Showing posts with label lung cancer. Show all posts
Showing posts with label lung cancer. Show all posts

Saturday, September 12, 2020

Combined drug treatment for lung cancer and secondary tumors



In continuation of my update on alectiniberlotinib and  osimertinib

Alectinib structure.svg 
                                                                   alectinib

                                                   Erlotinib Structural Formulae.png 
                                                                     erlotinib
                                                  Osimertinib.svg
                                                                             Osimertinib


Researchers at Kanazawa University report in the Journal of Thoracic Oncology a promising novel approach for a combined treatment of the most common type of lung cancer and associated secondary cancers in the central nervous system. The approach lies in combining two cancer drugs, with one compensating for a resistance side effect of the other.

In 20 to 40% of patients with cancer, metastasis (the development of secondary tumors) in the central nervous system (CNS) occurs. CNS metastasis impacts negatively on a patient's quality of life, and is associated with a poor health prognosis. In a form of cancer known as ALK-rearranged non-small-cell lung cancer (NSCLC), CNS metastasis is known to persist when drugs targeting primary tumors are used. Now, Seiji Yano from Kanazawa University and colleagues have investigated the origins for the resistence to such drugs, and tested a new therapeutic strategy on a mouse model.

The researchers looked at the drug alectinib. Although used in standard treatments for advanced ALK-rearranged NSCLC, approximately 20 to 30% of patients treated with alectinib develop CNS metastasis, which is attributed to acquired resistance to the drug.
By treating mice first injected with tumor cells with alectinib daily for 16 weeks, the scientists obtained a mouse model displaying alectinib resistance. By biochemical analyses of the mouse brains, Yano and colleagues were able to link the resistance to the activation of a protein known as epidermal growth factor receptor (EGFR). This activation is, in turn, a result of an increase in production of amphiregulin (AREG), a protein that binds to EGFR and in doing so 'activates' it.
Based on this insight, the researchers tested the effect of administering drugs used for inhibiting the action of EGFR in combination with alectinib treatment. The experiments showed that a combination treatment of alctinib with either erlotinib or osimertinib—two existing EGFR-inibiting drugs—prevented the progression of CNS metastasis, controlling the condition for over 30 days.
The scientists conclude that the combined use of alectinib and EGFR-inhibitors could overcome alectinib resistance in the mouse model of leptomeningeal carcinomatosis (LMC), a particular type of CNS metastasis. Quoting Yano and colleagues: "Our findings may provide rationale for clinical trials to investigate the effects of novel therapies dual-targeting ALK and EGFR in ALK-rearranged NSCLC with alectinib-resistant LMC."
Non-small-cell lung cancer
Non-small-cell lung carcinoma (NSCLC) and small-cell lung carcinoma (SCLC) are the two types of lung cancer. 85% of all lung cancers are of the NSCLC type. NSCLCs are less sensitive to chemotherapy than SCLCs, making drug treatment of the highest importance.
Alectinib is a drug used for treating NSCLC, with good efficiency. However, 20-30% of patients taking the  develop secondary cancer in the central nervous system (CNS), which is associated with an acquired resistance to alectinib. Seiji Yano from Kanazawa University and colleagues have now made progress towards a novel therapy against this resistance: a combination of alectinib with other drugs.
Epidermal growth factor receptor inhibitors
The drugs that Yano and colleagues tested in combination with alectinib on a mouse model were of a type known as epidermal growth factor receptor (EGFR) inhibitors, including osimertinib and erlotinib. Both are being used as medication for treating NSCLC. The former was approved in 2017 as cancer treatment by the U.S. Food and Drug Administration and the European Commission. Yano and colleagues obtained results showing that EGFR inhibitors counteract resistance to alectinib and have therefore potential in novel therapies for NSCLC and secondary cancers in the CNS.
https://medicalxpress.com/news/2017-11-osimertinib-progression-free-survival-asian-egfr-mutated.html

Friday, August 25, 2017

New Application of Existing Drug Offers Personalized Therapy for Lung Cancer

A subset of lung tumours is exquisitely sensitive to a class of recently approved anti-cancer drugs. Researchers at the CeMM Research Center for Molecular Medicine of the Austrian Academy of Sciences in Vienna and the Ludwig Institute for Cancer Research in Oxford published this finding in the journal Nature Communications. It opens the way for new clinical trials in a type of cancer considered to be "undruggable" and may lead to a therapy for up to 10% of lung cancer patients.

