Newer Treatments

[Deanne Jenkyns]

Newer Treatment Options
There have been encouraging advances made in recent years in the fight against lung cancer, and researchers are investigating potential new treatments or treatment strategies all the time. The following list is a brief sample of some the types of potential anti-cancer agents and technologies under investigation:

New Surgical Techniques
Video-assisted thoracoscopic surgery (VATS): a less invasive surgical technique that may be helpful for people with marginal lung function who cannot tolerate major surgery. VATS allows “keyhole” surgery, enabling the surgeon to perform the necessary surgery through a small incision with the aid of a video camera and television screen.

New Radiation Techniques
Conformal 3-D radiation therapy is an important new technique that allows the dose of radiation to be increased with a reduction in the exposure time.
The combination of both primary radiation therapy and chemotherapy is being examined and shows promise.
Fractionation: the practise of varying the dose, duration and time between radiation treatments.
Radiation modifiers can be used to change the cellular response to radiation. These agents appear to inhibit cancer cells from repairing the damage caused by a radiation treatment.
Radiation sensitisers i.e. agents that make cells more sensitive to the effects of radiation.
Brachytherapy – a technique used to deliver high doses of radiation from very short distances and involves the placement of a small radiation source in the airway next to a tumour.
Epidermal Growth Factor Receptor (EGFR) inhibitors
EGFR inhibitors are designed to stop the uncontrolled growth of cancer cells in certain types of tumour. EGFR inhibitors work by blocking one of the important signalling pathways involved in cancer cell growth in lung tumours. Clinical studies of these agents in advanced lung cancer have demonstrated that significant numbers of patients achieved either tumour shrinkage or stabilised disease and many patients experienced an improvement in their disease related symptoms.

New Chemotherapy Agents
Promising new chemotherapeutic agents are in clinical trials now, either alone, or in a variety of combinations. Timing and dosing of chemotherapeutic agents is under investigation, as are products that could enhance the effectiveness of the drugs or which can protect normal cells during chemotherapy.

Anti-angiogenic compounds
There are a variety of treatments under investigation that may inhibit the formation of tumour blood vessels. Solid tumours, such as lung cancer are able to grow and survive in the human body only by developing their own blood vessels to link into the body’s blood supply. By preventing the tumour from thus accessing the body’s blood supply – which brings nutrients and oxygen to the tumour cells, enabling them to survive and grow, and takes waste products away for processing elsewhere in the body – the tumour cells will eventually die.

Gene Therapy
Gene therapy for cancer uses genetic material as a therapeutic agent. The aim is to insert into cancer cells a regulator gene that has been lost or altered, or to try to block production of a gene whose function is to promote uncontrolled cell growth. For example, half of all NSCLC patients have abnormalities in their p53 gene – the gene responsible for killing abnormal cells. Whether it is this gene, or other genes involved with lung cancer, genetic therapy may hold promise for preventing and treating NSCLC.

Matrix Metalloprotease Inhibitors
Matrix metalloproteases (MMPs) are naturally-occurring enzymes which help to break down the structure between cells in order to make room for new, healthy tissue to grow. These enzymes are important in normal processes like new blood vessel development and wound healing. It is also believed, however, that MMPs can assist tumour cells as they invade surrounding healthy tissue and spread to more distant parts of the body and may help the development of new tumour blood vessels. By inhibiting the action of MMPs, it is hoped that tumour growth and spread may be slowed down.

Therapeutic Monoclonal Antibodies
Monoclonal antibodies are antibodies that are cloned, or artificially reproduced in a laboratory. They bind only to a certain protein that is a “match” for them. This means monoclonal antibodies can be designed to attach to certain tumour cells and destroy only them.

link to full article
www.lungcancercoalition.org/cancer_facts.html#new_options

[dtay]

This vaccination also sounds promising for hopefully the not too distant future :


David Carbone, MD, PhD David Jablons, MD Charles A. Butts, MD Summary

Development of L-BLP25 Vaccine for NSCLC
DR. BUTTS: MUC-1 is a glycoprotein present on the luminal surfaces of many normal epithelial cells (although also present on myeloma and plasma cells) that has been identified as an important target for vaccine development, especially in patients with lung cancer. It is a long branched-chain carbohydrate that has a long extracellular component with an amino acid backbone and branched-chain carbohydrate side chains. Also present are an anchoring cell membrane component and an intracellular component that may have tyrosine kinase activity or may interact with other intracellular proteins. It is often one of the first substances that an immune effector cell might encounter.

MUC-1 possesses many key features of an ideal tumor antigen.
In cancer cells, MUC-1 is expressed over the entire cell surface. In malignant cells, the branched-chain carbohydrate becomes truncated and exposes the protein backbone. It becomes like a neoantigen.

