Verified Date:
2025-04
Last Known Status:
None
Delayed Posting:
No
If Stopped, Why?:
Not Stopped
Has Expanded Access:
False
If Expanded Access, NCT#:
N/A
Has Expanded Access, NCT# Status:
N/A
Acronym:
None
Brief Summary:
This prospective, single-arm, multi-center clinical trial aims to explore and evaluate the efficacy and safety of the combination therapy involving arsenic trioxide, MAPK inhibitors, and chemotherapy for stage 4/M neuroblastoma.
Detailed Description:
Neuroblastoma (NB) is the most common extracranial solid tumor in children. Since 2018, we have led a prospective, nationwide multicenter collaborative clinical study on arsenic trioxide(ATO) combined with chemotherapy for 4/M stage NB (NCT03503864).The results indicate that the objective response rate (ORR) and complete remission rate (CRR) at the end of induction (EOI) for the ATO-combined chemotherapy regimen are significantly higher than those of the commonly used NB regimens in China, as well as the internationally recognized rCOJEC and MSKCC-N5 regimens. Additionally, the ATO regimen demonstrates a lower incidence of toxic side effects, providing favorable conditions for subsequent consolidation therapy and contributing to the long-term survival of High-risk neuroblastoma(HR-NB) patients. However, in clinical practice, we found that some children responded poorly to ATO combined induction chemotherapy, with lesions persisting or progressing and recurring, gradually developing into refractory cases during induction chemotherapy. Studies show that primary/acquired resistance in NB is related to the high-frequency clonal diversity that gradually emerges with chemotherapy.
With the advancement of precision medicine technology and in-depth research on signaling pathways, we found the RAS-MAPK signaling pathway plays an important role in the regulation of cell proliferation and differentiation, and this pathway is abnormally activated in various tumors. Literature reports that 78% of refractory/recurrent NB have activating mutations in the RAS-MAPK pathway, suggesting a close association between this pathway and refractory/recurrent NB. In addition, in some tumor cell lines, ATO can cause upregulation of the MAPK pathway, which may be the reason for the poor efficacy of ATO in some HR-NB children and suggests the necessity of combining MAPK inhibitors in ATO-containing induction chemotherapy regimens. Studies have shown that in APL cell line NB4 and APL primary cells, MAPK (MEK) inhibitors (PD98059 and PD184352) enhance apoptosis in ATO-treated cells by inhibiting downstream ERK1/2 and Bad phosphorylation, indicating that combining ATO with MAPK inhibitors can further improve efficacy.
Clinical studies show that single-agent MAPK inhibitors often have poor efficacy in the treatment of advanced or refractory tumors. Studies have found that in ALK-dependent RAS-MAPK mutant NB cell lines, MAPK inhibitors can activate the pro-cancer PI3K-AKT pathway through the mTORC2 complex-related subunit SIN1, and thus the MAPK inhibitor trametinib cannot inhibit the growth of ALK-dependent NB in mouse models. Previous studies have found that ATO can downregulate the PI3K-AKT pathway in various tumors, and we have found through non-label quantitative proteomics technology that ATO treatment of NB cell line SK-N-BE(2) can also cause downregulation of this pathway, and studies have shown that ATO can inhibit the activity of the mTORC2 complex in this pathway. In summary, we propose combining ATO with MAPK inhibitors, with the aim of using MAPK inhibitors to counteract the adverse effects of ATO activating the MAPK pathway, while ATO inhibits the activation of the PI3K-AKT pathway caused by MAPK inhibitors, thereby jointly inhibiting tumor growth.
As chemotherapy progresses, tumor cells gradually accumulate DNA damage under chemotherapy pressure, leading to a higher probability of gene mutations and clonal evolution associated with poor prognosis, increasing the likelihood of drug resistance; studies show that primary/acquired resistance in NB is also related to the high-frequency clonal diversity that gradually emerges with chemotherapy; under the selective pressure of chemotherapeutic drugs, cells with drug-resistant characteristics gradually expand and enrich, and gradually dominate; the later the remission time during induction chemotherapy in NB patients, the worse the prognosis; studies show that patients with initial bone marrow minimal residual disease(MRD) positivity who remain positive after 4 courses of chemotherapy have a significantly higher recurrence rate than those who become negative (74.1% vs. 33.3%), and the event-free survival has statistical significance; and radical surgery performed after the 3rd or 4th course of induction chemotherapy according to consensus and mainstream cooperative group regimens may also be one of the potential risk factors promoting the dissemination and metastasis of NB tumor cells; therefore, we chose to add trametinib to the medication sequence starting from the 5th course of induction chemotherapy, for a total of 5 courses of combined medication (the 5th to 9th courses of induction chemotherapy). The effectiveness and safety of the above combined medication strategy need to be further verified through multicenter collaborative clinical studies, and we expect that this combined medication regimen can improve the treatment status and prognosis of HR-NB, a refractory tumor.
