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Most prostate cancers are first found as a result of screening. (See Screening Tests for Prostate Cancer.) Early prostate cancers usually don’t cause symptoms, but more advanced cancers are sometimes first found because of symptoms they cause.
If prostate cancer is suspected based on results of screening tests or symptoms, tests will be needed to be sure. If you’re seeing your primary care doctor, you might be referred to a urologist, a doctor who treats cancers of the genital and urinary tract, including the prostate.
The actual diagnosis of prostate cancer can only be made with a prostate biopsy (discussed below).
If your doctor suspects you might have prostate cancer, you will be asked about symptoms you are having, such as any urinary or sexual problems, and how long you have had them. You might also be asked about possible risk factors, including your family history.
Your doctor will also examine you. This might include a digital rectal exam (DRE), during which the doctor inserts a gloved, lubricated finger into your rectum to feel for any bumps or hard areas on the prostate that might be cancer. If you do have cancer, the DRE can sometimes help tell if it’s only on one side of the prostate, if it’s on both sides, or if it’s likely to have spread beyond the prostate to nearby tissues. Your doctor may also examine other areas of your body.
After the exam, your doctor might then order some tests.
Prostate-specific antigen (PSA) is a protein made by cells in the prostate gland (both normal cells and cancer cells). PSA is mostly in semen, but a small amount is also in the blood.
The PSA blood test is used mainly to screen for prostate cancer in men without symptoms. It’s also one of the first tests done in men who have symptoms that might be caused by prostate cancer.
PSA in the blood is measured in units called nanograms per milliliter (ng/mL). The chance of having prostate cancer goes up as the PSA level goes up, but there is no set cutoff point that can tell for sure if a man does or doesn’t have prostate cancer. Many doctors use a PSA cutoff point of 4 ng/mL or higher when deciding if a man might need further testing, while others might recommend it starting at a lower level, such as 2.5 or 3.
If your PSA level is high, you might need further tests to look for prostate cancer.
To learn more about how the PSA test is used to look for cancer, including factors that can affect PSA levels, special types of PSA tests, and what the next steps might be if you have an abnormal PSA level, see Screening Tests for Prostate Cancer.
The PSA test can also be useful if you have already been diagnosed with prostate cancer.
If the results of a PSA blood test, DRE, or other tests suggest that you might have prostate cancer, you will most likely need a prostate biopsy.
A biopsy is a procedure in which small samples of the prostate are removed and then looked at with a microscope. A core needle biopsy is the main method used to diagnose prostate cancer. It is usually done by a urologist.
During the biopsy, the doctor usually looks at the prostate with an imaging test such as transrectal ultrasound (TRUS) or MRI, or a ‘fusion’ of the two (all discussed below). The doctor quickly inserts a thin, hollow needle into the prostate. This is done either through the wall of the rectum (a transrectal biopsy) or through the skin between the scrotum and anus (a transperineal biopsy). When the needle is pulled out it removes a small cylinder (core) of prostate tissue. This is repeated several times. Most often the doctor will take about 12 core samples from different parts of the prostate.
Though the procedure sounds painful, each biopsy usually causes only some brief discomfort because it is done with a special spring-loaded biopsy instrument. The device inserts and removes the needle in a fraction of a second. Most doctors who do the biopsy will numb the area first by injecting a local anesthetic alongside the prostate. You might want to ask your doctor if there are plans to do this.
The biopsy itself takes about 10 minutes and is usually done in the doctor’s office. You will likely be given antibiotics to take before the biopsy and possibly for a day or 2 after to reduce the risk of infection.
For a few days after the procedure, you may feel some soreness in the area and might notice blood in your urine. You may also have some light bleeding from your rectum, especially if you have hemorrhoids. Many men notice blood in their semen or have rust colored semen, which can last for several weeks after the biopsy, depending on how often you ejaculate.
Your biopsy samples will be sent to a lab, where they will be looked at with a microscope to see if they contain cancer cells. Getting the results (in the form of a pathology report) usually takes at least 1 to 3 days, but it can sometimes take longer. The results might be reported as:
If the prostate biopsy results are negative (that is, if they don’t show cancer), and the chance that you have prostate cancer isn’t very high based on your PSA level and other tests, you might not need any more tests, other than repeat PSA tests (and possibly DREs) sometime later.
But even if many samples are taken, biopsies can still sometimes miss a cancer if none of the biopsy needles pass through it. This is known as a false-negative result. If your doctor still strongly suspects you have prostate cancer (because your PSA level is very high, for example), your doctor might suggest:
If prostate cancer is found on a biopsy, it will be assigned a grade. The grade of the cancer is based on how abnormal the cancer looks under the microscope. Higher grade cancers look more abnormal, and are more likely to grow and spread quickly. There are 2 main ways to describe the grade of a prostate cancer.
The Gleason system, which has been in use for many years, assigns grades based on how much the cancer looks like normal prostate tissue.
