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Research into the causes, prevention, detection, testing, and treatment of prostate cancer is being done in many medical centers throughout the world.
New research on gene changes linked to prostate cancer is helping scientists better understand how prostate cancer develops. This could make it possible to design medicines to target those changes.
Tests for abnormal prostate cancer genes might also help identify men at high risk who might benefit from screening or from chemoprevention clinical trials, which use drugs to try to keep them from getting cancer.
In men already diagnosed with prostate cancer, tests for certain gene changes can give men and their doctors a better idea of how likely the cancer is to grow and spread, which might influence treatment options (see below).
Researchers continue to look for foods (or substances in them) that can help lower prostate cancer risk. Scientists have found some substances in tomatoes (lycopenes) and soybeans (isoflavones) that might help prevent some prostate cancers. Studies are now looking at the possible effects of these compounds more closely.
Scientists are also trying to develop related compounds that are even more potent and might be used as dietary supplements. But so far, most research suggests that a balanced diet including these foods as well as other fruits and vegetables is probably of greater benefit than taking specific substances as dietary supplements.
One vitamin that may be important in prevention is vitamin D. Some studies have found that men with high levels of vitamin D seem to have a lower risk of developing the more lethal forms of prostate cancer. Overall though, studies have not found that vitamin D protects against prostate cancer.
Some research has suggested that men who regularly take certain medicines (such as aspirin or cholesterol-lowering statins) for a long time might have a lower risk of getting or dying from prostate cancer. Still, more research is needed to confirm this, and to confirm that any benefit outweighs potential risks.
Scientists have also tested certain hormonal medicines called 5-alpha reductase inhibitors as a way of reducing prostate cancer risk. This is discussed in Can Prostate Cancer Be Prevented?
Doctors agree that the prostate-specific antigen (PSA) blood test is not a perfect test for finding prostate cancer early. It misses some cancers, and it sometimes finds cancers that probably never need to be treated. Researchers are working on strategies to address these issues.
One approach is to try to improve on the test that measures the total PSA level, as described in Screening Tests for Prostate Cancer.
Another approach is to develop new tests based on other forms of PSA, or other tumor markers. Several newer tests seem to be more accurate than the PSA test, including:
These tests aren’t likely to replace the PSA test any time soon, but they might be helpful in certain situations. For example, some of these tests might be useful in men with a slightly elevated PSA, to help determine whether they should have a prostate biopsy. Some of these tests might be more helpful in determining if men who have already had a prostate biopsy that didn’t find cancer should have another biopsy. Doctors and researchers are trying to determine the best way to use each of these tests.
Doctors doing prostate biopsies often rely on transrectal ultrasound (TRUS), which creates black and white images of the prostate using sound waves, to know where to take samples from. But standard ultrasound may miss some areas containing cancer. There are several newer approaches to diagnosing prostate cancer.
Determining the stage (extent) of prostate cancer plays a key role in determining a man’s treatment options. But imaging tests for prostate cancer such as CT and MRI scans can’t detect all areas of cancer, especially small areas of cancer in lymph nodes, so doctors are now looking at newer types of imaging tests.
Multiparametric MRI can be used to help determine the extent of the cancer and how aggressive it might be, which might affect a man’s treatment options. For this test, a standard MRI is done to look at the anatomy of the prostate, and then at least one other type of MRI (such as diffusion weighted imaging [DWI], dynamic contrast enhanced [DCE] MRI, or MR spectroscopy) is done to look at other parameters of the prostate tissue. The results of the different scans are then compared to help find abnormal areas.
Enhanced MRI may help find lymph nodes that contain cancer cells. Patients first have a standard MRI. They are then injected with tiny magnetic particles and have another scan the next day. Differences between the 2 scans point to possible cancer cells in the lymph nodes. Early results of this technique are promising, but it needs more research before it becomes widely used.
For standard positron-emission tomography (PET) scans, a type of radioactive tracer known as FDG is injected into the body and then detected with a special camera. Unfortunately, these scans aren’t very helpful in staging prostate cancer. But newer types of PET scans may be more helpful in detecting prostate cancer in different parts of the body. These newer tests use tracers other than FDG, such as radioactive sodium fluoride, fluciclovine, choline, or carbon acetate. Some newer tests (known as PSMA PET scans) use radioactive tracers that attach to prostate-specific membrane antigen (PSMA), a substance that is often found in large amounts on prostate cancer cells. Some of these newer tests are now being used in certain centers, while others are still being studied. For more information, see Tests to Diagnose and Stage Prostate Cancer.
