Even though statistics show 1 in 8 U.S. women will be diagnosed with breast cancer, there is hope on the horizon. Overall, survival rates continue to rise and women are living longer after beating the disease. In order to keep this momentum, however, which can lead to improved care and better outcomes, it’s necessary to continue advancing our understanding of the disease through research.
Breast cancer research opens the door to finding better ways to prevent, detect, and treat breast cancer, and to improve the quality of life of both cancer patients and survivors. From studying causes and prevention to learning how to manage and treat, here are some of the main focuses in breast cancer research today.
Researching the Causes of Breast Cancer
Cancer researchers are actively studying what causes breast cancer. Studies continue to uncover cancer-contributing factors such as lifestyle habits as well as inherited genes that may increase the risk of breast cancer. Here are some examples of ongoing studies:
Research into how exercise, diet, and body weight gain or loss affect breast cancer risk
Studies on how to best use genetic testing to detect gene mutations that lead to breast cancer
Exploration on how common gene variations (small changes in genes that are not as significant as mutations) may affect breast cancer risk
A look into environmental factors that can cause breast cancer
Research on how to Lower the Risk of Developing Breast Cancer
Researchers are actively looking for medicines that may help lower the risk of breast cancer:
Hormone therapy drugs, which are typically used to help treat breast cancer, are being researched to determine if some may also help prevent it
Non-hormonal drugs for breast cancer reduction are being evaluated through clinical trials
Exploration into drugs that may prevent breast cancer from coming back or spreading to the bones
Research on Ways to Manage Ductal Carcinoma in Situ
The behavior of Ductal Carcinoma in Situ (DCIS) is unpredictable. Ductal Carcinoma in Situ refers to a condition in which abnormal cells are found in the lining of a breast duct. DCIS is considered non-invasive or pre-invasive breast cancer, meaning these cells are contained within the ducts (in situ) and have not spread outside the breast. However, without additional treatment after surgery, these cells can become invasive, spreading to lymph nodes or other organs. Because of this unpredictability, determining the best method of treatment is challenging.
Researchers are continuously studying ways to use computers and statistical methods to estimate the chances that the DCIS will become invasive. They also ask women diagnosed with DCIS what factors (such as survival rates, recurrence prevention, and side effects) they consider most important in choosing a treatment. Most women with DCIS are candidates for lumpectomy. However, certain factors may make mastectomy a better option.
Breast Cancer Treatment Research
One major use for cancer research is finding new treatments or combinations of treatments that will work more effectively for specific types of breast cancer. Some research involves new combinations of treatments that are already considered the standard of care, while other research involves newer surgical techniques or drugs. This is the most common type of cancer research currently underway.
For example, one type of breast cancer that has been difficult to treat is triple negative breast cancer. However, recent clinical studies show that this aggressive cancer may be caused by a mutation in the BRCA gene.
Currently, testing for BRCA gene mutation is not routine for women diagnosed with triple negative breast cancer. Because of these findings, however, researchers are suggesting that they should be, since those who test positive may benefit from this new treatment. Knowing if the BRCA gene is involved opens up different treatment options than what would typically be given for triple negative breast cancer. The study, funded by Cancer Research UK and Breast Cancer Now, showed that triple negative breast cancers carrying the mutated BRCA gene showed a greater response to carboplatin (Paraplatin) rather than the standard chemotherapy given to triple negative patients.
Interested in Participating in a Breast Cancer Clinical Trial?
Arizona Oncology is dedicated to advancing breast cancer care by leading and participating in clinical trials that test the safety and efficiency of new or modified treatments. If you would like to learn more about clinical trials that might be right for you, please click here.
According to the American Cancer Society, lung cancer is the leading cause of cancer death in the United States , with about 222,500 new cases and 155,870 deaths each year. Fortunately, lung cancer deaths have begun to decline, due to a decrease in smoking. The field of cancer care has also advanced faster than most fields in medicine, and major progress has been made in lung cancer treatments, including surgery (delivered by thoracic surgeons), radiation treatments for lung cancer (delivered by radiation oncologists) and systemic therapies (delivered by medical oncologists).
Treatment for Lung Cancer
The majority of lung cancers can be split into two major groups – either non-small cell lung cancer (NSCLC), which makes up 80-85% of lung cancers, or small cell lung cancer (SCLC). We will focus on treatment options for NSCLC in this review. The decision to choose certain lung cancer treatments over others depends on many patient-related factors. Once lung cancer has been detected and diagnosed, we first need to carefully identify if the cancer cells are localized or have spread to regional lymph nodes or other parts of the body – this process is called staging. For lung cancer staging, we typically use CT scans, PET/CT scans, bone scans, MRI imaging and invasive procedures, including endobronchial ultrasound or mediastinoscopy. Based on the extent of the tumor, staging for lung cancer ranges from I or II (early stage), stage III (locally advanced) and stage IV (metastatic).
