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Journal of Clinical Microbiology, June 1999, p. 2106-2108, Vol. 37, No. 6
0095-1137/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Mycobacterium bovis BCG Causing
Vertebral Osteomyelitis (Pott's Disease) Following Intravesical
BCG Therapy
Ibrahim S.
Aljada,1
John K.
Crane,2
Nancy
Corriere,3
Datta G.
Wagle,4 and
Daniel
Amsterdam1,2,3,5,*
Erie County Medical
Center3 and Departments of
Medicine,2
Microbiology,5
Pathology,1 and
Urology,4 School of Medicine and
Biomedical Sciences, University at Buffalo, Buffalo, New York
14215
Received 21 September 1998/Returned for modification 10 November
1998/Accepted 18 March 1999
 |
ABSTRACT |
We report a case of Mycobacterium bovis BCG vertebral
osteomyelitis in a 79-year-old man 2.5 years after intravesical BCG therapy for bladder cancer. The recovered isolate resembled M. tuberculosis biochemically, but resistance to pyrazinamide (PZA) rendered that diagnosis suspect. High-pressure liquid chromatographic studies confirmed the diagnosis of M. bovis BCG infection.
The patient was originally started on a four-drug antituberculous regimen of isoniazid, rifampin, ethambutol, and PZA. When
susceptibility studies were reported, the regimen was changed to
isoniazid and rifampin for 12 months. Subsequently, the patient was
transferred to a skilled nursing facility for 3 months, where he
underwent intensive physical therapy. Although extravesical adverse
reactions are rare, clinicians and clinical microbiologists need to be
aware of the possibility of disseminated infection by M. bovis BCG in the appropriate setting of clinical history,
physical examination, and laboratory investigation.
| |
CASE REPORT |
We report a case of
Mycobacterium bovis BCG spinal osteomyelitis affecting a
79-year-old man 2.5 years after intravesical BCG administration for
bladder cancer. A 79-year-old man was admitted to the Erie County
Medical Center in December 1997 with low back pain, left hip pain,
lower extremity weakness, and inability to walk. He first had back pain
in June 1996, when he sustained a compression fracture of vertebral
body L1. He had additional compression fractures of vertebral bodies L5
and T11 between December 1996 and June 1997; all of these fractures
were attributed to osteoporosis. His medical history included
hypertension, two myocardial infarctions (in 1974 and 1975), cigarette
smoking, Parkinson's disease, and peripheral vascular disease.
The patient had bladder cancer diagnosed in November 1993. A cystoscopy
done at another medical center at that time showed a slightly more than
5-cm transitional cell carcinoma (grade 1, stage 0), for which he was
treated with transurethral resection the following month. A repeat
cystoscopy 18 months later revealed multiple superficial urinary
bladder tumors aggregating to less than 5 cm (grade 2, stage 0), and
all were resected at the time of cystoscopy. Treatment with
intravesical bacillus Calmette-Guérin (BCG) immunotherapy (TICE
strain by Organon) was started in June 1995 with one instillation
treatment given every week for 8 weeks, followed by one treatment every
month for the next 12 months, with the last dose of BCG given in
October 1996. Follow-up cystoscopy was performed every 3 months until
May 1997; these examinations did not reveal any evidence of a recurrent tumor.
