Monday, April 23, 2018

Hip Replacement-Swedish Study.

Nationwide Study of Cancer Risk Among Hip Replacement Patients in Sweden 

JNCI: Journal of the National Cancer Institute, Volume 93, Issue 18, 19 September 2001, Pages 1405–1410, https://doi.org/10.1093/jnci/93.18.1405
Published:

19 September 2001

Article history

Abstract


Background: Orthopedic implants and their fixatives contain materials with carcinogenic potential. Whether these implants are linked to subsequent cancer development remains unknown, mainly because large-scale, long-term follow-up data are scarce. Methods: We conducted a nationwide cohort study in Sweden to examine cancer incidence among 116 727 patients who underwent hip replacement surgery during the period from 1965 through 1994. Through record linkage to the Swedish Cancer Register, we identified all incident cancers through 1995 in this population (693 954 person-years of observation). For each cancer type, the observed number of cases was divided by that expected in the general Swedish population to produce standardized incidence ratios (SIRs). Results: Relative to the general population, the cohort had no overall cancer excess (SIR = 1.01; 95% confidence interval [CI] = 0.99 to 1.03). However, we observed elevated SIRs for prostate cancer (SIR = 1.16; 95% CI = 1.11 to 1.22) and melanoma (SIR = 1.15; 95% CI = 1.01 to 1.30) and a reduction in stomach cancer risk (SIR = 0.83; 95% CI = 0.75 to 0.92). Long-term follow-up (≥15 years) revealed an excess of multiple myeloma (SIR = 1.86; 95% CI = 1.01 to 3.11) and a statistically nonsignificant increase in bladder cancer (SIR = 1.42; 95% CI = 0.98 to 1.99). There was no material increase in risk for bone or connective tissue cancer for either men or women in any follow-up period. Conclusions: In this, the largest study to date, hip implant patients had similar rates of most types of cancer to those in the general population. Although the excesses of melanoma, multiple myeloma, and prostate and bladder cancers may be due to chance, confounding, or detection bias and should be interpreted cautiously, they warrant further investigation because of the ever-increasing use of hip implants at younger ages.

The carcinogenic potential of hip implants is of growing public health interest as they become more common, are implanted in younger patients, and remain in the body for increasingly longer periods of time (1). Various metallic and nonmetallic substances contained within the implants or as components of their fixatives are known or are suspected to cause cancer in humans or animals; in particular, these substances include chromium, cobalt, nickel, beryllium, cadmium, zinc, iron, lead, titanium, and polymethylmethacrylate (15). Case reports of bone and soft-tissue sarcomas adjacent to orthopedic implants have suggested that exposure of local tissues to the implanted material may induce cancer at that site (68). Systemic exposure to metallic ions and other particulate debris released through corrosion of the implant is another concern, since distant tissues could also be affected. The International Agency for Research on Cancer determined the evidence regarding human carcinogenicity of orthopedic implants to be inadequate, in part because previous cohort studies had limited data beyond 10–15 years' latency to address possible long-term effects.
We reported previously on a nationwide cohort of patients who underwent hip implant surgery during the period from 1965 through 1983 in Sweden and were followed until the end of 1989 (9). This cohort has now been expanded to include new patients who received hip implants through 1994, and the followup was updated through 1995. Hence, the total person-years of observation of our original report has more than doubled, and the present study of hip implants and cancer risk is, to our knowledge, the largest to date with the longest follow-up to evaluate potential long-term effects.

METHODS

This study was approved by the regional Ethics Committee of the medical faculty, Uppsala University, Sweden, and by the Data Inspection Board of the National Board of Health and Welfare of Sweden, Stockholm.

Identifying the Cohort

The Inpatient Register was established by the National Board of Health and Welfare in Sweden in 1964 to document individual hospital discharges. Each Inpatient Register record contains (a) the patient's national registration number (NRN— a unique identifier assigned to all Swedish residents), (b) the date of hospital admission and discharge, (c) up to six discharge diagnoses coded according to the International Classification of Diseases (ICD)-7 until 1968, ICD-8 from 1968 through 1986, and ICD-9 thereafter, and (d) up to six operation codes from the Swedish Classification of Operations and Major Procedures. The NRN permits unambiguous linkage across all national registers in Sweden.
All records in the Inpatient Register indicating hip replacement surgery (operation codes 8410, 8411, 8412, and 8419 and also codes 8413, 8414, and 8415 since 1984) from January 1, 1965, through December 31, 1994, were initially selected. To remove records with erroneous NRNs (correct NRNs are a prerequisite for record linkages and follow-up), we excluded NRNs that could not be found in either the Register of Total Population, Migration, or Death (n = 799, 0.6% of the identified records).
A total of 128 170 persons were identified as having had hip replacement surgery during the study period. We selected the first recorded discharge to be used as the index surgery in this analysis.

