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Dr. Duke K. Bahn, M.D. Publications: “Color Doppler and Tissue Harmonic Ultrasound in the Early
Detection and Staging of Prostate Cancer.” PCR INSIGHTS Vol
5, No 2: 1-10
Over the years, increases in the reported incidence of PC has been disproportionate to the changes in population demographics. The main reason for this rapid rise may be the easy access to PSA and subsequent ultrasound guided biopsies (random biopsy). Ironically though, this presents a dilemma for the patients and the clinicians. Although saving the lives of many men, some men may have so-called “latent” or “insignificant” tumors that may not need any treatment. Precise ultrasound evaluation with proper biopsy will provide us with valuable information to make a decision between watchful waiting and appropriate early intervention.
Gland Volume and Diagnosis There is much debate about how to use the diagnostic tools that we have—DRE, diagnostic PSA levels, PSA in relation to age, and gland volume—for early detection of PC. In our practice, a serum PSA> 3ng/ml, a PSA increase of 1ng/ml in a year, or abnormal DRE are the indications for TRUS. If aman’s serum PSA is greater than the predicted PSA (gland volume x 0.12), he is in a “high-risk” group forcancer. This group is subjected to careful ultrasound evaluation.
Sonographic Evaluation Because clinically relevant (>0.5 cm ) PC is nearly always hypoechoic
(black on ultrasound) compared with normal prostate tissue, we only
biopsy lesions that are visible by ultrasound. Depending on tumor architecture, the degree of hypoechogenicity
(darkness on ultrasound) ranges from obvious (nodular) to subtle
(infiltrative) changes. Thus, it is incumbent on the physician performing
the examination to be familiar with the zonal anatomy and morphologic
presentation of prostate cancer. Cancers in the outer gland (peripheral zone and central zone) and
inner gland (transition zone) have different sonographic appearances
and biologic behavior, and our threshold that defines whether to
biopsy varies depending on lesion size, location, and amount of
excess PSA.
Outer Gland Cancers Outer gland cancers have a greater propensity than inner gland
cancers for extracapsular spread because they can escape easily
through the area of anatomic weakness (entry of neurovascular bundle
branches, seminal vesicles, and apex). Fortunately, these tumors
are easy to visualize because the background tissue is more homogeneous
than that of the inner gland. Most outer gland cancers originate laterally at the entrance of
the neurovascular bundles. To visualize and sample this area, we
have found it best to perform the scanning and biopsy in the transverse
plane. When targeting outer gland lesions, we first biopsy the lesion
and than sample the accompanying neurovascular branches tangentially
along a plane just external to the prostatic capsule. A finding
of a tumor intermixed with fat definitively diagnoses histologic
stage T3 cancer. When outer gland tumors extend to the midline,
we perform a biopsy of the confluence of the seminal vesicle and
trapezoid space of the apex. The base and apex of the gland in this
area are always biopsied to aid in the evaluations of the internal
spread of cancer. Hypoechoic lesions of the outer gland should be pursued vigorously because they can escape when they are relatively small. For this reason, we generally perform a biopsy of the lesions we see on the ultrasound when excess PSA suggests that a 1cm lesion may be present (excess PSA greater 2ng/ml). If we do not find lesions in the outer gland by ultrasound, we
generally do not perform random biopsies. At this point, we shift
our attention to the inner gland (transition zone).
Inner Gland Cancers TRUS can detect cancers in the inner gland, though its sensitivity
is less than that for the outer gland. If the excess PSA is 4 to
6 ng/ml and no lesion is found in the outer gland, on must carefully
scan the inner gland for a homogeneous, poorly defined hypoechoic
lesion. We focus on the sites of anatomic weakness of the inner
gland, the anterior apex and the bladder neck. Color-flow Doppler
and (lately) Tissue Harmonic aid in the diagnosis of these more
difficult-to-see inner gland cancers because most tumors larger
than 1 cm have neovascularity (abundant vessel inside of tumor)
that is easily identifiable with these new technologies. Given the
confusing heterogeneous nature of the transition zone, color-flow
may be the only clue for the presence of cancer in a subtle hypoechoic
lesion. For the inner gland, we take a watchful waiting approach when:
(1) gland volume is greater than 50 cm; (2) no suspicious lesion
of the anterior apex or apex or bladder neck area is seen; (3) excess
PSA is less than 4 to 6 ng/ml; and (4) there is no outer gland lesion.
In general, inner gland cancers have less aggressive prognostic
factors (Gleason score and DNA ploidy) than outer gland cancers
and tend to be confined until they attain very large volumes. Therefore,
we feel that these cancers do not need to be pursued as aggressively
as outer gland cancers. To ensure that we have not overlooked a
significant tumor, we repeat serum PSA testing at 4- to 6-month
intervals. Should an upward trend continue, we re-ultrasound.