On physical examination for this current admission, he had bilateral
lower extremity weakness and pain with hip movement, especially on the
left, but no other significant abnormality. X-rays showed the old
compression fractures at T11, L1, and L5 plus new destructive changes
affecting vertebral bodies L2 and L3. Magnetic resonance imaging
revealed destruction of the vertebral body of L3 with a paraspinal
soft-tissue mass extending into the left psoas muscle. The spinal canal
was severely compressed at L3. The patient underwent a computerized
tomography (CT)-guided needle biopsy of vertebral body L3 and the
paraspinal mass, but no tumor cells were seen and stains for bacteria,
mycobacteria, and fungi were negative. Therefore, 2 weeks later, a
laminectomy was performed which revealed pus in the paraspinal mass and
the psoas muscle. Histological examination of the tissue obtained did
not show granulomas or acid-fast bacteria (AFB). Cultures for routine
bacteria and fungi showed no growth. No AFB were seen on concentrated
smears in both biopsies, but BACTEC 12B broth (Becton-Dickinson,
Sparks, Md.) was positive for growth after 3 weeks from the initial
specimen and eventually all specimens. Subcultures to Lowenstein-Jensen
(L-J) and 7H10 media grew the same nonchromogenic rough colonies 3.5 weeks after inoculation from both biopsies. The use of a nucleic acid
probe (AccuProbe; Gen-Probe, San Diego, Calif.) for M. tuberculosis complex organisms was positive. Nitrate reduction was
weakly positive (1+) on colonies recovered from the CT-guided biopsy
and negative on those recovered from the open biopsy. Results of
additional biochemical testing of the initial biopsy colonies were as
follows: niacin production negative, heat-stable catalase reaction (at
68°C) negative, pyrazinamidase negative, semiquantitative catalase of
<20 mm, and thiophene-2-carboxylic acid hydrazide (TCH) susceptible.
The isolated AFB were susceptible to isoniazid, streptomycin, rifampin,
and ethambutol but resistant to pyrazinamide (PZA) as determined by the
radiometric BACTEC methods. Repeat testing for PZA susceptibility
confirmed resistance to the drug; all isolates reacted similarly. The
preliminary identification was M. tuberculosis complex.
Subsequent testing by high-pressure liquid chromatography (HPLC)
performed at North Carolina State University, upon referral from the
New York State Health Department, identified the mycobacterium as
M. bovis BCG.
The patient was started on a four-drug regimen of isoniazid, rifampin,
ethambutol, and PZA. When susceptibility results became available, the
regimen was changed to a 12-month course of isoniazid and rifampin.
Subsequently, the patient was transferred to a skilled nursing
facility, where he underwent intensive physical therapy for 3 months to
restore strength to his lower extremities. At the time this report was
prepared, the patient was unable to walk because of persistent leg
weakness. However, he was living at home and using a wheelchair. He had
had no recurrence of bladder cancer.
Discussion.
BCG is a live attenuated strain of M. bovis that was first used for immunization against tuberculosis in
1921. Over 3 billion doses of BCG vaccine have been given since 1948, and it has been considered safe (15). Localized abscesses,
regional lymphadenopathy, and disseminated disease in immunocompromised
hosts are uncommon but well-recognized complications (8, 13,
15). Intravesical instillation of BCG was first introduced by
Morales and associates in 1976 (10) and is currently the
most effective agent for therapy and prophylaxis of superficial
transitional cell carcinoma of the urinary bladder (i.e., Ta, T1, and
carcinoma in situ) and has been used in order to treat existing or
residual tumors, prevent tumor recurrence, prevent disease progression,
and prolong survival (12). Complications of BCG
instillations for cancer therapy are relatively rare but are more
frequent than in tuberculosis vaccination programs. While side effects
such as hematuria, dysuria, increased urinary frequency, and an
influenza-like syndrome are common, intravesical BCG is considered safe
and extravesical complications are rare (9). Lamm and
associates (7) noted the incidence of the following
complications in 2,602 patients: fever (2.9%), hematuria (1.0%),
granulomatous prostatitis (0.9%), pneumonitis or hepatitis (0.7%),
arthralgia (0.5%), epididymitis (0.4%), sepsis (0.4%), rash (0.3%),
ureteral obstruction (0.3%), contracted bladder (0.2%), renal abscess
(0.1%), and cytopenia (0.1%). The same authors made treatment
recommendations for BCG-related complications.
BCG osteomyelitis is a rare complication of vaccination with BCG for
prophylaxis of tuberculosis (1, 11). It has been reported
after use of intralesional BCG injections in a melanoma case
(14). To our knowledge, it has been reported only once previously after intravesical BCG instillation for bladder cancer (5). In our case, the patient's advanced age and
pre-existing osteoporotic compression fractures of the spine may have
contributed to the development of vertebral osteomyelitis.