Follow-up/Record Linkage

The nationwide Death Register provided data on all cohort member deaths (date and cause), while dates of emigration for cohort members who left Sweden were identified through the Migration Register. The national Cancer Register, founded in 1958 and estimated to be 98% complete (10), was used to ascertain (via linkage on patients' NRNs) all incident cancers diagnosed in the cohort from the start of follow-up until December 31, 1995. The Cancer Register has coded malignant neoplasms according to the ICD-7 classification scheme during the entire period of the study. To exclude hip replacement surgeries performed as a result of malignant disease and to restrict our outcome to first primary tumors, we excluded from the cohort all persons with a cancer diagnosis preceding their hip implant (n = 10 308). We excluded an additional 1135 subjects because of observed inconsistencies among data from the national registers. Thus, a total of 116 727 patients were entered into the study.

Statistical Analysis

Individual person-time was calculated from the first hip implant surgery until the first cancer diagnosis, death, emigration, or December 31, 1995, whichever came first. Person-time accrued and cancer events observed during the first year of follow-up were not counted in the analysis, since cancer cases diagnosed during this period are assumed to be coincidental, prone to selection and surveillance bias, and unlikely to be causally related to the implant. Cancers found incidentally at autopsy were excluded from the analyses to avoid possible ascertainment bias related to differential autopsy rates between hip implant patients and the general population. The number of expected events was calculated by multiplying age-, sex- and calendar year-specific incidence rates (expected rates) from the general population by the person-time accrued in the cohort. In the calculation of the expected rates, person-time at risk in the general population did not include that contributed by individuals who were alive but who had been diagnosed with cancer (prevalent cancer cases). The number of observed events was divided by the number of expected events, producing a standardized incidence ratio (SIR) with 95% confidence intervals (CIs) calculated assuming that the observed events followed a Poisson probability distribution (11). SIRs were calculated for all cancers combined as well as separately for each cancer type. A chi-square test for linear trend in SIRs was used to evaluate dose–response relationships by duration of follow-up. The indication for the hip implant operation was determined from the diagnostic codes (ICD codes) provided in the Inpatient Register. When more than one indication was listed, the one listed first was considered to be the principal diagnosis. Separate subanalyses were performed with the use of the group of patients with rheumatoid arthritis as their indication for hip replacement, because patients with this disease are hypothesized to have a somewhat different cancer risk profile. All P values presented in this report are two-sided, and the results were considered to be statistically significant at Pless than .05.