Almost all cancers are grade 3 or higher; grades 1 and 2 are not often used.
Since prostate cancers often have areas with different grades, a grade is assigned to the 2 areas that make up most of the cancer. These 2 grades are added to yield the Gleason score (also called the Gleason sum).
The first number assigned is the grade that is most common in the tumor. For example, if the Gleason score is written as 3+4=7, it means most of the tumor is grade 3 and less is grade 4, and they are added for a Gleason score of 7.
Although most often the Gleason score is based on the 2 areas that make up most of the cancer, there are some exceptions when a biopsy sample has either a lot of high-grade cancer or there are 3 grades including high-grade cancer. In these cases, the way the Gleason score is determined is modified to reflect the aggressive (fast-growing) nature of the cancer.
In theory, the Gleason score can be between 2 and 10, but scores below 6 are rarely used.
Based on the Gleason score, prostate cancers are often divided into 3 groups:
In recent years, doctors have come to realize that the Gleason score might not always be the best way to describe the grade of the cancer, for a couple of reasons:
Because of this, doctors have developed Grade Groups, ranging from 1 (most likely to grow and spread slowly) to 5 (most likely to grow and spread quickly):
The Grade Groups will likely replace the Gleason score over time, but currently you might see either one (or both) on a biopsy pathology report.
Along with the grade of the cancer (if it is present), the pathology report often contains other information about the cancer, such as:
Sometimes when the prostate cells are seen, they don’t look like cancer, but they’re not quite normal, either.
Prostatic intraepithelial neoplasia (PIN): In PIN, there are changes in how the prostate cells look, but the abnormal cells don’t look like they’ve grown into other parts of the prostate (like cancer cells would). PIN is often divided into 2 groups:
Many men begin to develop low-grade PIN at an early age, but low-grade PIN is not thought to be related to prostate cancer risk. If low-grade PIN is reported on a prostate biopsy, the follow-up for patients is usually the same as if nothing abnormal was seen.
If high-grade PIN is found on a biopsy, there is a greater chance that you might develop prostate cancer over time. This is why doctors often watch men with high-grade PIN carefully and may advise another prostate biopsy (or lab tests to help determine the risk of having cancer, such as the Prostate Health Index (PHI), 4Kscore test, PCA3 tests (such as Progensa), or ConfirmMDx). This is especially true if high-grade PIN is found in different parts of the prostate (multifocal high-grade PIN), or if the original biopsy did not take samples from all parts of the prostate.
Atypical small acinar proliferation (ASAP): This might also be called glandular atypia or atypical glandular proliferation. It might also just be reported as “suspicious for cancer.” All of these terms mean that the cells look like they might be cancer when seen with the microscope, but there are too few of them to be sure. If one of these terms is used, there’s a high chance that there is also cancer in the prostate, which is why many doctors recommend repeating the biopsy within a few months.
Proliferative inflammatory atrophy (PIA): In PIA, the prostate cells look smaller than normal, and there are signs of inflammation in the area. PIA is not cancer, but researchers believe that PIA may sometimes lead to high-grade PIN or to prostate cancer directly.
For more information about how prostate biopsy results are reported, see the Prostate Pathology section of our website.
Some doctors now recommend that some men with prostate cancer be tested to look for certain inherited gene changes. This includes men in whom a family cancer syndrome (such as a BRCA gene mutation or Lynch syndrome) is suspected, as well as men with prostate cancer that has certain high-risk features or that has spread to other parts of the body. Talk to your doctor about the possible pros, cons, and limitations of such testing.
Imaging tests use x-rays, magnetic fields, sound waves, or radioactive substances to create pictures of the inside of your body. One or more imaging tests might be used:
Which tests you might need will depend on the situation. For example, a prostate biopsy is typically done with transrectal ultrasound (TRUS) and/or MRI to help guide the biopsy. If you are found to have prostate cancer, you might need imaging tests of other parts of your body to look for possible cancer spread. (Men with a normal DRE result, a low PSA, and a low Gleason score may not need any other tests because the chance that the cancer has spread is so low.)
The imaging tests used most often to look for prostate cancer spread include:
For this test, a small probe about the width of a finger is lubricated and placed in your rectum. The probe gives off sound waves that enter the prostate and create echoes. The probe picks up the echoes, and a computer turns them into a black and white image of the prostate.
The procedure often takes less than 10 minutes and is done in a doctor’s office or outpatient clinic. You will feel some pressure when the probe is inserted, but it is usually not painful. The area may be numbed before the procedure.
TRUS might be used in different situations:
Newer forms of TRUS, such as color Doppler ultrasound, might be even more helpful in some situations. (See What’s New in Prostate Cancer Research?)
MRI scans create detailed images of soft tissues in the body using radio waves and strong magnets. MRI scans can give doctors a very clear picture of the prostate and nearby areas. A contrast material called gadolinium may be injected into a vein before the scan to better see details.
