STAR ABSTRACT

The role of MRI in
bone marrow

imaging
Maximilian FReiser

MD

MRI has unique capabilities in the
visualization of both the normal and
abnormal bone marrow. Moreover,
MRI allows us to monitor physiologi-
cal conversion from hematopoietic
(red) to fatty (yellow) marrow and to
assess variants in the distribution of
both marrow types.

In hematopoietic bone marrow,
the content of fat is much higher than
in the red marrow, in which the signal
characteristics are dominated by the
higher proportion of water, which is
due to the cellular elements. The con-
tent of bony trabeculae within the
bone marrow is also important for
signal characteristics, especially when
pulse sequences are applied which are
sensitive to susceptibility effects.

In the newborn, all bones contain
red marrow. During infancy, child-
hood and adolescence, conversion of
red to yellow marrow takes place. This
process of bone marrow co~ver~ion
proceeds in centripetal direction,
Most peripheral bones, such as the
phalanges of the hands and feet are
involved earlier than the more central
elements of the lower leg and forearm,
respectively. Within the long bones,
the conversion of the bone marrow
starts in the diaphyses and progresses
to the metaphyses. The epiphyses, on
the other hand, contain yellow mar-
row when they ossify. At the age of

about 22 to 25 years of age, the adult
distribution of red and yellow is
found. Hematopoietic bone marrow
in adults is found within vertebral
bodies, pelvis, ribs, scapula, skull as
well as in the proximal portions of the
humerus and femur. It should be
noted that fat content increases with
age also in those skeletal elements
which contain yellow marrow and
that islands of hematopoietic marrow
may exist in the long bones, especially
in the metaphyses which must not be
misinterpreted as an infiltration of
neoplastic tissue. Moreover, various
pathological and physiological condi-
tions which are associated with a need
of increased red or white cell produc-
tion, may result in focal or diffuse
reconversion of yellow to red marrow:
Increased menstrual blood loss, severe
infections, extensive athletic activities
(e.g. marathon runners), extensive
bone marrow infiltration by neo-
plasms or leukemia, hemoglo-
binopathies etc. MRI is able to depict
the distribution of yellow and red
marrow and to diagnose pathological
conditions within the bone marrow.
The selection of adequate pulse
sequences is critical. Tl-weighted
spinecho and STIR sequences are
most useful for this differentiation. In-
and out-of-phase gradient echo
sequences as well as T2* weighted gra-
dient echo sequences may add valu-
able information. In T2-weighted
(fast) spin echo sequences and con-

27 SA JOURNAL OF RADIOLOGY. December 2002

trast enhanced Tl-weighted
sequences, on the other hand, the ~o~-
trast between fatty and hematopoietic
marrow is greatly reduced. Initial
results indicate that diffusion weight-
ed imaging (DWI) may be superior to
other techniques for specific ques-
tions, e.g. differentiation of neoplastic
and osteoporotic fractures of the ver-
tebrae.

MRI is particularly sensitive for
the detection of bone marrow mani-
festations of lymphoma, multiple
myeloma as well as bony metastases.
This issue will be addressed in anoth-
er lecture specifically devoted to this
subject. There exist many other disor-
ders of the bone marrow which are
readily detected using MRI. Some of
them may play an important role in
oncologic imaging.

Bone infarcts and
aseptic necrosis
Bone infarct and aseptic necroses

frequently occur in tumor patients
and patients with leukemia treated
with cytotoxic drugs and steroids.
When pain and restriction of motion
is reported by the patients bony
metastases are suspected. In the late
phase, bone infarcts are displa~ed as
polycyclic areas with a dense nm ?f
calcification in the periphery on plain
radiograms which allow for a straight-
forward diagnosis. In the early stage,
however, when bone infarcts cause
severe pain, radiographic signs are
very discrete. MRI shows high signal
intensity on STIR and fat sat CE scans
in the periphery of the lesion, normal
fat signal in the center and edema in
the adjacent normal bone marrow
thus allowing for a specific diagnosis.

Aseptic necroses are located in the
subchondral region of various joints,
such as the femoral and humeral



STAR ABSTRACT

head, the femoral condyles and the
talus. In the early stage, minor degrees
of osteopenia or the crescent -sign
(semicircular lucency) are the only
plain film findings. In MRI the
necrotic zone is clearly demarcated
and depending upon the composition
of the necrotic tissue high, intermedi-
ate or low signal intensities are found.
The 'double line sign' at the periphery
of the necrotic zone is regarded as a
specific feature of aseptic necrosis.

Stress and insuffi-
ciency fractures

Following radiation therapy,
chemotherapy and immobilization
patients treated for malignant tumors,
who are frequently at older age, are
prone to insufficiency fractures.
Especially previous radiation therapy
results in weakening of the bone.
Insufficiency fractures are often locat-
ed in the femoral neck, sacrum, iliac
bones and lower lumber vertebrae.
Bone scanning shows focal tracer
accumulation in the areas affected by
insufficiency fractures thus mimick-
ing bony metastases. With MRI (and
CT) these insufficiency fractures are
readily diagnosed. Longitudinal bands
of low signal intensity with adjacent
bone marrow edema are indicative of
insufficiency fractures. In CT, bond-
like or geographic areas of sclerosis are
visualized.

Osteomyelitis
and cellulitis

Plain radiography is insensitive for
the detection of osteomyelitis before
larger areas of trabecular and cortical
bone are destroyed (up to 3 weeks
after the onset of symptoms). Bone
scanning is highly sensitive but non-
specific. MRI, especially when using

fat sat CE scans allows for early diag-
nosis and precise assessment of the
location and extent of the infectious
process. Extension within the bone
marrow, involvement of the cortex,
and paraosseus involvement are visu-
alized. Following contrast enhance-
ment, abscess cavities and the hyper-
vascular abscess membrane are
depicted. Following surgical treat-
ment of bone tumors and skeletal
metastases the differentiation of reac-
tive tissue and early infection, howev-
er, may be difficult or impossible.
SAPHO syndrome is a specific entity
which is associated with palmo-plan-
tar pustulosis, psoriasis or skin infec-
tions (acne conglobata). It involves
multiple skeletal elements, especially
the proximal sternum and the medial
portions of the clavicles. However,
multiple other bones can also be
involved. Thickening, irregular struc-
ture and multiple small bony destruc-
tions are found in the involved bones.
These features may be misinterpreted
as neoplasms and this diagnosis may
be supported by multifocal tracer
accumulation in the bone scans. MRI
and CT findings also have an aggres-
sive appearance and awareness of this
entity is important to avoid false diag-
noses.

Chronic recurrent multifocal
osteomyelitis (CRMO) is found in
children and adolescents and multiple
bones are affected by a chronic type of
osteomyelitis. Multifocality may also
lead to misdiagnosis of osseous
metastases.

leukemia
In acute and chronic types of

leukemia, the normal bone marrow is
replaced by neoplastic cells. The
extent of bone marrow involvement is

28 SA JOURNAL OF RADIOLOGY. December 2002

variable. The radiologist may detect
homogeneous marrow abnormalities
when MRI is performed due to symp-
toms unrelated to a systemic bone
marrow disorder (e.g. joint pain) and
has to insist on a thorough examina-
tion by the internist.

For monitoring patients under
treatment for leukemia, MRI proved
not to be useful, even if some anecdo-
tal reports exist in which relapse of the
disease was first diagnosed by MRI.
Due to signal alterations within the
bone marrow in patients with
leukemia, other pathological condi-
tions such as aseptic necroses, osteo-
myelitis and spondylitis may be diffi-
cult to be detected.

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