RESULTS

The 116 727 patients who received hip implants during the period from 1965 through 1994 were followed for a mean of nearly 7 years (range, 1 day to 31 years) (Table 1). The reason for hip implant surgery was mainly osteoarthritis (67%), while 20% of the cohort had a fracture indication, 5% rheumatoid arthritis, and 8% some other indication.
The cohort generated more than 10 000 cases of cancer during follow-up, excluding those that occurred during the first year. SIRs for major cancer types are shown in Table 2, stratified by sex. Compared with the general population, we observed no excess of cancer overall (SIR = 1.01; 95% CI = 0.99 to 1.03). The incidence of the major digestive cancers was reduced (stomach cancer: SIR = 0.83 [95% CI = 0.75 to 0.92]; colon cancer: SIR = 0.95 [95% CI = 0.89 to 1.02]; and rectal cancer: SIR = 0.90 [95% CI = 0.82 to 0.99]). Among subjects with all indications for implants, lung cancer rates were 16% lower than expected for men (SIR = 0.84; 95% CI = 0.75 to 0.93), but they were 14% higher than expected for women (SIR = 1.14; 95% CI = 0.99 to 1.29). The excess lung cancer among female patients was, however, statistically significant only among those with a fracture indication for hip implant surgery (SIR = 1.52; 95% CI = 1.16 to 1.94). Men with fractures also had a statistically significant excess risk of lung cancer (SIR = 1.80; 95% CI = 1.35 to 2.35), despite the fact that an overall reduced risk was seen for males.
SIRs for both melanoma and nonmelanoma skin cancer were statistically significantly elevated, with the excess of melanoma being more pronounced among men and nonmelanoma skin cancer more pronounced among women. We also observed statistically significant excesses of prostate cancer (SIR = 1.16; 95% CI = 1.11 to 1.22) and of kidney cancer in women (SIR = 1.26; 95% CI = 1.07 to 1.48). Stratification by indication showed that the excess risk for kidney cancer among women was most prominent for those with underlying rheumatoid arthritis (SIR = 1.88; 95% CI = 0.97 to 3.29). Among women with osteoarthritis, the SIR for kidney cancer was 1.28 (95% CI = 1.05 to 1.55).
No association was observed for connective tissue cancer (SIR = 0.96; 95% CI = 0.72 to 1.25). Eight cases of bone cancer were identified in the cohort, slightly less than the 8.6 expected. The report forms received by the Cancer Register were reviewed for each of these eight cases. Five were chordomas (three located in the sacrum/coccyx area and two in the vertebral column excluding the sacrum and coccyx), and three were chondrosarcomas (located in the tibia [n = 1], distal femur [n = 1], and proximal femur [n = 1]). Five of the bone cancer cases were diagnosed in the patient within 5 years of receiving the implant, and all were diagnosed within 7 years (mean, 4.4 years after implantation).
Almost 1900 incident cancer cases were identified among cohort members followed at least 10 years after their surgeries (Table 3). For all cancers combined, we observed a borderline statistically significant excess risk between 10 and 14 years after surgery (SIR = 1.06; 95% CI = 1.00 to 1.12), but not in any other time period. The deficit of stomach cancer became more pronounced with increasing follow-up time (particularly after the exclusion of cardia cancers), with a 30% reduction in risk after 10 years' latency. The largest excess of melanoma was seen after a latency period of 15 years or more (SIR = 1.83; 95% CI = (1.10–2.86), and our analysis revealed a clear and statistically significant trend of increasing SIRs over time for this cancer (P for trend = .01). In contrast, the association with nonmelanoma skin cancer was inconsistent across latency periods and disappeared after 15 years of follow-up. The highest SIR for prostate cancer was seen during the period 5–9 years after implant surgery (SIR = 1.21; 95% CI = 1.12 to 1.31), although some excess was still apparent at a latency of 15 or more years (SIR = 1.15; 95% CI = 0.92 to 1.43). The incidence of kidney cancer was 54% higher than expected 10–14 years after surgery (SIR = 1.54; 95% CI = 1.13 to 2.04), but this excess was attenuated and statistically nonsignificant with longer follow-up. The risks of multiple myeloma and bladder cancer were higher than expected after a latency of 15 years or more, but not in earlier time periods. We could not assess patterns of cancer risk by latency and surgical indication jointly, because the number of cancer events became too small in the later follow-up years.
In the subgroup of patients with rheumatoid arthritis, we found statistically nonsignificantly elevated SIRs for hematopoietic malignancies (Table 4). We also observed a strong and statistically significant deficit of colon cancer, a nonsignificant deficit of rectal cancer, and stomach cancer risk close to that expected in the general population. In contrast, among patients who had osteoarthritis or a fracture as their surgical indication, we observed no association with hematopoietic cancers (SIR = 0.95; 95% CI = 0.88 to 1.03) or colon cancer (SIR = 0.97; 95% CI = 0.91 to 1.04), a modest deficit in rectal cancer (SIR = 0.90; 95% CI = 0.82 to 0.99), and a substantial reduction in stomach cancer (SIR = 0.82; 95% CI = 0.74 to 0.91) (data not shown).
Separate analyses of the original cohort who received hip implants during the period from 1965 through 1983 (36 774 patients; 364 882 person-years) and the newer cohort who received implants during the period from 1984 through 1994 (79 953 patients; 329 071 person-years) produced, on the whole, similar results. The exception was with respect to kidney cancer. The overall SIR for kidney cancer in the original cohort was 1.35 (95% CI = 1.15 to 1.56; 177 cases observed versus 131.6 expected) with excesses of varying magnitudes seen for patients with all indications, while in the newer cohort the SIR for kidney cancer was 0.92 (95% CI = 0.75 to 1.11; 108 cases observed versus 117.9 expected) with an excess seen only for patients with rheumatoid arthritis (SIR = 2.66; 95% CI = 1.38 to 4.65).

DISCUSSION

In summary, overall cancer risk among hip implant patients was close to expectation. However, we observed these patients to have a statistically significant excess of melanoma and prostate cancer and, after a latency of 15 years or more, of multiple myeloma and bladder cancer. In contrast, we noted a statistically significant deficit of stomach cancer and suggestive evidence for decreased colorectal cancer risk. The incidence of bone and connective tissue cancers was not statistically significantly higher than expected for either sex in any follow-up period.
In our earlier report (9), the rate of kidney cancer was found to be statistically significantly elevated among hip implant recipients, whereas this finding is not confirmed in the newer cohort of patients who received implants during the period from 1984 through 1994. It is possible that hip implants from the earlier time period (more commonly metal on metal than polyethylene on metal) could influence renal cancer risk via properties that are not shared by newer implants. Also, hip implant patients are high consumers of analgesics, and the older cohort of patients had more opportunity to take phenacetin, an analgesic that was linked to both kidney failure (12) and kidney cancer (13) and, therefore, withdrawn from the Swedish market in the early 1970s. If one considers the number of associations examined in the analysis, it is also possible that the elevated SIR for kidney cancer in the 1965–1983 cohort was due to chance. In line with findings from our expanded cohort, Olsen et al. (14) found no excess of kidney cancer in a large cohort of Danish patients who had hip implant surgery during the period from 1977 through 1989 (SIR = 0.93; 95% CI = 0.74 to 1.14).
The excess risk of melanoma that we observed is also consistent with the Danish study (14), which found a nearly 50% excess risk and a trend of increasing SIRs with increasing follow-up. The biologic rationale linking hip implants to melanoma is not clear, and other studies (1517) have not reported this association. However, a large Swedish cohort study (18) has reported that persons with physically demanding occupations, particularly involving outdoor work, are at statistically significantly elevated risk of being hospitalized for osteoarthritis. Thus, individuals with high sun exposure may be over-represented among hip implant patients with osteoarthritis.
Increased rates of multiple myeloma and of bladder cancer have not been observed in earlier studies, possibly because the follow-up periods were too short for such evaluation. The etiology of multiple myeloma is poorly understood, but chronic immune stimulation is thought to play a role (19).Foreign-body implants provoke a variety of immune responses (2023) that persist for the life of the implant; thus, a causal relationship may be plausible. With regard to bladder cancer, no information was available on risk factors, such as cigarette smoking, phenacetin-containing analgesics, and a number of occupational exposures (24); therefore, confounding by these variables cannot be ruled out as an explanation for the excess risk.
Confounding seems a likely explanation for the inverse association with stomach cancer, which could be due to incidental Helicobacter pylori eradication via antibiotic prophylaxis used at the time of hip implant surgery (9,25,26)and/or to frequent use of nonsteroidal anti-inflammatory drugs (NSAIDs) for arthritis and other pain (27,28). It is noteworthy that, in our study, the protective effect was greater for stomach cancer than for colorectal cancer. An antibiotic effect on H. pylori infection should be specific for stomach cancer, while NSAIDs have been shown to protect against both stomach and colorectal cancers (27,29,30). Further evidence suggesting an antibiotic effect comes from a study in Denmark (14), where a lowered risk of stomach cancer was found among patients with osteoarthritis who underwent hip implant surgery (presumably exposed to both NSAIDs and antibiotics) but not among those who did not have surgery (presumably exposed only to NSAIDs). Also, Akre et al. (26)recently showed a dose–response reduction in stomach cancer risk with increasing weight-adjusted prophylactic antibiotic dose among hip implant patients.
An excess of lung cancer was seen only among implant patients with a hip fracture indication, probably because cigarette smoking is a risk factor for low bone density and associated hip fractures (31,32). A reason for the excess risk of prostate cancer is less clear. Increased contact with the medical system due to hip surgery could increase detection rates for prostate cancer, although we did exclude cancers that were found during the first year of follow-up and it is unlikely that detection bias would be sustained over one to two decades. Confounding by obesity is possible, although the association between obesity and prostate cancer is weak (33). If the association between hip implants and prostate cancer is causal in nature, it could be via exposure to cadmium (34).
Patients with rheumatoid arthritis have been shown to have higher rates of hematopoietic cancers and lower rates of colorectal and possibly stomach cancers (3537). This study provided the opportunity to test these associations in a large group of hip implant patients with rheumatoid arthritis as an underlying condition. Despite the small number of cases, we did find that leukemia and lymphoma were related (albeit statistically nonsignificantly) to hip implantation only among this subgroup of patients. Earlier studies (38,39)have reported associations between hip implantation and hematopoietic cancers. A relatively small (14 286 person-years of observation) cohort study by Gillespie et al. (38) found a statistically significant 68% increased risk of lymphoma/hematopoietic cancer, but patients with a prior diagnosis of cancer were included in the analysis, and the association was primarily seen in the first 2 years of follow-up. Visuri and Koskenvuo (39) reported a statistically significant threefold excess risk of lymphoma/leukemia among hip implant patients with osteoarthritis after 5729 person-years of observation, but again the first year of follow-up largely contributed to the excess. Later studies by the same authors of these early studies (15,17,40), as well as other studies (9,16),have not found evidence linking hip implants to hematopoietic cancers beyond the first year after implantation, although Olsen et al. (14) noted a marginally significant 10% excess. We observed a substantial deficit of colon and rectal cancers, consistent with other studies of patients with rheumatoid arthritis (35,36). High NSAID use among these patients may account for these associations (2930).
Overall, the results of our study are largely reassuring that hip implant patients have similar rates of most types of cancer as the general population. We did find evidence, however, that hip replacement may be associated with an increased risk of melanoma and prostate cancer and with an excess of multiple myeloma and bladder cancer after long-term follow-up. If these associations were causal in nature, they would represent serious public health issues, but we note that causal inference is hindered by the limitations of our study design (and that of other previous record linkage studies that lack information on confounding factors). Still, general impressions can be offered on the basis of an assessment of the overall state of the evidence. Except for our earlier report (9), there is almost no other evidence linking hip implants to prostate cancer risk, and there is no consistency regarding an association with melanoma; given the lack of proposed biologic hypotheses and the multiple comparisons that we performed, chance or confounding bias is a likely explanation for the melanoma and prostate cancer results. However, because this investigation provided the first opportunity to adequately evaluate the long-term cancer-related effects of hip implants, the associations that we observed with bladder cancer and multiple myeloma, while also potentially attributable to chance or bias, should be considered carefully and require further in-depth study.

Table 1.
Characteristics of the 116 727 hip replacement patients and their follow-up
Characteristic Men Women Total 
*Excludes 113 659 person-years observed during the first year of follow-up. 
†Excludes 1377 cases of cancer diagnosed during the first year of follow-up. 
Hip replacement patients, No. 45 249 71 478 116 727 
Diagnosis at index surgery, No. of patients 
    Osteoarthritis 36 263 42 357 78 620 
    Late sequelae after fracture 2573 9601 12 174 
    Acute fracture 1842 8970 10 812 
    Rheumatoid arthritis 1524 4077 5601 
    Other 3047 6473 9520 
Mean age at entry, y 67.7 70.7 69.5 
Median calendar year at entry 1987 1987 1987 
Total person-years at risk 264 493 429 460 693 954* 
Mean years of follow-up 6.8 7.0 6.9 
No. of cancer cases during follow-up 4941 5082 10 023† 
Mean age at cancer diagnosis, y 75.6 76.3 76.0 

Table 2.
Standardized incidence ratios (SIRs) and 95% confidence intervals (CIs) for cancer occurrence among hip replacement patients, stratified by sex
Men Women Total 
Cancer type (ICD-7 code*) No. observed SIR 95% CI No. observed SIR 95% CI No. observed SIR 95% CI 
*World Health Organization (WHO): International Classification of Diseases (ICD). 7th revision. Geneva (Switzerland): WHO; 1957. 
All sites (140–209) 4941 1.02 1.00 to 1.05 5082 0.99 0.96 to 1.02 10 023 1.01 0.99 to 1.03 
Buccal cavity (140–148) 104 1.00 0.82 to 1.22 83 1.11 0.88 to 1.37 187 1.05 0.90 to 1.21 
Esophagus (150) 41 0.74 0.53 to 1.01 34 0.96 0.66 to 1.34 75 0.83 0.65 to 1.04 
Stomach (151) 209 0.85 0.74 to 0.97 168 0.81 0.69 to 0.94 377 0.83 0.75 to 0.92 
Stomach excluding cardia (151) 166 0.78 0.67 to 0.91 157 0.82 0.70 to 0.96 323 0.80 0.72 to 0.89 
Colon (153) 371 1.02 0.92 to 1.13 478 0.90 0.82 to 0.98 849 0.95 0.89 to 1.02 
Rectum (154) 207 0.84 0.73 to 0.96 248 0.96 0.84 to 1.08 455 0.90 0.82 to 0.99 
Primary liver and bile duct (155) 98 1.03 0.84 to 1.26 175 0.98 0.84 to 1.14 273 1.00 0.89 to 1.13 
Pancreas (157) 123 1.00 0.83 to 1.19 169 0.93 0.80 to 1.08 292 0.96 0.85 to 1.07 
Lung (162–163) 353 0.84 0.75 to 0.93 231 1.14 0.99 to 1.29 584 0.94 0.86 to 1.01 
Breast (170) 12 1.59 0.82 to 2.77 1113 0.96 0.90 to 1.01 1125 0.96 0.90 to 1.02 
Cervix (171) — — — 78 0.91 0.72 to 1.14 — — — 
Corpus uteri (172) — — — 249 0.96 0.84 to 1.08 — — — 
Ovary (175) — — — 219 1.04 0.90 to 1.18 — — — 
Prostate (177) 1789 1.16 1.11 to 1.22 — — — — — — 
