Masatoshi Masahiro
Kudo, Hirasa,
MD MD
Hepatic Specific US with
Shusuke Tomita, Akio Todo, MD
a a
MD
a
Hitoshi
Tochio,
RT
a
Hiroshi
Kashida,
W
the recent advances in imaging technology including the development of ultrasonography (US), computed tomography (CT), single photon emission computed tomography (SPECT), and magnetic resonance (MR) imaging, the mcidental discovery of asymptomatic small liver tumors has been increasing. In Asia, where hepatocellulan carcinoma (HCC) is endemic, differentiation of benign hepatic nodules from HCC is one of the most important considerations in the fields of gastroenterology and radiology. Focal nodular hyperplasia (FNH) is a rare benign hypervascular lesion (i) that is often found incidentally and is confirmed by the postoperative pathologic study of the mesected specimen. However, since it is a benign nodule, it would be preferable to distinguish it from a malignant vascular tumor before surgery, thus avoiding unnecessary surgical intervention. A large FNH has hemodynamic and histopatho!ogic characteristics that permit accurate diagnosis with imaging modalities (2-4). However, with a small FNH, it is difficult to recognize characteristic radiologic findings, such as the “spoke-wheel sign,” with angiography. Recently we have examined four patients with histologically proved small FNH less than 3 cm in diameten. The characteristic findings of FNH were observed with dynamic contrast material-enhanced US dunITH
ing
hepatic
PATIENTS
study
the
AT.)
761.3119
Liver
Liver,
#{149} Liver
focal
nodular
neoplasms,
neoplasms.
neop!asrns,
diagnosis,
761.3114,
neoplasms,
secondary,
761.33
plasms,
US
studies,
761.12988
14, 761.321
761.124
#{149} Liver
761.321 a
Liver
a
neo-
Liver
and
Section
Service (H.T.), Minatojima-Nakamachi,
hyperplasia.
761.31
angiography.
a
1991;
179:377-382
of Castroenterology, (M.K.,
ST.,
of Abdominal Kobe
City
De-
H.K.,
M.H.,
Ultrasound
Ceneral Chuo-ku,
Hospital, 4-6, Kobe 650, Ja-
of
METHODS
FNH
smaller
(three
underwent
went
percutaneous
ing
144
of
3 cm in diameter
biopsy). had
HCC
(n
a total
113),
=
nodule
(n
nodule (n = 5), hemangioma
tastasis granuloma
(n
=
pemplastic
(n
the
one
under-
The
remain-
of
167
hepatic
hy14),
(i
(n
me-
4), and
=
1).
US was dioxide
catheter
patients
adenomatous 6), regenerative
24), lymphoma
Dynamic ing carbon
artery branch)
148
resection,
patients
nodules:
Four
than
performed microbubbles
placed
in
the
by
injectthrough
proper
hepatic
(or in the right or left hepatic after conventional superse!ective
hepatic
angiogmaphy.
catheter
tip
for
The dynamic
position US
of the
was
the
same
as for conventional angiography. Injection of carbon dioxide microbubbles was performed slowly, at a rate of approximately
2 mL/sec,
evaluation tern within early the
arterial
phase.
patients
them
period,
to hold
accurate
dioxide dioxide, saline,
blood
given
early
US
to study
breath an
for a
accurate
pattern arterial
of the phase.
microbubbles
were
mixing
10 mL
vigorously
normal
their
vascular
at the
patat the
was
dynamic
permits
of the
nodule
carbon
own
the
which
observation
by
the
Oxygen
during
to enable long
permitting
of the dynamic vascular the nodule, especially
preof
10 mL of heparinized
and 5 mL of the patient’s with use of two syringes con-
nected to each cock. The total
other by a three-way volume of microbubbles
stop-
pan. Received October 3, 1990; revision requested October 31; revision received Decernber 12; accepted December 26. Supported in part by Medical
a grant Research
ta!. Address Radiology
Division
of Medicine
AND
population.
had
pared From
infusion
From March 1989 to August 1990, dynamic US was performed on 148 patients with histologically proved hepatic tumoms. These patients constituted our
Carbon
partment
arterial
carbon dioxide microbubbles. In this article, these findings will be described, and new diagnostic criteria for FNH will be discussed and cornpared with the findings observed in HCC and other hepatic tumors.
small
terms:
a
Focal Nodular Hyperplasia: Findings at Dynamic Contrast-enhanced Carbon Dioxide Microbubbles’
Dynamic contrast material-enhanced ultrasonography (US) with intraarterial infusion of carbon dioxide microbubbles was performed for four cases of histologically proved focal nodular hyperplasia (FNH) in four patients and for i67 cases of various hepatic nodules in 144 patients. No complications due to dynamic US were observed in any of the 148 patients. All FNH nodules were less than 3 cm in diameter. Consistent specific findings of FNH were not obtained with US, computed tomography, magnetic resonance imaging, radiocolloid scanning, or angiography in the four cases of FNH. In contrast, the characteristic vascular pattern (ie, early central hypervascular supply with centrifugal filling to the periphery at the arterial phase and a uniform or lobulated dense stain at the capillary phase) was observed in all four cases of FNH with dynamic US. This vascular pattern demonstrated in FNH with dynamic US was not seen in any of the i67 hepatic nodules, including 44 small hepatocellular carcinomas less than 3 cm in diameter. Therefore, the newly developed, dynamic contrastenhanced US technique seems to be extremely sensitive and specific for diagnosing FNH and is useful in the differentiation of FNH from other hepatic tumors, especially hepatocellular carcinoma.
Index
MD
C
RSNA,
from
reprint 1991
the Grant-in-Aid of Kobe City General
requests
to M.K.
1989 for Hospi-
Abbreviations: plasia,
SPECT
FNH
HCC =
=
single
focal
hepatocel!ular photon
nodular
hyper-
carcinoma, emission
computed
to-
mography.
p7,7
injected US
was
adequately
monitoring
determined
to avoid
attenuation
with
producing
of the deeper
ma. Dynamic images corded on a videotape
strong
liver
pamenchy-
of all cases were recorder during
me-
the period prior to the injection dioxide microbubbles until the
of carbon bubbles
were
paren-
washed
chyma.
out from
The
with three
vascular
dynamic patterns,
vascularity
the liver distributions
US were depending
compared
seen
classified into on the tumor
with
the surround-
ing liver vascular,
parenchyma: hypervascular, isoand hypovascular. The vascular patterns of the four cases of FNH and 44 cases of HCC smaller than 3 cm in diame-
ter (24 patients underwent
underwent
percutaneous
precisely
biopsy)
compared.
linear-array
or 5.0-MHz studies Most scanning
20 were
A convex-
and/or
electronic
scanner
with
transducer
was used
a 3.5-
for the
(SSD-650; Aloka, Tokyo). of the 148 patients underwent CT with a 9800 scanner (GE Medi-
cal Systems,
Milwaukee)
administration imaging
before
of contrast was
imager
netom;
Siemens,
weighted with
with
operating
1.5 T (Mag-
Germany).
images
a repetition
MR
a supercon-
at
Erlangen,
spin-echo
and after
material.