MRI might be used in different situations:
To improve the accuracy of the MRI, you might have a probe, called an endorectal coil, placed inside your rectum for the scan. This can be uncomfortable for some men. If needed, you can be given medicine to make you feel sleepy (sedation).
Multiparametric MRI: This newer MRI technique can be used to help better define possible areas of cancer in the prostate, as well as to get an idea of how quickly a cancer might grow. It can also help show if the cancer has grown outside the prostate or spread to other parts of the body. 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.
When this test is done to help determine if a man might have prostate cancer, the results are typically reported using the Prostate Imaging Reporting and Data System, or PI-RADS. In this system, abnormal areas in the prostate are assigned a category on a scale ranging from PI-RADS 1 (very unlikely to be a clinically significant cancer) to PI-RADS 5 (very likely to be a clinically significant cancer).
MRI/ultrasound fusion-guided prostate biopsy: In this approach, a man gets an MRI scan a few days or weeks before the biopsy to look for abnormal areas in the prostate. During the biopsy itself, TRUS is used to view to prostate, and a special computer program is used to fuse the MRI and TRUS images on a computer screen. This can help ensure the doctor gets biopsy samples from any suspicious areas seen on the images.
If prostate cancer spreads to distant parts of the body, it often goes to the bones first. A bone scan can help show if cancer has reached the bones.
For this test, you are injected with a small amount of low-level radioactive material, which settles in damaged areas of bone throughout the body. A special camera detects the radioactivity and creates a picture of your skeleton.
A bone scan might suggest cancer in the bone, but to make an accurate diagnosis, other tests such as plain x-rays, CT or MRI scans, or even a bone biopsy might be needed.
A PET scan is similar to a bone scan, in that a slightly radioactive substance (known as a tracer) is injected into the blood, which can then be detected with a special camera. But PET scans use different tracers that collect mainly in cancer cells. The most common tracer for standard PET scans is FDG, which is a type of sugar. Unfortunately, this type of PET scan isn’t very useful in finding prostate cancer cells in the body.
However, newer tracers, such as fluciclovine F18, sodium fluoride F18, and choline C11, have been found to be better at detecting prostate cancer cells.
Other newer tracers attach to prostate-specific membrane antigen (PSMA), a protein that is often found in large amounts on prostate cancer cells. These tracers include:
Tests using these types of tracers are referred to as PSMA PET scans.
These newer types of PET scans are most often used if it’s not clear if (or exactly where) prostate cancer has spread. For example, one of these tests might be done if the results of a bone scan aren’t clear, or if a man has a rising PSA level after initial treatment but it’s not clear where the cancer is in the body. PSMA PET scans can also be used to help determine if the cancer can be treated with a radiopharmaceutical that targets PSMA.
The pictures from a PET scan aren’t as detailed as MRI or CT scan images, but they can often show areas of cancer anywhere in the body. Some machines can do a PET scan and either an MRI (PET-MRI) or a CT scan (PET-CT) at the same time, which can give more detail about areas that show up on the PET scan.
Doctors are still learning about the best ways to use these newer types of PET scans, and some of them might not be available yet in all imaging centers.
A CT scan uses x-rays to make detailed, cross-sectional images of your body. This test isn’t often needed for newly diagnosed prostate cancer if the cancer is likely to be confined to the prostate based on other findings (DRE result, PSA level, and Gleason score). Still, it can sometimes help tell if prostate cancer has spread into nearby lymph nodes. If your prostate cancer has come back after treatment, the CT scan can often tell if it is growing into other organs or structures in your pelvis.
CT scans are not as useful as magnetic resonance imaging (MRI) for looking at the prostate gland itself.
In a lymph node biopsy, also known as lymph node dissection or lymphadenectomy, one or more lymph nodes are removed to see if they have cancer cells. This isn’t done very often for prostate cancer, but it might be used to find out if the cancer has spread from the prostate to nearby lymph nodes.
If there is more than a very small chance that the cancer might have spread (based on factors such as a high PSA level or a high Gleason score), the surgeon may remove lymph nodes in the pelvis during the same operation as the removal of the prostate, which is known as a radical prostatectomy (see Surgery for Prostate Cancer).
The lymph nodes and the prostate are then sent to the lab to be looked at. The lab results are usually available several days after surgery.
A lymph node biopsy is rarely done as a separate procedure. It’s sometimes used when a radical prostatectomy isn’t planned (such as for some men who choose treatment with radiation therapy), but when it’s still important to know if the lymph nodes contain cancer.
Most often, this is done as a needle biopsy. To do this, the doctor uses an image (such as from an MRI or CT scan) to guide a long, hollow needle through the skin in the lower abdomen and into an enlarged node. The skin is numbed with local anesthesia before the needle is inserted to take a small tissue sample. The sample is then sent to the lab and looked at for cancer cells.
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Last Revised: May 31, 2023
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