Staging Biopsy Technique The biopsy samples should include one sample from the middle of the lesion, and all routes of possible tumor escape, based on known sites of anatomic weakness. The positive neurovascular bundle biopsy has to include fat cells in contact with tumor cells or the invaded nerve sheath; a seminal vesicle biopsy should include pigmented epithelium (specific cell layer of seminal vesicle). Because the prostate gland does not contain fat, the presence of this tissue in the specimen confirms an extra prostatic invasion. We stain the rectal end of the tissue core with blue ink before sending it to the laboratory. This will allow us to determine the exact location of the tumor—an inked end signifies an outer gland (peripheral zone) tumor and a non-inked end indicates an inner gland tumor (transition zone).
Information (Risk Factors) Needed from TRUS and Staging Biopsy
This information will provide the exact local staging of the cancer and will thereby help the physician and patient choose appropriately, a further staging work-up and decide on eventual treatment options.
State-of-the-Art Ultrasound Equipment It is important to use a high-end, up-to-date ultrasound unit for an early detection and accurate staging biopsy. Power Color Doppler ultrasound demonstrates all the blood flow patterns inside the prostate. Usually, cancer tissue shows a higher blood flow (tumor neo-vascularity) than that of normal tissue. This capability will improve detection and actual tumor size measurement. The newly developed Tissue Harmonic technology improves spatial
resolution to permit visualization of smaller objects and improves
contrast resolution to discern very subtle differences in grayscale.
This is different from conventional ultrasound imaging, which sends
out a burst of sound and listens for that burst to echo off structures
in the body, (an echo that is usually weak and distorted). The time
it takes for the echo to return is proportional to the distance
the sound wave travelled. In Tissue Harmonic technology, instead
of listening for the same sound burst to return in the echo, the
ultrasound equipment listens only for a sound burst at twice the
transmitted frequency. Good ultrasound evaluation with staging (strategic)
biopsy may eliminate an unnecessary endo-rectal MRI study (that
is still an imaging study without tissue confirmation). Moreover,
it will eliminate the “guesstimation” from random biopsies.
Currently, we use the Hitachi EUB-6500 Ultrasound model. Soon, there will be further developments in TRUS that will include
contrast (IV form of micro-bubbles), enhanced Color Doppler, and
three-dimensional imaging capability.
The Role of TRUS-Guided (Not Random) Biopsies in Determining
the Internal and External Spread of PC Dr. Fred Lee and I published our data comparing sextant (random) biopsy proven PC data with our staging biopsy data on 110 men. All men came to us for a second opinion with known cancer. We performed TRUS with repeat staging biopsies on all of those men. (Seminars in Urologic Oncology, Vol 16, 1998, p 129-136.) The results were as follows:
Conclusion Current methods for determining confined PC for the individual
patient are only guesstimations. The pathological outcomes for clinically
confined PC have only a 50% probability of being correct. Today’s
patients seek answers through patient advocacy groups, Internet
surfing, and scientific literature. When one of our patients consults
with the “specialists”, he quickly surmises their uncertainty. In our hands, the use of state-of-the-art TRUS with Color Doppler and Tissue Harmonic has helped us, and others, to resolve the uncertainty of whether a cancer is or is not confined, and what other risk factors they may have. Then, and only then, do we more reliably predict a prognosis and guide our patients to those treatments that are most appropriate for them. References McNeal J: Cancer volume and site of origin of adenocarcinoma in the prostate: Relationship to local and distant spread. Hum Pathol 23:258-266, 1992 Lee F: Prostate Cancer: Transrectal ultrasound and pathology comparision. Cancer 67:1132-1142, 1991 Epstein J. Corellation of prostate cancer nuclear deoxyribonucleic acid, size, shape and gleason grade with pathological stage at radical prostatectomy. J Urol: 148:87-91, 1992 Bostwick D. Optimized microvessel density analysis improves prediction of cancer stage from prostate needle biopsies. Urology 48:47-57, 1996 Lee F. Bahn D. The role of TRUS-guided biopsies for determination of internal and external spread of prostate cancer. Seminars in Uro Oncology 16: 129-136, 1998 |
Transrectal ultrasound (TRUS) imaging has long been an essential
tool for prostate cancer (PC) diagnosis. In fact, the combination
of prostate specific antigen (PSA) testing with TRUS and digital
rectal examination (DRE) has been responsible for diagnosing most
prostate cancers in the U.S. each year. Actually, early detection
and early intervention of progressive PC may help to reduce the
30,000 prostate cancer-related deaths each year.
© 2007
Prostate Institute of America