Newer treatments are being developed, and improvements are being made among many standard prostate cancer treatment methods.
Doctors are constantly improving the surgical techniques used to treat prostate cancer. The goal is to remove all of the cancer while lowering the risk of complications and side effects from the surgery.
As described in Radiation Therapy for Prostate Cancer, advances in technology are making it possible to aim radiation more precisely than in the past. Current methods such as conformal radiation therapy (CRT), intensity modulated radiation therapy (IMRT), and proton beam radiation help doctors avoid giving radiation to normal tissues as much as possible. These methods are expected to increase the effectiveness of radiation therapy while reducing the side effects.
Technology is making other forms of radiation therapy more effective as well. New computer programs allow doctors to better plan the radiation doses and approaches for both external radiation therapy and brachytherapy. Planning for brachytherapy can now even be done during the procedure (intraoperatively).
Researchers are looking at newer forms of treatment for early-stage prostate cancer. These new treatments could be used either as the first type of treatment or after unsuccessful radiation therapy.
One treatment, known as high-intensity focused ultrasound (HIFU), destroys cancer cells by heating them with highly focused ultrasonic beams. This treatment has been used in some countries for a while, and is now available in the United States. Its safety and effectiveness are now being studied, although most doctors in the US don’t consider it to be a proven first-line treatment for prostate cancer at this time.
Many studies have looked at the possible benefits of specific nutrients (often as supplements) in helping to treat prostate cancer, although so far none have shown a clear benefit. Some compounds being studied include extracts from pomegranate, green tea, broccoli, turmeric, flaxseed, and soy.
One study has found that men who choose not to have treatment for their localized prostate cancer may be able to slow its growth with intensive lifestyle changes. The men in the study ate a vegan diet (no meat, fish, eggs, or dairy products) and exercised frequently. They also took part in support groups and yoga. After one year the men saw, on average, a slight drop in their PSA level. It isn’t known if this effect will last since the report only followed the men for 1 year. The regimen may also be hard for some men to follow.
It's important for men thinking about taking any type of nutritional supplement to talk to their health care team first. They can help you decide which ones you can use safely while avoiding those that might be harmful.
Several newer forms of hormone therapy have been developed in recent years. Some of these may be helpful when standard forms of hormone therapy are no longer working.
Some examples include abiraterone (Zytiga), enzalutamide (Xtandi), and apalutamide (Erleada), which are described in Hormone Therapy for Prostate Cancer. Others are now being studied as well.
5-alpha reductase inhibitors, such as finasteride (Proscar) and dutasteride (Avodart), are drugs that block the conversion of testosterone to the more active dihydrotestosterone (DHT). These drugs are being studied to treat prostate cancer, either to help with active surveillance, or if the PSA level rises after prostatectomy.
Studies in recent years have shown that many chemotherapy drugs can affect prostate cancer. Some, such as docetaxel (Taxotere) and cabazitaxel (Jevtana) have been shown to help men live longer.
Results of large studies have shown that giving men with metastatic prostate cancer chemotherapy (docetaxel) earlier in the course of the disease might help them live longer.
Other new chemo drugs and combinations of drugs are being studied as well.
The goal of immunotherapy is to boost the body’s immune system to help fight off or destroy cancer cells.
Unlike vaccines against infections like measles or mumps, prostate cancer vaccines are designed to help treat, not prevent, prostate cancer. One possible advantage of these types of treatments is that they seem to have very limited side effects. An example of this type of vaccine is sipuleucel-T (Provenge), which has received FDA approval (described in Immunotherapy for Prostate Cancer).
Several other types of vaccines to treat prostate cancer are being tested in clinical trials.
An important part of the immune system is its ability to keep itself from attacking other normal cells in the body. To do this, it uses “checkpoints” – proteins on immune cells that need to be turned on (or off) to start an immune response. Cancer cells sometimes use these checkpoints to avoid being attacked by the immune system. But newer drugs that target these checkpoints hold a lot of promise as cancer treatments.