Based on the above theoretical basis, the combination of MAPK pathway inhibitors with ATO has a synergistic effect, and we expect that the new regimen of adding the MAPK pathway inhibitor trametinib to the original ATO combined chemotherapy regimen can improve CRR. Therefore, this study aims to use the CRR at EOI of ATO combined chemotherapy and MAPK signaling pathway inhibitor(for example. trametinib) in the treatment of 4/M stage NB as the main research objective. The overall CRR at EOI for 4/M stage NB, both domestically and internationally, will serve as an external control to assess the clinical efficacy and safety of ATO-combined chemotherapy plus the MAPK signaling pathway inhibitor during the induction chemotherapy phase of 4/M stage NB.
With the advancement of precision medicine technology and in-depth research on signaling pathways, we found the RAS-MAPK signaling pathway plays an important role in the regulation of cell proliferation and differentiation, and this pathway is abnormally activated in various tumors. Literature reports that 78% of refractory/recurrent NB have activating mutations in the RAS-MAPK pathway, suggesting a close association between this pathway and refractory/recurrent NB. In addition, in some tumor cell lines, ATO can cause upregulation of the MAPK pathway, which may be the reason for the poor efficacy of ATO in some HR-NB children and suggests the necessity of combining MAPK inhibitors in ATO-containing induction chemotherapy regimens. Studies have shown that in APL cell line NB4 and APL primary cells, MAPK (MEK) inhibitors (PD98059 and PD184352) enhance apoptosis in ATO-treated cells by inhibiting downstream ERK1/2 and Bad phosphorylation, indicating that combining ATO with MAPK inhibitors can further improve efficacy.
Clinical studies show that single-agent MAPK inhibitors often have poor efficacy in the treatment of advanced or refractory tumors. Studies have found that in ALK-dependent RAS-MAPK mutant NB cell lines, MAPK inhibitors can activate the pro-cancer PI3K-AKT pathway through the mTORC2 complex-related subunit SIN1, and thus the MAPK inhibitor trametinib cannot inhibit the growth of ALK-dependent NB in mouse models. Previous studies have found that ATO can downregulate the PI3K-AKT pathway in various tumors, and we have found through non-label quantitative proteomics technology that ATO treatment of NB cell line SK-N-BE(2) can also cause downregulation of this pathway, and studies have shown that ATO can inhibit the activity of the mTORC2 complex in this pathway. In summary, we propose combining ATO with MAPK inhibitors, with the aim of using MAPK inhibitors to counteract the adverse effects of ATO activating the MAPK pathway, while ATO inhibits the activation of the PI3K-AKT pathway caused by MAPK inhibitors, thereby jointly inhibiting tumor growth.
As chemotherapy progresses, tumor cells gradually accumulate DNA damage under chemotherapy pressure, leading to a higher probability of gene mutations and clonal evolution associated with poor prognosis, increasing the likelihood of drug resistance; studies show that primary/acquired resistance in NB is also related to the high-frequency clonal diversity that gradually emerges with chemotherapy; under the selective pressure of chemotherapeutic drugs, cells with drug-resistant characteristics gradually expand and enrich, and gradually dominate; the later the remission time during induction chemotherapy in NB patients, the worse the prognosis; studies show that patients with initial bone marrow minimal residual disease(MRD) positivity who remain positive after 4 courses of chemotherapy have a significantly higher recurrence rate than those who become negative (74.1% vs. 33.3%), and the event-free survival has statistical significance; and radical surgery performed after the 3rd or 4th course of induction chemotherapy according to consensus and mainstream cooperative group regimens may also be one of the potential risk factors promoting the dissemination and metastasis of NB tumor cells; therefore, we chose to add trametinib to the medication sequence starting from the 5th course of induction chemotherapy, for a total of 5 courses of combined medication (the 5th to 9th courses of induction chemotherapy). The effectiveness and safety of the above combined medication strategy need to be further verified through multicenter collaborative clinical studies, and we expect that this combined medication regimen can improve the treatment status and prognosis of HR-NB, a refractory tumor.
Based on the above theoretical basis, the combination of MAPK pathway inhibitors with ATO has a synergistic effect, and we expect that the new regimen of adding the MAPK pathway inhibitor trametinib to the original ATO combined chemotherapy regimen can improve CRR. Therefore, this study aims to use the CRR at EOI of ATO combined chemotherapy and MAPK signaling pathway inhibitor(for example. trametinib) in the treatment of 4/M stage NB as the main research objective. The overall CRR at EOI for 4/M stage NB, both domestically and internationally, will serve as an external control to assess the clinical efficacy and safety of ATO-combined chemotherapy plus the MAPK signaling pathway inhibitor during the induction chemotherapy phase of 4/M stage NB.
Study Oversight
Has Oversight DMC:
None
Is a FDA Regulated Drug?:
False
Is a FDA Regulated Device?:
False
Is an Unapproved Device?:
None
Is a PPSD?:
None
Is a US Export?:
None
Is an FDA AA801 Violation?: