2005;46:1455-1459.J Nucl Med. 
  
Amy Tran, Betty S. Pio, Bahareh Khatibi, Johannes Czernin, Michael E. Phelps and Daniel H.S. Silverman
  
Outer-Quadrant Tumors: Comparison with Long-Term Clinical Outcome 

F-FDG PET for Staging Breast Cancer in Patients with Inner-Quadrant Versus18

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18F-FDG PET for Staging Breast Cancer
in Patients with Inner-Quadrant Versus
Outer-Quadrant Tumors: Comparison
with Long-Term Clinical Outcome
Amy Tran, BS; Betty S. Pio, MS; Bahareh Khatibi, BS; Johannes Czernin, MD; Michael E. Phelps, PhD; and
Daniel H.S. Silverman, MD, PhD

Department of Molecular and Medical Pharmacology, David Geffen School of Medicine, UCLA, Los Angeles, California

Extraaxillary metastases (i.e., in the absence of axillary involve-
ment) are more likely to develop in patients with inner-quadrant (IQ)
breast cancer than in patients with outer-quadrant (OQ) primary
tumors. The relative difficulty of identifying extraaxillary metastases
may lead to understaging of cancer in these patients. This study
examined whether 18F-FDG PET findings were differentially asso-
ciated with the location of primary tumors, and with long-term
prognosis, in IQ and OQ patients. Methods: Follow-up data were
obtained for 141 patients whose breast cancer was staged by PET
and who were documented to have IQ (n � 42) or OQ (n � 99)
primaries. Results were stratified according to PET findings con-
sistent with different metastatic patterns. Data were further ana-
lyzed with respect to disease outcome after a mean 3-y follow-up
period. Results: Among IQ patients, progressive disease was
identified in 26.1%, compared with 13.1% of OQ patients, for a
relative risk (RR) of 2.0. Of patients with PET findings of isolated
extraaxillary metastases, 36.1% had progressive disease, com-
pared with 10.7% of other patients (RR � 3.4), and 61.9% of IQ
patients had isolated extraaxillary metastases identified on PET,
compared with 10.1% of OQ patients (RR � 6.1). Conclusion: IQ
patients demonstrated a 6-fold greater frequency of PET findings
of isolated extraaxillary metastasis, and such findings were asso-
ciated with triple the risk for disease progression. Patients with IQ
tumors could be vulnerable to understaging with conventional
staging approaches and may particularly benefit from PET during
the staging process.

Key Words: breast cancer; PET; FDG

J Nucl Med 2005; 46:1455–1459

In the United States, breast cancer ranks second among
cancer deaths in women (1), and patients with primary
lesions in the inner quadrant (IQ) of the breast have a higher

mortality rate than patients with primary lesions in the outer
quadrant (OQ) (2–5). IQ primary tumors, which are located
in the medial region of the body, have a higher propensity
to metastasize to extraaxillary sites without metastasizing to
axillary regions (2,6). Because IQ patients have a greater
incidence of these isolated metastases, their disease is un-
derstaged more frequently.

The higher mortality rate for IQ patients may in part be
due to understaging and subsequent undertreating associ-
ated with the difficulty of detecting isolated extraaxillary
metastases using conventional imaging methods. Several
recent studies comparing 18F-FDG PET and conventional
diagnostic techniques have reported that PET is more sen-
sitive in detecting metastatic lesions, in particular extraax-
illary metastases (7–14), but that PET is less sensitive in
identifying axillary lymph node involvement (15–20).

The ability of PET to detect extraaxillary metastases
suggests that patients with IQ primary tumors may benefit
from the use of PET for staging and restaging evaluations.
Recognition of extraaxillary processes early during the
course of disease could have profound implications on the
future management of, and administration of therapy to,
breast cancer patients. Thus, in this study, we set out to
evaluate the prognostic value of 18F-FDG PET by looking at
the relationship between PET findings of hypermetabolic
foci and the clinical outcome of patients with IQ versus OQ
primary breast tumors.

MATERIALS AND METHODS

Patient Population
The study population (n � 150) included all breast cancer

patients who were referred to our facility for 18F-FDG PET staging
examinations through December 2001, for whom documentation
allowing retrospective assignment of primary tumors to OQ or IQ
locations was retrievable, and for whom longitudinal information
on disease assessment was available. Patients with records indi-
cating primary tumors in both IQ and OQ (n � 4) locations or in
the areolar region (n � 5) were excluded from this analysis. Data
pertaining to each patient’s initial evaluation and subsequent

Received Dec. 3, 2005; revision accepted May 18, 2005.
For correspondence or reprints contact: Daniel H.S. Silverman, MD, PhD,

Department of Molecular and Medical Pharmacology, University of California,
Los Angeles, 10833 LeConte Ave., Center for Health Sciences, AR-144, Los
Angeles, CA 90095-6942.

E-mail: dsilver@ucla.edu
Guest Editor: Dominique Delbeke, MD, PhD

PET AND INNER-QUADRANT BREAST CANCER • Tran et al. 1455

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course of therapy were used through a protocol approved by the
Office for Protection of Research Subjects of the UCLA Institu-
tional Review Board.

Clinical Data
We obtained clinical data on each patient through review of

inpatient and outpatient medical records and through a written
study questionnaire completed by the patient’s referring or most
recent managing oncologist. The clinical data, which included
treatment history, stage of disease, recent tumor marker values,
known tumor sites, date of most recent examination, and current
disease status, allowed the disease to be classified as progressive or
nonprogressive. If the disease was nonprogressive, we required a
minimum of 10 mo of clinical follow-up data documenting that the
patient’s condition was stable.

PET Imaging
Patients fasted for at least 6 h before intravenous injection of

555 MBq (15 mCi) of 18F-FDG. Whole-body PET emission data
were obtained using Siemens ECAT EXACT HR or HR� scan-
ners (CTI PET Systems) for 6 min per bed position with 2-dimen-
sional acquisition. PET scans were read by the nuclear medicine
physicians on clinical service at the time of acquisition, who were
unaware of this study and, in most cases, of the quadrant of the
primary tumor.

Statistical Analysis
Statistical analysis of risk ratios was performed on collected

data organized into a 2 � 2 table. Significant differences in
continuous variables between each stratum of n patients were
assessed by a 2-sided unpaired t test. Within each group, the
strength of the association of PET findings with clinical outcome
was assessed by the �2 test. Ninety-five percent confidence inter-
vals (CIs) for the probability (p) of each stratum of n subjects were
calculated as the product of 1.96 and the square root of p(1 � p)/n.
Calculation of relative risk (RR) and odds ratios was based on
methods described by Gordis, and calculation of CIs was based on
methods described by Armitage and Berry (21,22).

RESULTS

Distribution of Hypermetabolic Foci
Review of medical records revealed that more than one

fourth of patients had primary tumors in the IQ (28%). The
remaining patients had primary tumors in the OQ (66%), in
both the IQ and the OQ (3%), or in the areolar region (3%).
Review of original PET reports allowed stratification of OQ
and IQ patients into subgroups based on whether hyper-

metabolic foci believed to be consistent with metastatic
disease were found. Seventy-two examinations were for
initial staging, and 69 were for restaging after one or more
courses of therapy. For women who underwent multiple
PET examinations, the scan obtained at the time closest to
initial diagnosis was used. During follow-up after PET, 108
of the 141 patients received systemic treatment either as
adjuvant therapy (n � 68) or for metastatic disease (n �
40). Among those patients, 26% had histories of IQ (n �
28) and 74% had histories of OQ (n � 80) primary tumors,
similar to the distribution in the study population overall.

The mean ages of IQ (56 � 10 y) and OQ (57 � 14 y)
patients were similar. On the basis of findings noted on the
18F-FDG PET reports, patients were stratified into 1 of 4
groups: extraaxillary metastasis only, axillary metastasis
only, both extraaxillary and axillary metastases, or no me-
tastasis (Figs. 1 and 2). Some patients had multiple sites of
metastasis. Extraaxillary tumor sites included the mediasti-
nal or internal mammary nodes (n � 15), supraclavicular
region (n � 10), brain (n � 4), osseous processes such as
spine and joints (n � 12), liver (n � 9), and lung or pleural
cavity (n � 18). In IQ patients with isolated extraaxillary
disease, tumor sites were the brain (n � 4), supraclavicular
region (n � 5), mediastinal or internal mammary nodes
(n � 1), osseous processes (n � 10), liver (n � 4), and lung
or pleura (n � 10). In OQ patients with isolated extraaxil-
lary disease, tumor sites were the supraclavicular region
(n � 1), mediastinal or internal mammary nodes (n � 3),
osseous processes (n � 2), liver (n � 2), and lung or pleura
(n � 3).

Within the group of OQ patients, 10.1% (n � 10) had
extraaxillary metastases, 50.5% (n � 50) had axillary me-
tastases, 23.2% (n � 23) had both extraaxillary and axillary
metastases, and 16.2% (n � 16) had no metastases identi-
fied on PET (Fig. 1A). For IQ patients, 61.9% (n � 26) had
extraaxillary metastases, 4.8% (n � 2) had axillary metas-
tases, 11.9% (n � 5) had both extraaxillary and axillary
metastases, and 21.4% (n � 9) had no identified metastases
(Fig. 1B). The IQ group thus exhibited a higher frequency
of PET findings for isolated extraaxillary metastasis,
whereas the OQ group exhibited a higher frequency of PET
findings for axillary metastasis only, and the RR for finding
isolated extraaxillary metastases in IQ (61.9%; 95% CI,

FIGURE 1. (A) Distribution of PET find-
ings of hypermetabolic foci for 99 OQ pa-
tients. (B) Distribution of PET findings of
hypermetabolic foci for 42 IQ patients.
EAx � extraaxillary; Ax � axillary; both �
axillary and extraaxillary; none � no metas-
tases.

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48%–76%) versus OQ (10.1%; 95% CI, 0%–33%) patients
was 6.13 (95% CI, 3.25–11.55).

Clinical Follow-up
Data obtained for both IQ and OQ patients indicated that,

during the average post-PET follow-up of about 3 y, 17% of
the 141 patients experienced disease progression whereas
117 (83%) maintained a disease-free or stable clinical
course. The average follow-up was 36 � 13 mo and 35 � 12
mo for the IQ and OQ groups, respectively. Patients within
each group were stratified according to whether their disease
was progressive or nonprogressive (stable or regressed). Each
of the subgroups based on hypermetabolic foci was also
stratified according to such outcome data (Fig. 3).

The analysis revealed disease progression among 34.6%
(9/26) of IQ patients with isolated extraaxillary metastases,
compared with 12.5% (2/16) of IQ patients with other
patterns of metastases or no metastases (RR � 2.77, 34.6%/
12.5%). The risk for disease progression was 3.96 times
greater among OQ patients with PET findings of isolated
extraaxillary metastases (40%, 4/10) than among OQ pa-
tients with other patterns of metastases or no metastases
(10.1%, 9/89). The proportion of IQ patients with progres-
sive disease (26.2%, 11/42) was twice the proportion of OQ
patients with progressive disease (13.1%, 13/99). For the
entire study group, the frequency of progressive disease
documented in patients with PET findings of isolated ex-

FIGURE 2. Whole-body coronal 18F-FDG
PET scans of breast cancer patients, with ar-
rows indicating extraaxillary metastases in
chest and supraclavicular regions (A), metas-
tasis in right axilla (B), and axillary and ex-
traaxillary metastases in chest, lumbar, and
iliac regions (C).

FIGURE 3. Breakdown of clinical outcomes and PET findings for different primary-tumor locations.

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traaxillary metastases was 36.1% (13/36), versus 10.5%
(11/105) for other patients, for an RR of 3.45. Clinical data
allowed further stratification of patients into groups accord-
ing to the type of post-PET therapy (adjuvant, for metastatic
disease, or none) received during follow-up. Among those
who received adjuvant therapy (n � 68), 42.9% (6/14) of IQ
patients had PET findings of isolated extraaxillary metasta-
ses, compared with 9.3% (5/54) of OQ patients (RR � 4.63)
(Fig. 4). Similarly, for patients who received post-PET
treatment for metastatic disease (n � 40), IQ patients had a
greater frequency of PET findings of isolated extraaxillary
metastases (RR � 3.50, 87.5%/25.0%). For patients under-
going systemic therapy, quadrant-associated risk of progres-
sion was particularly heightened when the therapy was
adjuvant; 28.6% (4/14) of IQ patients were documented to
have progressive disease, versus 7.4% (4/54) of OQ pa-
tients, for an RR of 3.86.