For example, newer drugs such as pembrolizumab (Keytruda) and nivolumab (Opdivo) target the immune checkpoint protein PD-1, while atezolizumab (Tecentriq) targets the related PD-L1 protein. These types of drugs have been shown to be useful in treating many types of cancer, including some prostate cancers with DNA mismatch repair (MMR) gene changes (although these are rare in prostate cancer). Studies are now being done to see how well these drugs might work against other prostate cancers.
One promising approach for the future might be to combine a checkpoint inhibitor with another drug. For example, combining it with a prostate cancer vaccine might strengthen the immune response and help the vaccine work better. Other types of drugs might help the immune system better recognize the cancer cells, which might help the checkpoint inhibitor itself work better.
In this treatment, immune cells called T cells are removed from the patient’s blood and altered in the lab so they have receptors called chimeric antigen receptors (CARs) on their surface. These receptors can be made to attach to proteins on the surface of prostate cells. The altered T cells are then multiplied in the lab and put back into the patient’s blood. The hope is that they can then find the prostate cancer cells in the body and launch a precise immune attack against them.
This technique has shown some encouraging results against prostate cancer in early clinical trials, but more research is needed to see how useful it can be. CAR T-cell therapy for prostate cancer is a complex treatment with potentially serious side effects, and it is only available in clinical trials at this time.
Newer drugs are being developed that target specific parts of cancer cells or their surrounding environments. Each type of targeted therapy works differently, but all alter the way a cancer cell grows, divides, repairs itself, or interacts with other cells.
Some men with prostate cancer have mutations in DNA repair genes (such as BRCA2) that make it hard for cancer cells to fix damaged DNA. Drugs called poly-adenosine diphosphate ribose polymerase (PARP) inhibitors work by blocking a different DNA repair pathway. Cancer cells are more likely to be affected by these drugs than normal cells.
PARP inhibitors such as olaparib, rucaparib, and niraparib have shown promising results in early studies of men with one of these gene mutations, and these drugs are now being studied in larger clinical trials.
These are manmade versions of immune proteins that can be designed to attach to very specific targets on cancer cells (such as the PSMA protein on prostate cancer cells). For prostate cancer, most of the monoclonal antibodies being studied are linked to chemo drugs or to small radioactive molecules. The hope is that once injected into the body, the antibody will act like a homing device, bringing the drug or radioactive molecule directly to the cancer cells, which might help them work better. Several monoclonal antibodies are now being studied in clinical trials.
Doctors are studying the use of radiofrequency ablation (RFA) to help control pain in men whose prostate cancer has spread to one or more areas in the bones. During RFA, the doctor uses a CT scan or ultrasound to guide a small metal probe into the area of the tumor. A high-frequency current is passed through the probe to heat and destroy the tumor. RFA has been used for many years to treat tumors in other organs such as the liver, but its use in treating bone pain is still fairly new. Still, early results are promising.
Our team is made up of doctors and oncology certified nurses with deep knowledge of cancer care as well as journalists, editors, and translators with extensive experience in medical writing.
Considine B, Petrylak DP. Integrating novel targets and precision medicine into prostate cancer care—Part 1: The non-androgen–targetable pathways in castration-resistant prostate cancer. Oncology (Williston Park). 2019; 33(3):113-118.
Nelson WG, Antonarakis ES, Carter HB, DeMarzo AM, DeWeese TL. Chapter 81: Prostate Cancer. In: Niederhuber JE, Armitage JO, Doroshow JH, Kastan MB, Tepper JE, eds. Abeloff’s Clinical Oncology. 6th ed. Philadelphia, Pa: Elsevier; 2020.
Walczak JR, Pili R, Carducci MA, Antonarakis ES. Investigational approaches for the treatment of advanced prostate cancer. UpToDate. 2019. Accessed at https://www.uptodate.com/contents/investigational-approaches-for-the-treatment-of-advanced-prostate-cancer on April 8, 2019.
Zelefsky MJ, Morris MJ, Eastham JA. Chapter 70: Cancer of the Prostate. In: DeVita VT, Lawrence TS, Rosenberg SA, eds. DeVita, Hellman, and Rosenberg’s Cancer: Principles and Practice of Oncology. 11th ed. Philadelphia, Pa: Lippincott Williams & Wilkins; 2019.
Last Revised: October 8, 2021
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