MUC-1 possesses many key features of an ideal tumor antigen. It is expressed on tumor cells—not confined to the tumor cells, but significantly different in tumor cells as opposed to normal cells. It is broadly expressed—more than 80% of tumor cells, in general, express MUC-1; probably 60% or more of NSCLCs express MUC-1.23

It is expressed in sufficient levels or, in fact, overexpressed on many cells. It is expressed in metastatic cells as well as in primary tumors. It seems to play a role in tumorigenesis, such that if the pathway can be interrupted, the overall tumorigenic process may be affected. Most importantly, multiple studies show that MUC-1 is an immunogenic antigen in humans

For the L-BLP25 vaccine, the antigen is the entire 20 amino acid tandem repeat segment of the MUC-1 protein backbone. It uses an adjuvant for the source of cytokines, monophosphoryl lipid A, which is a nonspecific immune stimulant that may affect toll-like receptors as well. The delivery system is a liposomal formulation, which is thought to enhance delivery to immune effector cells.

The clinical development of L-BLP25 has occurred primarily in the lung cancer arena. Its safety, as well as schedule and dose, were established in phase I and II trials. The main trial of interest is the phase IIB trial, which was an open-label, randomized, multicenter trial of the vaccine in patients with stage IIIB/IV NSCLC who responded or had stable disease to first-line lung cancer therapy, whether chemotherapy alone or chemoradiation.24 Eligible patients were randomized to best supportive care or the vaccine plus best supportive care. If disease progressed, patients were eligible for second-line treatment. The primary endpoints were efficacy (survival) and safety, and secondary endpoints included health-related quality of life and the immune response elicited by the vaccine as assessed by the MUC-1 proliferative T-cell response. Tumor responses were not expected and therefore were not measured.

The vaccine strategy incorporated a single dose of cyclophosphamide, 300 mg/m2, given 3 days before the initiation of the L-BLP25 vaccine. Previous trials have shown that cyclophosphamide enhances the immune response as measured by DTH and antibody production.25,26 The vaccine was given subcutaneously at a standard dose of 1,000 µg once weekly for 8 weeks as an induction phase. Patients who were considered to have stable disease were eligible for a maintenance phase of vaccine therapy, which employed the same dose as the induction phase, but was given once every 6 weeks. Patients continued on the vaccine until disease progression.

A total of 171 patients was enrolled in the study at 17 centers in Canada and the United Kingdom over a 2-year period. Demographics were comparable in the 2 patient groups. About 95% of patients had performance status of 0 or 1; more than 95% had received standard first-line platinum-based chemotherapy. Of the patients, 35% had stage IIIB or local regional disease, and 65% had either pleural effusions or stage IV disease.

Overall, the 2-year survival rate was 43.2% for the L-BLP25 arm vs 28.9% for the best-supportive-care arm, and the median overall survival time for patients in the L-BLP25 arm was 17.2 months compared with 13.0 months in the best-supportive-care arm. The greatest survival difference was noted in patients with stage IIIB locoregional disease, in whom survival was longer for those randomly assigned to the L-BLP25 arm compared with the best-supportive-care arm (Figure 3). At 34 months, the survival rate was 48.6% for the L-BLP25 arm vs 26.7% for the best-supportive-care arm, and median survival was 30.6 months among the L-BLP25 vaccine recipients compared with 13.3 months among those in the best-supportive-care group. No clinically significant survival advantage was noted in patients with stage IIIB pleural effusion or stage IV disease.

No significant toxicity was associated with the L-BLP25 vaccine, and quality of life was maintained longer in patients who received the vaccine.

Planning for a phase III trial of the L-BLP25 vaccine is nearing completion. It is a double-blind, placebo-controlled trial of L-BLP25 vaccine in patients with unresectable stage III NSCLC, with planned enrollment of over 1,300 patients. The primary endpoint will be overall survival; secondary endpoints include time to symptom progression, time to tumor progression, and safety. The study will also include a cost-effectiveness evaluation.

Link :http://www.targetedtherapies.org/rdt1_5.html

[dtay]

Cyberknife (radiofrequency abalation)
This is also a very promising new procedure which has started being used in the States for Elderly patients who cannot tolerate surgery or indeed anyone who has a tumour/s which is/are unsuitable for resection(I think the tumrours need to be no more than 3cms tho)

How Does CyberKnife Work?
CyberKnife is a non-surgical procedure that delivers high doses of radiation to cancerous and benign tumors without damaging nearby healthy tissue and organs. Utilizing precision technology developed to guide cruise missiles to their target, CyberKnife represents a significant advancement in stereotactic radiosurgery.
During the CyberKnife procedure, more than 100 beams of radiation produced by a linear accelerator enter the body from different angles. By itself, each small beam of radiation does not harm the healthy tissue or organs it passes through. It is when each of these beams intersects at the target that a high enough dose is delivered to destroy the tumor and stop the progression of abnormal cell growth.
CyberKnife's advanced image-guided stereotactic robotic system delivers radiation so precisely that it can stay on target even if a patient moves during treatment. With its attached linear accelerator, CyberKnife's robotic arm delivers radiation to a specific target, guided by a computerized 3-D map created through the use of CT or MRI scans. Any movement by the patient is compensated for by the robotic system, ensuring optimal accuracy throughout treatment.

Link : www.comhs.org/cyberknife/advantage.asp

[Deanne Jenkyns]

Thanks for sharing Dawn


Deanne
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[Deanne Jenkyns]

American Society of Clinical Oncology

Useful website for finding the latest advances in cancer care.

www.plwc.org/portal/site/PLWC



Deanne
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