Lung cancer treatment decisions are then based upon the stage, tumor location, and functional status of the patient. Treatment for lung cancer typically includes surgery, systemic therapy, radiation therapy, or a combination of these modalities. Systemic therapies include chemotherapy, targeted therapy, and immunotherapy. For instance, patients with early stage lung cancers who are medically able to undergo surgery may be cured with surgery (such as a lobectomy or pneumonectomy) +/- chemotherapy alone. For patients with early-stage cancers who are not surgical candidates or who prefer a non-surgical approach, stereotactic body radiation therapy (SBRT) is a highly innovative technique that has been shown to provide excellent outcomes (discussed further below) in patients that have been diagnosed with non-small cell lung cancer. For more locally advanced stages that are not amenable to surgery, a combination of systemic therapy, such as chemotherapy, and radiation may be the most effective approach. Stage IV lung cancers (also known as metastatic lung cancer) are incurable and treatment is given to improve symptoms and slow down progression. These treatments have advanced quickly over the last few years, and we will highlight some key advances in the fields of radiation and systemic therapy.
Advances in Radiation Therapy for Lung Cancer
When radiation therapy for lung cancer patients first began in 1956 in the USA, it was very rudimentary. A highly potent X-ray machine was positioned close to the tumor, and the machine was turned on. The challenge was that radiation oncologists couldn’t always treat the entire lung tumor and, many times, the side effects were too severe to continue treatment.
As technology improved (Figure 1), we began to utilize CT and MRI scans to help identify the specific location of the tumor and the surrounding normal tissues (like the heart, lungs, liver, among many others). This helped to create a much more effective radiation treatment plan that could better target the lung cancer, and we called this 3-dimensional radiation therapy.
More recently, however, the newest radiation machines have enabled more accurate treatment of the tumor while minimizing radiation dose to the normal body.
We now use numerous beam angles to shape the radiation dose to the specific size and shape of the tumor – a treatment called intensity modulated arc therapy (IMRT). As technology has further improved, we can now deliver IMRT with an even higher degree of sophistication and conformality with a technique called volumetric-modulated arc therapy (or VMAT). Figure 2 shows the most modern radiation therapy linear accelerator, which is now available at our St. Mary’s and Green Valley offices.
As we have continued to improve our ability to deliver VMAT, we can now deliver very high doses of radiation in just a few treatments. This form of treatment is called stereotactic body radiation therapy (or SBRT) and offers an excellent opportunity to control cancer, reduce symptoms, and improve quality of life in very specific patients. Whereas treatment for these lung cancers used to take 30 to 35 treatments, it can now take as little as 1 to 5 treatments.
Figure 3 details an SBRT plan delivered using the advanced VMAT approach.
Advances in Systemic Therapy
Systemic therapies, which can include chemotherapy, targeted therapy, and immunotherapy, have also undergone significant advancements in the past several years. Chemotherapy has commonly been given to non-metastatic lung cancer patients whose tumors are large, have unfavorable characteristics, or whose tumors have spread to lymph nodes. The most common chemotherapy regimens are typically platinum-based chemotherapy for 4-6 cycles. Chemotherapy can also be used at a lower-dose to enhance the effectiveness of radiation therapy and can be given at the same time as radiation, depending on the clinical situation.
However, the biggest advances in systemic therapies have been made for metastatic (or Stage IV) non-small cell lung cancers (NSCLC). The first step in determining which systemic therapies are most appropriate for patients with metastatic lung cancer is to identify the histologic and molecular features specific to the lung cancer. About 20% of metastatic NSCLC cases have so called “actionable driver mutations” where we have specific systemic therapies that can target the mutation. The known mutations with targeted agents that are approved for treatment are EGFR, ALK-1 and ROS mutations – these mutations are associated with favorable prognoses. Additionally, the expression level of a protein called PD-L1 can help inform the treatment team if the patient is a candidate for immunotherapy. There are many other mutations that have been identified and new clinical trials are helping to identify novel targeted agents for those mutations.
These advances in surgery, radiation therapy, and systemic therapy only serve to highlight the rapid improvements in lung cancer therapies, and multiple clinical trials are underway to continue to push the efficacy, safety, and quality of life of novel therapies for lung cancer.