performed
ducting
tamed
resection,
were
time
Ti-
ob-
of 600 msec
and an echo time of 15 msec. T2-weighted spin-echo images were obtained with a repetition time of 2,000 msec and an echo time with
of 70 msec. SPECT was performed a model 400T or Starcam 400AC
tating gamma camera (GE Medical Systems). nous
injection
and minicomputer After an intrave-
of 185 MBq
technetium-99m
phytate,
liver scintigmaphy formed.
ro-
(5 mCi) conventional
and SPECT
were
of
per-
RESULTS FNH The nadiologic findings in the four cases of FNH are listed in Table 1 All four patients had normal liver function and had no symptoms related to FNH. US showed no specific finding except in patient 4 in whom the “central scar sign” was seen. One FNH nodule was not demonstrated with CT and MR imaging, probably because of its size (patient 2). CT and MR imaging findings were not specific for FNH except in patient 4, in whom a central fibrous scar was demonstrated with MR imaging. The spoke-wheel sign was demonstrated with angiography in only one case (patient 3), and in all four cases a dense capillary stain was seen. In two of four cases of FNH, decreased opacity centrally was demonstrated on .
the
venous
In the US
phase
four
showed
cases consistent
of angiography.
of FNH, findings
dynamic of a
hypenechoic spot at 1 second after jection of carbon dioxide, centrifugal 378
a
Radiology
in-
filling pattern to the periphery at 2-5 seconds after injection, and dense staining at the late phase after injection. In one case, a 61-year-old man (patient 1) was referred for US examination to screen for liver metastasis aften an operation for scrotal Paget disease, which is a carcinoma arising in the apocnine gland epithelium. The results of blood tests showed normal liver function. Abdominal US mevealed a homogeneous hypoechoic nodule 1.8 cm in diameter in the posterosupenion area of the liver. The nodule was demonstrated as a highattenuation mass on a CT scan obtamed with contrast material enhancement. The lesion was homogeneously hypointense on Ti-weighted sequences and homogeneously hypenintense on T2-weighted sequences at MR imaging. A SPECT madiocolloid liver scan showed normal distribution of radioactivity. Hepatic angiognaphy revealed the nodule to be hypervascular with a dense stain at the capillary phase, but the spokewheel sign was not demonstrated (Fig la, ib). Dynamic contrast-enhanced US cleanly revealed the antenial supply arising from the center of the nodule at 1-2 seconds after infusion of carbon dioxide (early arterial phase). The arterial supply gradually radiated to the periphery at 3-4 seconds after infusion of carbon dioxide (arterial phase), and a hypervascular stain with sharp margin was observed at 10 seconds after infusion (capillary phase), which is diagnostic of FNH (Fig ic). The resected nodule was a well-circumscribed, but nonencapsulated, nodular mass in an otherwise normal liver. Pathologic study of the resected nodule revealed a central, stellate fibrotic scar with connective tissue septa radiating to the periphery.
The
hepatocytes
were
C .
0.
C (05’
u
bc 0
u0.
++++
0
C IL.
.L Ic
++++
Cu’ 5’
u. -
(50 5)
I
I ++
50
I
1+1,
5)0
L)3 -C 0. (0 bO
0 50 C
5) 5)
-C .
0 0.
‘5
50
Iz
I ±
0
5’
50
C
-C 50
50
a)
s
0.
0.0.
‘
(5
0 0.
00 0.0.
IZI
I C
0 I-
5) 0
C
U
5) .C
5)
C
.p
. .
0.
.
.C
C
+
C
C
z
cy-
tologically normal, and abundant dilated arterial vessels and bile duct proliferation were seen in the central scar and in the radiating septa (Fig id). In another case, a 68-year-old woman (patient 2) was referred to our hospital for further evaluation of a hepatic nodule incidentally detected with abdominal US. The results of blood tests showed normal liver function. There was no history of the patient taking oral contraceptives. Abdominal US revealed a homogeneous hypoechoic nodule 1.0 cm in diameter with a clear margin in the anterosupenior area of the right lobe of the liver. The nodule was not dernonstrated with CT or MR imaging.
‘
(0
0
5)
00
5)
0.
0. 0
.
E
(5
C
(5(5
E
uu2 OO
0
0.
0.
0
zzzz
0
0
0 5) U 0 5)
C)
‘U
bO
0
C
111+
0
lv
z
0 ia.1
0000 0. 0.
-
0.
0.
.
..‘
C)
0
50 5) 0.
‘0 0
r’4 ,-
,-‘
0i
-
‘LI
II
U
00 e
.2
-
.
:
00
‘
0
c’
IL.
IL.
5)5)
z 0.
:
5;
z*
0.
May
1991
d.
b.
a.
Plain
isec
2sec
3sec
4sec
lOsec
C.
Figure 1. (a) Hepatic capillary phase shows lobe (arrow). al radiation the capillary stain; original
angiogram
obtained
a dense
stain
during
with
a clear
Dynamic contrast-enhanced to the periphery at 2-3 seconds, phase (10 seconds), diagnostic magnification, Xi.)
Table 2 Vascular
Patterns
at Dy namic
the
arterial
margin.
US scans filling of FNH
phase
(c) Plain
with carbon of the nodule (arrow). (d)
U S of Histologic
ally Proved
Adenomatous Hyperplastic
Regenerative
shows
US scan
hypervascular
(intercostal)
tumor.
shows
dioxide microbubbles show at 4 seconds, and a uniform Cross section of the resected
H epatic
Hepatic
angiogram
obtained
hypoechoic
tumor
during
central hyperechoic spot at 1 second with gradudense stain in the nodule with sharp margin at specimen shows typical finding of FNH. (Silver
Nodules
FNH
3
6*
2
0
3
3
1
0
Isovascular
8
0
3*
0
0
0
0
0
102* 0 0 0
0 0 0 0
0 0 0 0
0 14* 0 0
5 0 16* 0
1 0 0 0
0 0 0 0
0 0 0 4*
6
5
14
24
4
1
4
supply
Total *
These
113 nodules
showed
typical
vascular
Metastasis
Granu!oma
Hypovascular Hypervascular Uniformormosaic Spottypooling Peripheral Central arterial
Hemangioma
Lymphoma
Nodule
Pattern
pattern.
HCC
Radiocolloid liver scanning was not performed. Hepatic angiography showed the nodule as hypervascular with a dense stain at the capillary
to the
phase,
not demonstrated (Fig 2a, 2b). Dynamic contrast-enhanced US clearly mevealed the arterial supply arising from the center of the nodule at the early
ule, radiating to the periphery, and no atypia in the hepatocyte, consistent with typical FNH (Fig 2d). Histopathologic examination showed abundant dilated arteries in the central fibrous
arterial
scar
Volume
but
the
spoke-wheel
phase
179
then
a
sign
gradually
Number
2
the
in the right
HCC
Vascular
Nodule
(b)
a homogeneous
was
radiating
periphery,
and
a hypervascular
stain was noted at the capillary phase (Fig 2c). Pathologic study revealed fibrous
septa
and
in the
in the
center
radiating
of the
septa.
nod-
The characteristic observed in FNH strated
with
vascular were not
dynamic
patterns demon-
contrast-en-
hanced US in any of the 1 i3 histologically proved HCCs. One hundred two HCC nodules showed a hypervascular nodules
pattern, showed
while three a hypovascular
Radiology
HCC pat-
a
379
a.
b.
d.
C.
Figure
2. the
during poechoic
arterial
(a) Hepatic angiogram capillary phase shows tumor in the right lobe
vascular
stain Xl.)
(10
seconds).
pattern (d)
of FNH Cross
obtained during the arterial hypervascular tumor with of the liver (arrow). Dynamic
(arrow)
section
(ie, central
of the
resected
phase shows hypervasculam a dense stain (arrow). (c) Plain contrast-enhanced US scans
hypervascu!ar specimen
supply) shows
arterial
phase
compared
those
arterial
radiation
of FNH.
HCCs
in FNH
vascular
HCCs arose from infiltrated to the
seconds),
finding
in 44 small
with
3). The
(1-2
typical
tumor (arrow). (b) Hepatic angiogram obtained US scan (intercostal) shows a homogeneous hywith carbon dioxide microbubbles show typical
were
(Table
supply
in a!!
the periphery and center in a willow-
branch fashion in 37 of 44 HCCs (Fig 3). In seven of 44 HCCs, the filling
pattern of the nodule determined because filling
within
phase lary
stain
HCCs,
tern,
and
eight
showed
lam pattern (Table 2). The namic patterns, especially
vascular 380
a
supply Radiology
pattern,
an isovascuhemodythe arterial
at the
early
was
and
in four. lary
the
stain
Other
(Table
Hepatic
At
the
US, a dense observed
a faint
Two
could not be of simultaneous
nodule.
of dynamic
stain
HCCs
late
demonstrated
vascular
with
dynamic
with
cu!ar
at
seconds),
original
gradually over time very late dynamic
and
dense
magnification,
US
early
arterial
(ie,
hypovasphase
and
infiltrating to the center with spotty pooling at the phase) reflecting the hemocharacteristic of extremely
blood vascular
was
observed
tumors
no
lam
in
dynamic the
The
flow
were 67%
within
the
patterns
of
peripheral (16
of
24
tumor.
metastatic
hypervascutumors),
uniform
or mosaic hypervascular in 2i% of 24 tumors), and hypovascular 13% (three of 24 tumors). None
Tumors
were
tern
slow
capi!-
(2-3 stain;
generative nodules, two were demonstrated as hypovasculam, and three were isovascular. All i4 hemangiomas showed a typical vascular pat-
in 38 of 44
3).
nodules
trichrome
capil-
showed
A!! six adenomatous
to the periphery
(Masson
hepatic
hyperplastic as hypo-
US.
Of five
tumors,
demonstrated lam supply
me-
No
other
than
a central pattern
complications
FNH,
arterial
(Table
were
(five in of the vascu-
2).
observed
May
in
1991
Plain
isec
2sec
3sec
10 sec
4sec
a. Figure 3. right lobe lar supply ion,
(a) Plain US scan (intercostal) shows a homogeneous hypoechoic tumor in the of the liver (arrow). Dynamic contrast-enhanced US scans show the arterial vascuarising from the periphery and infiltrating to the center in a willow-branch fash-
a typical
finding
ab!ed confirmation
b.
the i48 patients namic US.
who
underwent
dy-
an
essential
for the
are
ing
The pathologic findings usually distinctive and
istic.
FNH
consists
of FNH character-
of hepatocytes;
Kupffer cells; bile duct elements; a central, stellate fibrotic scar with connective tissue septa; and a specific antenial vascular structure (5-7). The madiologic diagnosis of FNH, based on the results of radiocolloid liven scanning,
hepatobiliany
scanning,
US,
CT, MR imaging, and angiography, has focused on the identification this
pathologic
(1-8).
signature
of How-
even, as seen in our presented cases, although US, CT, and MR imaging are sensitive in the detection of FNH, they have been less specific in the agnosis of FNH than scmntigraphy angiography (1-4,6,8).
The
diagnosis
tamed
if the
of FNH
can
radiocolloid
liven
reveals normal or increased the lesion (1,8). However, graphic findings for small sions
are
poor
resolution
raphy
the
not
for
use
reliable
space-occupying 2 cm in diameter only ii%-45%
if normal Volume
because
the
179
of the
Even
ability
lesions smaller was reported (9,iO). Therefore,
radiocolloid Number
#{149}
scan
of scintig-
lesions.
of SPECT,
be ob-
uptake in scintiFNH le-
capability
small
dion
uptake 2
with
to detect than even
is ob-
Tumor
procedure
differential
FNH
but
not
diagnosis
also
for
only
includ-
treatment
plan-
ning. Moreover, histologic diagnosis of the relatively small specimen obtamed at percutaneous biopsy is not always pathognomonic for FNH since it is difficult to determine if the nodule consists of normal hepatocytes on if a sampling error has occumred when normal hepatocytes are obtained. Therefore, angiography memains agnosis
of considerable of FNH. The
value in the angiographic
di-
diagnosis is based on the demonstration of the nodule’s pathologic vasculam feature; namely, the arteries enter into the center of the FNH and then fill the nodule in a centrifugal dinection as demonstrated at the three-dimensional pathologic study (7). The characteristic angiographic appearance of FNH is, therefore, a hypervascular, septated lesion with a central vascular supply or central spokewheel arterial pattern (1,2,6) and a uniform dense blush gins at the capillary
with phase
sharp man(8). How-
ever, since this typical finding can be detected in only 57%-90% of cases of large FNH (1,3), it is more difficult to detect this vascular pattern with conventional angiography in small FNH nodules,
as
(arrow).
served in hepatic lesions smaller than 2 cm in diameter, such as in patients 1-3 in our series, a definitive diagnosis of FNH cannot be made. Although percutaneous biopsy with US guidance is a very useful procedure in the differential diagnosis of hepatic tumors, angiography is still
DISCUSSION
of HCC
especially
cm in diameter phy
in three
vessel
is evident.
(b)
Resected
specimen
en-
of HCC.
those
(1,3,8). of four
less
than
3
At angiognacases
of FNH
de-
scnibed
in this
article
the
nonspecific
finding of hypervasculan stain at the capillary phase was seen; this mimics the finding with HCC. Dynamic contrast-enhanced US with arterial infusion of carbon dioxide microbubbles was first applied to the diagnosis of hepatic tumors by Matsuda and Yabuuchi (ii). This technique is a combination of US and angiography and is considered extremely sensitive in the detection of tumor vascular pattern even if the tumom is very small. Matsuda and Yabuuchi found that findings on sonograms enhanced with carbon dioxide microbubbles and obtained by means of their technique are similar to the tumor stain seen in the venous phase of angiography. Moreover, since contnast-enhanced US is sensitive in the detection of arterial vasculanity because of its tomographic imaging capability, it is superior to angiography in most
cases.
We modified two ways. First, method
their technique we modified
of preparing
the
in their
carbon
di-
oxide microbubbles to simplify the technique of dynamic contrast-enhanced US. We made carbon dioxide microbubbles by agitation of a mixtune of carbon dioxide, hepaminized normal saline, and the patient’s own blood, instead of using a solution of 20%
glucose
and
Our modified carbon dioxide sidemed solution
25%
albumin
(ii).
method of preparing microbubbles is con-
much simpler since necessary, including
any
extra hepa-
rinized normal saline, is routinely used at the conventional angiographic procedure. It was proved with microscopic
measurement
that
the
Radiology
a
381
mean size of the microbubbles made with our method was 34 rn ± 18, similar to the size of those made by Matsuda and Yabuuchi (1 1), and moreover, the flow of microbubbles can be satisfactorily regarded as the same as blood flow. Second, we evaluated arterial flow by making a videotape recording from the start of the carbon dioxide infusion until the time when carbon dioxide was washed out of the liver parenchyma, instead of evaluating only at the late phase after injection of carbon dioxide as was done by Matsuda and Yabuuchi. By observing the vascular flow from the early phase to the late phase, more accurate evaluation of the vascular pattern of the hepatic nodule is possible. With our method, early, middle, and late phases at dynamic US are assumed to correspond to the arterial, capillary, and venous phases at conventional angiography, respectively. Our method of dynamic US, therefore, permits much more precise three-dimensional evaluation of anterial flow, not only in the capillary phase but also in the arterial phase, than does conventional angiography or the contrast-enhanced US technique used by Matsuda and Yabuuchi (11). In our four cases of FNH smaller than 3 cm in diameter, the typical vascular pattern (ie, the vascular supply to the tumors arising centrally and radiating peripherally, as well as a uniform or lobulated dense hypervascular
stain
at the
capillary
phase)
was clearly demonstrated with our technique. This vascular pattern was not observed with any of the other histologically proved hepatic nodules, suggesting that these findings are specific for FNH (Table 2). Since dynamic US is an extremely sensitive method for detecting arterial vascularity within the tumor, even faint arterial flow, which is not demonstrated at conventional angiography, is expected to be detected in the case of a hypovascular FNH (i). However, further study is necessary to clarify this point. CT arteniography (12,13) is a technique that combines CT and angiography and is considered highly sensitive in the detection of small hepatic
nodules. that with
Takayasu et al (14) reported CT arteriognaphy the dilat-
ed
was
sary.
382
a
Radiology
artery
demonstrated
in the
center of nodules in 100% of cases of large FNH, and they stated that this would be a specific finding for FNH. Although, to our knowledge, there has been no other case report of small FNHs that were diagnosed with CT arteniography, CT arteniography is potentially a sensitive diagnostic tool for detecting the arterial vascular pattern of FNH as well, when dynamic CT is performed. However, since the early arterial phase, which is the most important period in evaluating the vascular pattern of FNH, lasts only a few seconds after injection in small (less than 3 cm) nodules, CT arteniography seems of limited value in the confirmation of FNH due to the inherent limitation of the relatively long scanning time compared with the real-time scanning in dynamic contrast-enhanced US. In summary, dynamic contrast-enhanced US is a highly sensitive technique in the evaluation of tumor vascular patterns especially at the early arterial phase, and is useful in the diagnosis of FNH even if the lesion size is smaller than 3 cm in diameter. The specific arterial vascular pattern for FNH with dynamic contrast-enhanced US is early central hypervascular supply with centrifugal filling to the periphery and a uniform or lobuiated dense stain at the capillary phase, and this finding is extremely characteristic for FNH (Tables 2, 3). Moreover, since dynamic US is cornplementary to the conventional angiographic procedure, dynamic US is beneficial in the following ways: (a) it is easy to perform, (b) it produces no complications, (c) it takes negligible extra time to perform (less than 10 minutes), and (d) it provides specific findings in the diagnosis of FNH. Therefore, we emphasize that dynamic contrast-enhanced US should be included routinely with the angiognaphic procedure for a suspected FNH nodule found incidentally in a patient with a normal liver, when findings at conventional angiography are not specific. If the specific vascular pattern described above is seen with dynamic US, additional wonkup or surgery is unneces-
Acknowledgments: We thank Masatoshi Makuuchi, MD, Osamu Matsui, MD, and Kazutaka Yamamoto, MD, for their critical review of the manuscript.
Kozue
We
also
Mayurni
preparation
thank
Kristin
for their of the
Coulon
secretarial
and
support
in
manuscript.
References 1.
Rogers
JV, Mack
Hepatic
focal
ography,
CT,
phy. 2.
AJR
JC,
EK,
Sanders
RC.
in focal
ular
hyperplasia
of the
liver.
J Ultrasound
1982; D,
Pointreau mas and
CC, focal CT
Bruneton
CR,
N.
adenody-
1986;
GM,
160:53-
Quint
of hepatic
LE,
focal
characterization primary
J,
Drouil!ard
Hepatic hyperplasia:
Radiology
Glazer
imaging
malignant
et a!.
nodular
hy-
and
distinction
hepatic
tumors.
1987; 148:711-715.
Knowles
DM
hyperplasia study
Hum
Pathol
Fechner
and
Il, Wolff of the
logic
cal
JN,
Vasile nodular
studs’.
58. Mattison
AJR
nod-
1:275-278.
Mathieu
from
7.
137:983-990.
Fishman
sign”
perplasia:
6.
scintigra-
“scar
MR
5.
angi-
and
sonographic
namic 4.
PC, et a!.
hyperplasia:
The Med 3.
Freeny
sonography.
1981;
Scatarige
LA,
nodular
and RE,
M.
liver:
review
of the
1976;
7:533-545.
Roehrn
JOF
pathologic nodular
liver.
literature. Angiographic
C, Adams
of focal
of the
nodular
of hepatic foAm J Surg Pathol
hyperplasia.
pathogenesis
plasia
Jr.
correlations
1977; 1:217-224. Wanless IR, Mawdsley
the
Focal
a clinicopatho-
R.
nodular
On
hyper-
Hepatology
1985;
5:1194-1200. 8.
D’Souza VJ, Focal nodular aging diol
9.
by
differing
1983;
modalities.
K, Mukai usefulness for
ceedings
of
eration
III Congress
ic liver
disease:
diology
1986;
Matsuda
12.
US contrast crobubb!es. Moss AA,
14.
of the
World
and
Takakuwa
detection
Fed-
Biology
H,
et a!. in chron-
with
SPECT.
Ra-
159:697-703.
Y, Yabuuchi
I.
Hepatic
tumors:
enhancement with CO2 miRadiology 1986; 161:701-705. Dean PB, Axe! L, et a!. Dynam-
masses
N, Miura
angiography
computed Pro-
carcinomas
ic CT of hepatic
Nakao
Ra-
1, et a!.
Medicine M,
and intraarterial 1982; 138:847-852.
13.
T, Dodo
hepatocellular
11.
NE, et a!. liver: im-
Pediatr
of emission liver scintigraphy.
of Nuclear
1982; 2866-2869. Kudo M, Hirasa Small
Watson of the
13:77-81.
Yamamoto Clinical tomography
10.
Sumner TE, hyperplasia
in
with
contrast
K, Takayasu hepatocellular
intravenous
material.
AJR
Y, et at.
CT
carcinoma.
J Comput Assist Tomogr 1983; 7:780-787. Takayasu K, Muramatsu Y, Moriyama N, et a!. Computed tomography: hepatic neoplasms hepatocellular
showing similar carcinoma.
features to Diagn Imaging
Abdomen
1990;
[Japanesej
10:22-30.