The M. tuberculosis complex includes M. tuberculosis, M. africanum, M. bovis,
M. bovis BCG, and the newly described species M. canetti. Nitrate reduction and niacin production are strongly positive in cases of M. tuberculosis infection. Colonies
grown in our case had weak nitrate reduction and no niacin production, making M. tuberculosis a remote possibility. M. africanum is a cause of human tuberculosis in tropical Africa. In
addition, M. tuberculosis and M. africanum are
both resistant to TCH inhibition and susceptible to PZA. In our case,
colonies were susceptible to TCH inhibition and resistant to PZA,
results that favor an identification of M. bovis. A possible
consideration at this point would be M. bovis BCG. The
treatment history with BCG makes a diagnosis of M. bovis BCG
more likely. Differentiation of wild-type M. bovis and
M. bovis BCG based on morphology and biochemical criteria is
difficult, since the two exhibit similar features. Although both
species demonstrate susceptibility to TCH inhibition and resistance to
PZA, some differences help to distinguish them. M. bovis BCG
strains are eugonic, i.e., more rapidly growing (requiring 3 to 4 weeks
to grow on L-J medium), having a rough, buff-colored appearance, and in
some cases, accumulating niacin (6). M. bovis, on
the other hand, has a very slow growth rate, producing dysgonic-appearing colonies on L-J medium, frequently requiring 6 to 8 weeks to become observable. Growth of most strains is better on L-J
medium than in Middlebrook 7H10 or an equivalent medium, the best being
one without glycerol, although repeated subculture permits growth
adaptation (17). Typical colonies are buff colored, low, and
small and may appear either smooth or rough on egg-based media. On
Middlebrook 7H10 agar, colonies are very flat and transparent and often
show little or no stranding (referred to as water droplet like)
(6). Freshly isolated cultures of M. bovis are
microaerophilic, and inocula dispersed into liquid, semiliquid, or
solid agar media grow in the medium but not on the surface, while
M. bovis BCG strains grow well aerobically. In addition,
M. bovis BCG strains grow well on glycerated media
(17). In our case, colonies grew after 3 weeks and had a
rough, buff-colored appearance, favoring a diagnosis of M. bovis BCG.
The four validated methods for the definitive identification of
M. bovis BCG are phage typing (4), HPLC
(2), restriction fragment length polymorphism analysis with
the use of insertion element IS1081 as a probe (i.e.,
IS1081 fingerprinting) (16), and amplification of
a specific region containing the major polymorphic tandem repeat by
PCR, followed by restriction enzyme analysis (3). HPLC was
the method used in our case.
This is the second report of Pott's disease caused by intravesical BCG
therapy for bladder cancer. The standard mycobacterial culture
techniques currently used in the majority of laboratories are capable
of recovering the organism as M. bovis. More sophisticated techniques are probably needed to confirm a diagnosis of M. bovis BCG as mentioned above. Media and growth parameters may have
to be adjusted to recover some of the difficult-to-grow nontuberculous mycobacteria. Microbiologists should consider M. bovis BCG
when a nucleic acid probe is positive but the organism is characterized by negative nitrate reduction, negative niacin production,
susceptibility to inhibition by TCH, and resistance to PZA, especially
in a patient with a history of intravesical BCG therapy for bladder cancer.
There is no established antimicrobial regimen for the treatment of
Pott's disease caused by BCG. In this case, a 12-month regimen of
isoniazid and rifampin proved successful. BCG is generally highly
susceptible to antituberculosis drugs, including isoniazid, rifampin,
paraaminosalicylic acid, ethambutol, and to a lesser degree, kanamycin
and gentamicin (7).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Laboratory Medicine, Erie County Medical Center, 462 Grider St.,
Buffalo, NY 14125. Phone: (716) 898-3114. Fax: (716) 898-3090. E-mail: AMSTERDAM{at}LAB.ECMC.EDU.
| |
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Journal of Clinical Microbiology, June 1999, p. 2106-2108, Vol. 37, No. 6
0095-1137/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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