(Vienna, 6th of December 2016) Lung cancer remains the leading cause of cancer-related deaths worldwide. In contrast to other tumour types, lung tumours present a high number of genomic alterations - this is a consequence of exposure to carcinogenic substances found in tobacco smoke, which is the main cause of lung cancer. About 10% of lung tumours carry mutations in a gene called ATM. However, there are no drugs available in the clinic to treat ATM mutant lung cancer.

With cutting edge high-throughput drug screens that analyse how the genetic makeup of the patient affects their response to drugs, the team of Sebastian Nijman, CeMM Adjunct PI and Group Leader at the Ludwig Institute for Cancer Research in Oxford made a surprising discovery: Cancer cells with ATM mutations are sensitive for drugs that inhibit an enzyme called MEK. The study was published in Nature Communications (DOI: 10.1038/NCOMMS13701)

MEK is part of a biochemical pathway which is responsible for supporting proliferation and survival of the cell, while ATM plays a central role during the DNA damage response. In ATM deficient lung cancer cells, Nijman's team found that MEK inhibition results in cells being unable to keep proliferating and leads to apoptosis. An unexpected finding, as MEK inhibitors have so far been approved for the treatment of a type of skin cancer but not for lung cancer.

"Normally lung cancer cells are resistant to MEK inhibition as they activate compensatory signals," Ferran Fece, one of the two first authors on the study and former PhD student at CeMM, explains. "In contrast, ATM mutant cells fail to do this and subsequently cannot cope with the blocking of MEK and die. We call this type of unexpected drug sensitivity synthetic lethality".

 Trametinib.svg Trametinib

Michal Smida, the other shared first author on the article and former PostDoc at CeMM, adds: "We knew that cancer mutations can lead to extreme sensitivity to some drugs. But finding these cancer Achilles' heels is very difficult as they are difficult to predict and extremely rare. We screened a large number of gene and drug combinations and got lucky."


The study constitutes a substantial contribution for the development of a future precision medicine: ATM mutations could be used as a potential biomarker to stratify lung cancer patients to receive a MEK inhibitor. ATM is found to be mutated in 8-10% of lung adenocarcinomas - given that this type of tumour is among the most prevalent for both men and women worldwide, a significant number of patients could benefit from a MEK inhibitor based treatment. 


More : http://www.nature.com/articles/ncomms13701

Friday, April 26, 2013

Ganetespib Shows Potency Against Lung Cancer

Sunday, June 24, 2012

New combination of two previously approved FDA drugs treat lung cancer

In continuation of my update on Erlotinib..

Dr. Narla's laboratory focuses on the identification and characterization of the genes and pathways involved in cancer metastasis. By studying the functional role of the KLF6 tumor suppressor gene, Dr. Narla and his team have identified new signaling pathways regulated by this gene family thus providing new insight into cancer diagnosis and treatment. The team's research found that KLF6 and FOXO1, both tumor suppressor genes, are turned off as cancer spreads through the body. By using a combination of two existing FDA drugs -Erlotinib (left structure), a targeted cancer drug, and Trifluoperazine (below right structure), a medication used to treat schizophrenia, the team developed an understanding of the properties that turn these critical genes back on, initiating tumor cells to die.
Since first discovering the KLF6 gene 13 years ago as a medical student at the Mount Sinai School of Medicine in the laboratory of Dr. Scott Friedman, Dr. Narla has been involved in the identification and characterization of the KLF6 gene and its role in cancer development and the progression of cancer.
Read details at JCI.....