DISCUSSION

In breast cancer patients with primary tumors in an OQ,
metastases are more often in the axillary lymph nodes,
whereas patients with primary tumors in an IQ more often
have extraaxillary metastatic disease. Isolated extraaxillary
metastases can go undetected during conventional staging,
possibly contributing to the higher mortality rate of IQ
patients than of OQ patients. An evaluation of 2,396 breast

cancer patients found that those with primary tumors in
central or IQ locations had a 30% greater chance for devel-
opment of distant metastases and a 20% higher mortality
rate than did patients with OQ primary tumors (2). Another
study found patients with medial primary breast tumors to
have double the risk of patients with lateral tumors for
relapse of disease and for breast cancer death (3). The
higher mortality rate associated with lesions in the IQ may
result from the greater difficulty in detecting spread of
disease to extraaxillary sites. Accurate staging after initial
diagnosis of disease is critical for determining the most
appropriate course of therapy and may thereby affect clin-
ical outcome.

The longitudinal clinical information collected here com-
prises a database of PET findings that one can relate to
primary tumor location and subsequent disease course. Pa-
tients with and without disease progression did not signifi-
cantly differ in age at the time of PET or in the length of
follow-up. Patients with IQ primary tumors had a 6-fold
greater frequency of PET findings of isolated extraaxillary
metastasis and a greater risk for development of progressive
disease than did patients with OQ primary tumors. In addi-
tion, patients who had isolated extraaxillary metastases
identified by PET had triple the risk for disease progression
of those who did not. This discovery suggests that IQ
patients with PET findings of isolated extraaxillary metas-

FIGURE 4. Breakdown of clinical outcomes and PET findings for patients who received adjuvant treatment after PET. Among
patients who received adjuvant treatment, 20.6% (14/68) had IQ tumors and 79.4% (54/68) had OQ tumors.

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tases may not have received treatment as adequate as that
received by IQ patients with no or other patterns of metas-
tases or by OQ patients overall.

A potential limitation of this study is the question of the
generalizability of its results: How closely do patients seen
in a tertiary-care university clinical environment compare
with patients seen in a community setting? However, all
18F-FDG PET scans were acquired under standard clinical
protocols and read by nuclear medicine physicians as stan-
dard clinical (nonresearch) studies, after being ordered by
referring physicians generally as a “problem-solver,” when
they desired more information to help clarify the extent of
disease (23).

Other possible limitations of the study data deserve men-
tion. Follow-up for patients after PET averaged 3 y. It is
possible that in some patients, disease progression may
develop after this period, such that classification of their
clinical course as “nonprogressive” is somewhat arbitrary.
Nevertheless, the lengths of follow-up for IQ and OQ pa-
tients were nearly identical (36 � 13 mo and 35 � 12 mo),
and this limitation would not affect main conclusions unless
progression after follow-up were to occur more frequently
in OQ patients than in IQ patients. That situation would
seem unlikely, and even if it were to exist, the main obser-
vations would still hold from a time-to-progression perspec-
tive. As another possibility, selection bias based on differ-
ential availability of clinical information for patients with
IQ and OQ tumors could occur, but again we cannot envi-
sion a way in which this could have occurred that would be
likely to alter our main findings. Similarly, any intergroup
differences in clinical parameters about which we have
incomplete information, such as distribution of TNM stages
or number of prior courses of therapy, could serve as
possible confounders.

It was not within the scope of this study to consider
quantitative information such as the standardized uptake
values of PET findings, because many of the scans were
obtained before the routine implementation of attenuation
correction. Several studies, however (24 –27), have found
18F-FDG standardized uptake values to be a probable prog-
nostic factor for assessing the response of breast cancer
patients to therapy, and the information obtained from such
measurements may well be used to complement the loca-
tion-based findings of this study.

CONCLUSION

In summary, 18F-FDG PET scans of patients with IQ
primary tumors often reveal a pattern of hypermetabolic
foci consistent with isolated extraaxillary metastasis. Such
patients may particularly stand to benefit from the use of
PET to ascertain the actual stage of disease and help ensure
that the therapeutic approach is at an appropriate level of
aggressiveness.

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