U
May
1991
Kudo, Hirasa,
MD MD
Hepatic Specific US with
Shusuke Tomita, Akio Todo, MD
a a
MD
a
Hitoshi
Tochio,
RT
a
Hiroshi
Kashida,
W
the recent advances in imaging technology including the development of ultrasonography (US), computed tomography (CT), single photon emission computed tomography (SPECT), and magnetic resonance (MR) imaging, the mcidental discovery of asymptomatic small liver tumors has been increasing. In Asia, where hepatocellulan carcinoma (HCC) is endemic, differentiation of benign hepatic nodules from HCC is one of the most important considerations in the fields of gastroenterology and radiology. Focal nodular hyperplasia (FNH) is a rare benign hypervascular lesion (i) that is often found incidentally and is confirmed by the postoperative pathologic study of the mesected specimen. However, since it is a benign nodule, it would be preferable to distinguish it from a malignant vascular tumor before surgery, thus avoiding unnecessary surgical intervention. A large FNH has hemodynamic and histopatho!ogic characteristics that permit accurate diagnosis with imaging modalities (2-4). However, with a small FNH, it is difficult to recognize characteristic radiologic findings, such as the “spoke-wheel sign,” with angiography. Recently we have examined four patients with histologically proved small FNH less than 3 cm in diameten. The characteristic findings of FNH were observed with dynamic contrast material-enhanced US dunITH
ing
hepatic
PATIENTS
study
the
AT.)
761.3119
Liver
Liver,
#{149} Liver
focal
nodular
neoplasms,
neoplasms.
neop!asrns,
diagnosis,
761.3114,
neoplasms,
secondary,
761.33
plasms,
US
studies,
761.12988
14, 761.321
761.124
#{149} Liver
761.321 a
Liver
a
neo-
Liver
and
Section
Service (H.T.), Minatojima-Nakamachi,
hyperplasia.
761.31
angiography.
a
1991;
179:377-382
of Castroenterology, (M.K.,
ST.,
of Abdominal Kobe
City
De-
H.K.,
M.H.,
Ultrasound
Ceneral Chuo-ku,
Hospital, 4-6, Kobe 650, Ja-
of
METHODS
FNH
smaller
(three
underwent
went
percutaneous
ing
144
of
3 cm in diameter
biopsy). had
HCC
(n
a total
113),
=
nodule
(n
nodule (n = 5), hemangioma
tastasis granuloma
(n
=
pemplastic
(n
the
one
under-
The
remain-
of
167
hepatic
hy14),
(i
(n
me-
4), and
=
1).
US was dioxide
catheter
patients
adenomatous 6), regenerative
24), lymphoma
Dynamic ing carbon
artery branch)
148
resection,
patients
nodules:
Four
than
performed microbubbles
placed
in
the
by
injectthrough
proper
hepatic
(or in the right or left hepatic after conventional superse!ective
hepatic
angiogmaphy.
catheter
tip
for
The dynamic
position US
of the
was
the
same
as for conventional angiography. Injection of carbon dioxide microbubbles was performed slowly, at a rate of approximately
2 mL/sec,
evaluation tern within early the
arterial
phase.
patients
them
period,
to hold
accurate
dioxide dioxide, saline,
blood
given
early
US
to study
breath an
for a
accurate
pattern arterial
of the phase.
microbubbles
were
mixing
10 mL
vigorously
normal
their
vascular
at the
patat the
was
dynamic
permits
of the
nodule
carbon
own
the
which
observation
by
the
Oxygen
during
to enable long
permitting
of the dynamic vascular the nodule, especially
preof
10 mL of heparinized
and 5 mL of the patient’s with use of two syringes con-
nected to each cock. The total
other by a three-way volume of microbubbles
stop-
pan. Received October 3, 1990; revision requested October 31; revision received Decernber 12; accepted December 26. Supported in part by Medical
a grant Research
ta!. Address Radiology
Division
of Medicine
AND
population.
had
pared From
infusion
From March 1989 to August 1990, dynamic US was performed on 148 patients with histologically proved hepatic tumoms. These patients constituted our
Carbon
partment
arterial
carbon dioxide microbubbles. In this article, these findings will be described, and new diagnostic criteria for FNH will be discussed and cornpared with the findings observed in HCC and other hepatic tumors.
small
terms:
a
Focal Nodular Hyperplasia: Findings at Dynamic Contrast-enhanced Carbon Dioxide Microbubbles’
Dynamic contrast material-enhanced ultrasonography (US) with intraarterial infusion of carbon dioxide microbubbles was performed for four cases of histologically proved focal nodular hyperplasia (FNH) in four patients and for i67 cases of various hepatic nodules in 144 patients. No complications due to dynamic US were observed in any of the 148 patients. All FNH nodules were less than 3 cm in diameter. Consistent specific findings of FNH were not obtained with US, computed tomography, magnetic resonance imaging, radiocolloid scanning, or angiography in the four cases of FNH. In contrast, the characteristic vascular pattern (ie, early central hypervascular supply with centrifugal filling to the periphery at the arterial phase and a uniform or lobulated dense stain at the capillary phase) was observed in all four cases of FNH with dynamic US. This vascular pattern demonstrated in FNH with dynamic US was not seen in any of the i67 hepatic nodules, including 44 small hepatocellular carcinomas less than 3 cm in diameter. Therefore, the newly developed, dynamic contrastenhanced US technique seems to be extremely sensitive and specific for diagnosing FNH and is useful in the differentiation of FNH from other hepatic tumors, especially hepatocellular carcinoma.
Index
MD
C
RSNA,
from
reprint 1991
the Grant-in-Aid of Kobe City General
requests
to M.K.
1989 for Hospi-
Abbreviations: plasia,
SPECT
FNH
HCC =
=
single
focal
hepatocel!ular photon
nodular
hyper-
carcinoma, emission
computed
to-
mography.
p7,7
injected US
was
adequately
monitoring
determined
to avoid
attenuation
with
producing
of the deeper
ma. Dynamic images corded on a videotape
strong
liver
pamenchy-
of all cases were recorder during
me-
the period prior to the injection dioxide microbubbles until the
of carbon bubbles
were
paren-
washed
chyma.
out from
The
with three
vascular
dynamic patterns,
vascularity
the liver distributions
US were depending
compared
seen
classified into on the tumor
with
the surround-
ing liver vascular,
parenchyma: hypervascular, isoand hypovascular. The vascular patterns of the four cases of FNH and 44 cases of HCC smaller than 3 cm in diame-
ter (24 patients underwent
underwent
percutaneous
precisely
biopsy)
compared.
linear-array
or 5.0-MHz studies Most scanning
20 were
A convex-
and/or
electronic
scanner
with
transducer
was used
a 3.5-
for the
(SSD-650; Aloka, Tokyo). of the 148 patients underwent CT with a 9800 scanner (GE Medi-
cal Systems,
Milwaukee)
administration imaging
before
of contrast was
imager
netom;
Siemens,
weighted with
with
operating
1.5 T (Mag-
Germany).
images
a repetition
MR
a supercon-
at
Erlangen,
spin-echo
and after
material.
performed
ducting
tamed
resection,
were
time
Ti-
ob-
of 600 msec
and an echo time of 15 msec. T2-weighted spin-echo images were obtained with a repetition time of 2,000 msec and an echo time with
of 70 msec. SPECT was performed a model 400T or Starcam 400AC
tating gamma camera (GE Medical Systems). nous
injection
and minicomputer After an intrave-
of 185 MBq
technetium-99m
phytate,
liver scintigmaphy formed.
ro-
(5 mCi) conventional
and SPECT
were
of
per-
RESULTS FNH The nadiologic findings in the four cases of FNH are listed in Table 1 All four patients had normal liver function and had no symptoms related to FNH. US showed no specific finding except in patient 4 in whom the “central scar sign” was seen. One FNH nodule was not demonstrated with CT and MR imaging, probably because of its size (patient 2). CT and MR imaging findings were not specific for FNH except in patient 4, in whom a central fibrous scar was demonstrated with MR imaging. The spoke-wheel sign was demonstrated with angiography in only one case (patient 3), and in all four cases a dense capillary stain was seen. In two of four cases of FNH, decreased opacity centrally was demonstrated on .
the
venous
In the US
phase
four
showed
cases consistent
of angiography.
of FNH, findings
dynamic of a
hypenechoic spot at 1 second after jection of carbon dioxide, centrifugal 378
a
Radiology
in-
filling pattern to the periphery at 2-5 seconds after injection, and dense staining at the late phase after injection. In one case, a 61-year-old man (patient 1) was referred for US examination to screen for liver metastasis aften an operation for scrotal Paget disease, which is a carcinoma arising in the apocnine gland epithelium. The results of blood tests showed normal liver function. Abdominal US mevealed a homogeneous hypoechoic nodule 1.8 cm in diameter in the posterosupenion area of the liver. The nodule was demonstrated as a highattenuation mass on a CT scan obtamed with contrast material enhancement. The lesion was homogeneously hypointense on Ti-weighted sequences and homogeneously hypenintense on T2-weighted sequences at MR imaging. A SPECT madiocolloid liver scan showed normal distribution of radioactivity. Hepatic angiognaphy revealed the nodule to be hypervascular with a dense stain at the capillary phase, but the spokewheel sign was not demonstrated (Fig la, ib). Dynamic contrast-enhanced US cleanly revealed the antenial supply arising from the center of the nodule at 1-2 seconds after infusion of carbon dioxide (early arterial phase). The arterial supply gradually radiated to the periphery at 3-4 seconds after infusion of carbon dioxide (arterial phase), and a hypervascular stain with sharp margin was observed at 10 seconds after infusion (capillary phase), which is diagnostic of FNH (Fig ic). The resected nodule was a well-circumscribed, but nonencapsulated, nodular mass in an otherwise normal liver. Pathologic study of the resected nodule revealed a central, stellate fibrotic scar with connective tissue septa radiating to the periphery.
The
hepatocytes
were
C .
0.
C (05’
u
bc 0
u0.
++++
0
C IL.
.L Ic
++++
Cu’ 5’
u. -
(50 5)
I
I ++
50
I
1+1,
5)0
L)3 -C 0. (0 bO
0 50 C
5) 5)
-C .
0 0.
‘5
50
Iz
I ±
0
5’
50
C
-C 50
50
a)
s
0.
0.0.
‘
(5
0 0.
00 0.0.
IZI
I C
0 I-
5) 0
C
U
5) .C
5)
C
.p
. .
0.
.
.C
C
+
C
C
z
cy-
tologically normal, and abundant dilated arterial vessels and bile duct proliferation were seen in the central scar and in the radiating septa (Fig id). In another case, a 68-year-old woman (patient 2) was referred to our hospital for further evaluation of a hepatic nodule incidentally detected with abdominal US. The results of blood tests showed normal liver function. There was no history of the patient taking oral contraceptives. Abdominal US revealed a homogeneous hypoechoic nodule 1.0 cm in diameter with a clear margin in the anterosupenior area of the right lobe of the liver. The nodule was not dernonstrated with CT or MR imaging.
‘
(0
0
5)
00
5)
0.
0. 0
.
E
(5
C
(5(5
E
uu2 OO
0
0.
0.
0
zzzz
0
0
0 5) U 0 5)
C)
‘U
bO
0
C
111+
0
lv
z
0 ia.1
0000 0. 0.
-
0.
0.
.
..‘
C)
0
50 5) 0.
‘0 0
r’4 ,-
,-‘
0i
-
‘LI
II
U
00 e
.2
-
.
:
00
‘
0
c’
IL.
IL.
5)5)
z 0.
:
5;
z*
0.
May
1991
d.
b.
a.
Plain
isec
2sec
3sec
4sec
lOsec
C.
Figure 1. (a) Hepatic capillary phase shows lobe (arrow). al radiation the capillary stain; original
angiogram
obtained
a dense
stain
during
with
a clear
Dynamic contrast-enhanced to the periphery at 2-3 seconds, phase (10 seconds), diagnostic magnification, Xi.)
Table 2 Vascular
Patterns
at Dy namic
the
arterial
margin.
US scans filling of FNH
phase
(c) Plain
with carbon of the nodule (arrow). (d)
U S of Histologic
ally Proved
Adenomatous Hyperplastic
Regenerative
shows
US scan
hypervascular
(intercostal)
tumor.
shows
dioxide microbubbles show at 4 seconds, and a uniform Cross section of the resected
H epatic
Hepatic
angiogram
obtained
hypoechoic
tumor
during
central hyperechoic spot at 1 second with gradudense stain in the nodule with sharp margin at specimen shows typical finding of FNH. (Silver
Nodules
FNH
3
6*
2
0
3
3
1
0
Isovascular
8
0
3*
0
0
0
0
0
102* 0 0 0
0 0 0 0
0 0 0 0
0 14* 0 0
5 0 16* 0
1 0 0 0
0 0 0 0
0 0 0 4*
6
5
14
24
4
1
4
supply
Total *
These
113 nodules
showed
typical
vascular
Metastasis
Granu!oma
Hypovascular Hypervascular Uniformormosaic Spottypooling Peripheral Central arterial
Hemangioma
Lymphoma
Nodule
Pattern
pattern.
HCC
Radiocolloid liver scanning was not performed. Hepatic angiography showed the nodule as hypervascular with a dense stain at the capillary
to the
phase,
not demonstrated (Fig 2a, 2b). Dynamic contrast-enhanced US clearly mevealed the arterial supply arising from the center of the nodule at the early
ule, radiating to the periphery, and no atypia in the hepatocyte, consistent with typical FNH (Fig 2d). Histopathologic examination showed abundant dilated arteries in the central fibrous
arterial
scar
Volume
but
the
spoke-wheel
phase
179
then
a
sign
gradually
Number
2
the
in the right
HCC
Vascular
Nodule
(b)
a homogeneous
was
radiating
periphery,
and
a hypervascular
stain was noted at the capillary phase (Fig 2c). Pathologic study revealed fibrous
septa
and
in the
in the
center
radiating
of the
septa.
nod-
The characteristic observed in FNH strated
with
vascular were not
dynamic
patterns demon-
contrast-en-
hanced US in any of the 1 i3 histologically proved HCCs. One hundred two HCC nodules showed a hypervascular nodules
pattern, showed
while three a hypovascular
Radiology
HCC pat-
a
379
a.
b.
d.
C.
Figure
2. the
during poechoic
arterial
(a) Hepatic angiogram capillary phase shows tumor in the right lobe
vascular
stain Xl.)
(10
seconds).
pattern (d)
of FNH Cross
obtained during the arterial hypervascular tumor with of the liver (arrow). Dynamic
(arrow)
section
(ie, central
of the
resected
phase shows hypervasculam a dense stain (arrow). (c) Plain contrast-enhanced US scans
hypervascu!ar specimen
supply) shows
arterial
phase
compared
those
arterial
radiation
of FNH.
HCCs
in FNH
vascular
HCCs arose from infiltrated to the
seconds),
finding
in 44 small
with
3). The
(1-2
typical
tumor (arrow). (b) Hepatic angiogram obtained US scan (intercostal) shows a homogeneous hywith carbon dioxide microbubbles show typical
were
(Table
supply
in a!!
the periphery and center in a willow-
branch fashion in 37 of 44 HCCs (Fig 3). In seven of 44 HCCs, the filling
pattern of the nodule determined because filling
within
phase lary
stain
HCCs,
tern,
and
eight
showed
lam pattern (Table 2). The namic patterns, especially
vascular 380
a
supply Radiology
pattern,
an isovascuhemodythe arterial
at the
early
was
and
in four. lary
the
stain
Other
(Table
Hepatic
At
the
US, a dense observed
a faint
Two
could not be of simultaneous
nodule.
of dynamic
stain
HCCs
late
demonstrated
vascular
with
dynamic
with
cu!ar
at
seconds),
original
gradually over time very late dynamic
and
dense
magnification,
US
early
arterial
(ie,
hypovasphase
and
infiltrating to the center with spotty pooling at the phase) reflecting the hemocharacteristic of extremely
blood vascular
was
observed
tumors
no
lam
in
dynamic the
The
flow
were 67%
within
the
patterns
of
peripheral (16
of
24
tumor.
metastatic
hypervascutumors),
uniform
or mosaic hypervascular in 2i% of 24 tumors), and hypovascular 13% (three of 24 tumors). None
Tumors
were
tern
slow
capi!-
(2-3 stain;
generative nodules, two were demonstrated as hypovasculam, and three were isovascular. All i4 hemangiomas showed a typical vascular pat-
in 38 of 44
3).
nodules
trichrome
capil-
showed
A!! six adenomatous
to the periphery
(Masson
hepatic
hyperplastic as hypo-
US.
Of five
tumors,
demonstrated lam supply
me-
No
other
than
a central pattern
complications
FNH,
arterial
(Table
were
(five in of the vascu-
2).
observed
May
in
1991
Plain
isec
2sec
3sec
10 sec
4sec
a. Figure 3. right lobe lar supply ion,
(a) Plain US scan (intercostal) shows a homogeneous hypoechoic tumor in the of the liver (arrow). Dynamic contrast-enhanced US scans show the arterial vascuarising from the periphery and infiltrating to the center in a willow-branch fash-
a typical
finding
ab!ed confirmation
b.
the i48 patients namic US.
who
underwent
dy-
an
essential
for the
are
ing
The pathologic findings usually distinctive and
istic.
FNH
consists
of FNH character-
of hepatocytes;
Kupffer cells; bile duct elements; a central, stellate fibrotic scar with connective tissue septa; and a specific antenial vascular structure (5-7). The madiologic diagnosis of FNH, based on the results of radiocolloid liven scanning,
hepatobiliany
scanning,
US,
CT, MR imaging, and angiography, has focused on the identification this
pathologic
(1-8).
signature
of How-
even, as seen in our presented cases, although US, CT, and MR imaging are sensitive in the detection of FNH, they have been less specific in the agnosis of FNH than scmntigraphy angiography (1-4,6,8).
The
diagnosis
tamed
if the
of FNH
can
radiocolloid
liven
reveals normal or increased the lesion (1,8). However, graphic findings for small sions
are
poor
resolution
raphy
the
not
for
use
reliable
space-occupying 2 cm in diameter only ii%-45%
if normal Volume
because
the
179
of the
Even
ability
lesions smaller was reported (9,iO). Therefore,
radiocolloid Number
#{149}
scan
of scintig-
lesions.
of SPECT,
be ob-
uptake in scintiFNH le-
capability
small
dion
uptake 2
with
to detect than even
is ob-
Tumor
procedure
differential
FNH
but
not
diagnosis
also
for
only
includ-
treatment
plan-
ning. Moreover, histologic diagnosis of the relatively small specimen obtamed at percutaneous biopsy is not always pathognomonic for FNH since it is difficult to determine if the nodule consists of normal hepatocytes on if a sampling error has occumred when normal hepatocytes are obtained. Therefore, angiography memains agnosis
of considerable of FNH. The
value in the angiographic
di-
diagnosis is based on the demonstration of the nodule’s pathologic vasculam feature; namely, the arteries enter into the center of the FNH and then fill the nodule in a centrifugal dinection as demonstrated at the three-dimensional pathologic study (7). The characteristic angiographic appearance of FNH is, therefore, a hypervascular, septated lesion with a central vascular supply or central spokewheel arterial pattern (1,2,6) and a uniform dense blush gins at the capillary
with phase
sharp man(8). How-
ever, since this typical finding can be detected in only 57%-90% of cases of large FNH (1,3), it is more difficult to detect this vascular pattern with conventional angiography in small FNH nodules,
as
(arrow).
served in hepatic lesions smaller than 2 cm in diameter, such as in patients 1-3 in our series, a definitive diagnosis of FNH cannot be made. Although percutaneous biopsy with US guidance is a very useful procedure in the differential diagnosis of hepatic tumors, angiography is still
DISCUSSION
of HCC
especially
cm in diameter phy
in three
vessel
is evident.
(b)
Resected
specimen
en-
of HCC.
those
(1,3,8). of four
less
than
3
At angiognacases
of FNH
de-
scnibed
in this
article
the
nonspecific
finding of hypervasculan stain at the capillary phase was seen; this mimics the finding with HCC. Dynamic contrast-enhanced US with arterial infusion of carbon dioxide microbubbles was first applied to the diagnosis of hepatic tumors by Matsuda and Yabuuchi (ii). This technique is a combination of US and angiography and is considered extremely sensitive in the detection of tumor vascular pattern even if the tumom is very small. Matsuda and Yabuuchi found that findings on sonograms enhanced with carbon dioxide microbubbles and obtained by means of their technique are similar to the tumor stain seen in the venous phase of angiography. Moreover, since contnast-enhanced US is sensitive in the detection of arterial vasculanity because of its tomographic imaging capability, it is superior to angiography in most
cases.
We modified two ways. First, method
their technique we modified
of preparing
the
in their
carbon
di-
oxide microbubbles to simplify the technique of dynamic contrast-enhanced US. We made carbon dioxide microbubbles by agitation of a mixtune of carbon dioxide, hepaminized normal saline, and the patient’s own blood, instead of using a solution of 20%
glucose
and
Our modified carbon dioxide sidemed solution
25%
albumin
(ii).
method of preparing microbubbles is con-
much simpler since necessary, including
any
extra hepa-
rinized normal saline, is routinely used at the conventional angiographic procedure. It was proved with microscopic
measurement
that
the
Radiology
a
381
mean size of the microbubbles made with our method was 34 rn ± 18, similar to the size of those made by Matsuda and Yabuuchi (1 1), and moreover, the flow of microbubbles can be satisfactorily regarded as the same as blood flow. Second, we evaluated arterial flow by making a videotape recording from the start of the carbon dioxide infusion until the time when carbon dioxide was washed out of the liver parenchyma, instead of evaluating only at the late phase after injection of carbon dioxide as was done by Matsuda and Yabuuchi. By observing the vascular flow from the early phase to the late phase, more accurate evaluation of the vascular pattern of the hepatic nodule is possible. With our method, early, middle, and late phases at dynamic US are assumed to correspond to the arterial, capillary, and venous phases at conventional angiography, respectively. Our method of dynamic US, therefore, permits much more precise three-dimensional evaluation of anterial flow, not only in the capillary phase but also in the arterial phase, than does conventional angiography or the contrast-enhanced US technique used by Matsuda and Yabuuchi (11). In our four cases of FNH smaller than 3 cm in diameter, the typical vascular pattern (ie, the vascular supply to the tumors arising centrally and radiating peripherally, as well as a uniform or lobulated dense hypervascular
stain
at the
capillary
phase)
was clearly demonstrated with our technique. This vascular pattern was not observed with any of the other histologically proved hepatic nodules, suggesting that these findings are specific for FNH (Table 2). Since dynamic US is an extremely sensitive method for detecting arterial vascularity within the tumor, even faint arterial flow, which is not demonstrated at conventional angiography, is expected to be detected in the case of a hypovascular FNH (i). However, further study is necessary to clarify this point. CT arteniography (12,13) is a technique that combines CT and angiography and is considered highly sensitive in the detection of small hepatic
nodules. that with
Takayasu et al (14) reported CT arteriognaphy the dilat-
ed
was
sary.
382
a
Radiology
artery
demonstrated
in the
center of nodules in 100% of cases of large FNH, and they stated that this would be a specific finding for FNH. Although, to our knowledge, there has been no other case report of small FNHs that were diagnosed with CT arteniography, CT arteniography is potentially a sensitive diagnostic tool for detecting the arterial vascular pattern of FNH as well, when dynamic CT is performed. However, since the early arterial phase, which is the most important period in evaluating the vascular pattern of FNH, lasts only a few seconds after injection in small (less than 3 cm) nodules, CT arteniography seems of limited value in the confirmation of FNH due to the inherent limitation of the relatively long scanning time compared with the real-time scanning in dynamic contrast-enhanced US. In summary, dynamic contrast-enhanced US is a highly sensitive technique in the evaluation of tumor vascular patterns especially at the early arterial phase, and is useful in the diagnosis of FNH even if the lesion size is smaller than 3 cm in diameter. The specific arterial vascular pattern for FNH with dynamic contrast-enhanced US is early central hypervascular supply with centrifugal filling to the periphery and a uniform or lobuiated dense stain at the capillary phase, and this finding is extremely characteristic for FNH (Tables 2, 3). Moreover, since dynamic US is cornplementary to the conventional angiographic procedure, dynamic US is beneficial in the following ways: (a) it is easy to perform, (b) it produces no complications, (c) it takes negligible extra time to perform (less than 10 minutes), and (d) it provides specific findings in the diagnosis of FNH. Therefore, we emphasize that dynamic contrast-enhanced US should be included routinely with the angiognaphic procedure for a suspected FNH nodule found incidentally in a patient with a normal liver, when findings at conventional angiography are not specific. If the specific vascular pattern described above is seen with dynamic US, additional wonkup or surgery is unneces-
Acknowledgments: We thank Masatoshi Makuuchi, MD, Osamu Matsui, MD, and Kazutaka Yamamoto, MD, for their critical review of the manuscript.
Kozue
We
also
Mayurni
preparation
thank
Kristin
for their of the
Coulon
secretarial
and
support
in
manuscript.
References 1.
Rogers
JV, Mack
Hepatic
focal
ography,
CT,
phy. 2.
AJR
JC,
EK,
Sanders
RC.
in focal
ular
hyperplasia
of the
liver.
J Ultrasound
1982; D,
Pointreau mas and
CC, focal CT
Bruneton
CR,
N.
adenody-
1986;
GM,
160:53-
Quint
of hepatic
LE,
focal
characterization primary
J,
Drouil!ard
Hepatic hyperplasia:
Radiology
Glazer
imaging
malignant
et a!.
nodular
hy-
and
distinction
hepatic
tumors.
1987; 148:711-715.
Knowles
DM
hyperplasia study
Hum
Pathol
Fechner
and
Il, Wolff of the
logic
cal
JN,
Vasile nodular
studs’.
58. Mattison
AJR
nod-
1:275-278.
Mathieu
from
7.
137:983-990.
Fishman
sign”
perplasia:
6.
scintigra-
“scar
MR
5.
angi-
and
sonographic
namic 4.
PC, et a!.
hyperplasia:
The Med 3.
Freeny
sonography.
1981;
Scatarige
LA,
nodular
and RE,
M.
liver:
review
of the
1976;
7:533-545.
Roehrn
JOF
pathologic nodular
liver.
literature. Angiographic
C, Adams
of focal
of the
nodular
of hepatic foAm J Surg Pathol
hyperplasia.
pathogenesis
plasia
Jr.
correlations
1977; 1:217-224. Wanless IR, Mawdsley
the
Focal
a clinicopatho-
R.
nodular
On
hyper-
Hepatology
1985;
5:1194-1200. 8.
D’Souza VJ, Focal nodular aging diol
9.
by
differing
1983;
modalities.
K, Mukai usefulness for
ceedings
of
eration
III Congress
ic liver
disease:
diology
1986;
Matsuda
12.
US contrast crobubb!es. Moss AA,
14.
of the
World
and
Takakuwa
detection
Fed-
Biology
H,
et a!. in chron-
with
SPECT.
Ra-
159:697-703.
Y, Yabuuchi
I.
Hepatic
tumors:
enhancement with CO2 miRadiology 1986; 161:701-705. Dean PB, Axe! L, et a!. Dynam-
masses
N, Miura
angiography
computed Pro-
carcinomas
ic CT of hepatic
Nakao
Ra-
1, et a!.
Medicine M,
and intraarterial 1982; 138:847-852.
13.
T, Dodo
hepatocellular
11.
NE, et a!. liver: im-
Pediatr
of emission liver scintigraphy.
of Nuclear
1982; 2866-2869. Kudo M, Hirasa Small
Watson of the
13:77-81.
Yamamoto Clinical tomography
10.
Sumner TE, hyperplasia
in
with
contrast
K, Takayasu hepatocellular
intravenous
material.
AJR
Y, et at.
CT
carcinoma.
J Comput Assist Tomogr 1983; 7:780-787. Takayasu K, Muramatsu Y, Moriyama N, et a!. Computed tomography: hepatic neoplasms hepatocellular
showing similar carcinoma.
features to Diagn Imaging
Abdomen
1990;
[Japanesej
10:22-30.
U
May
1991