Kidney (180) 129 1.02 0.86 to 1.22 156 1.26 1.07 to 1.48 285 1.14 1.01 to 1.28 
Bladder (181) 358 1.02 0.92 to 1.13 169 1.15 0.98 to 1.33 527 1.06 0.97 to 1.15 
Malignant melanoma of skin (190) 126 1.24 1.04 to 1.48 129 1.06 0.89 to 1.27 255 1.15 1.01 to 1.30 
Skin (nonmelanoma) (191) 278 1.03 0.91 to 1.16 296 1.19 1.05 to 1.33 574 1.11 1.02 to 1.20 
Brain (193) 71 1.05 0.82 to 1.32 101 1.04 0.85 to 1.26 172 1.04 0.89 to 1.21 
Thyroid (194) 0.54 0.22 to 1.11 37 0.93 0.66 to 1.29 44 0.84 0.61 to 1.12 
Bone (196) 0.53 0.06 to 1.93 1.25 0.46 to 2.71 0.93 0.40 to 1.84 
Connective tissue (197) 26 0.99 0.65 to 1.45 29 0.93 0.62 to 1.34 55 0.96 0.72 to 1.25 
All hematopoietic (200–209) 329 0.97 0.87 to 1.08 359 0.97 0.87 to 1.07 688 0.97 0.90 to 1.04 
Lymphoma (200–202, 205) 147 0.97 0.82 to 1.15 159 0.93 0.79 to 1.09 306 0.95 0.85 to 1.06 
Multiple myeloma (203) 91 1.17 0.94 to 1.44 90 1.04 0.84 to 1.28 181 1.10 0.95 to 1.28 
All leukemia (204–207) 91 0.82 0.66 to 1.00 110 0.96 0.79 to 1.16 201 0.89 0.77 to 1.02 

Table 3.
Standardized incidence ratios (SIRs) and 95% confidence intervals (CIs) for cancer occurrence among hip replacement patients, stratified by latency period
Latency period* 
1–4 y 5–9 y 10–14 y ≥15 y 
Cancer type (ICD-7 code†) Observed SIR 95% CI Observed SIR 95% CI Observed SIR 95% CI Observed SIR 95% CI 
*Person-years of observation in each strata: 1–4 years, 353 235; 5–9 years, 226 614; 10–14 years, 85 835; ≥15 years, 28 269. 
†World Health Organization (WHO): International Classification of Diseases (ICD). 7th revision. Geneva (Switzerland): WHO; 1957. 
All sites (140–209) 4790 1.00 0.97 to 1.03 3339 0.99 0.96 to 1.03 1434 1.06 1.00 to 1.12 460 0.99 0.91 to 1.09 
Buccal cavity (140–148) 85 0.97 0.78 to 1.20 60 1.00 0.77 to 1.29 34 1.45 1.00 to 2.02 1.01 0.44 to 2.00 
Esophagus (150) 45 1.02 0.75 to 1.37 19 0.62 0.37 to 0.97 11 0.90 0.45 to 1.62 — 0.00 to 0.91 
Stomach (151) 192 0.87 0.75 to 1.00 130 0.85 0.71 to 1.01 41 0.69 0.49 to 0.93 14 0.71 0.39 to 1.19 
Stomach excluding cardia (151) 167 0.85 0.72 to 0.98 106 0.78 0.64 to 0.95 39 0.74 0.53 to 1.01 11 0.64 0.32 to 1.14 
Colon (153) 400 0.95 0.86 to 1.04 297 0.98 0.87 to 1.10 120 0.96 0.80 to 1.15 32 0.73 0.50 to 1.03 
Rectum (154) 213 0.88 0.77 to 1.01 154 0.90 0.76 to 1.05 65 0.94 0.72 to 1.20 23 0.97 0.61 to 1.45 
Primary liver and bile duct (155) 139 1.04 0.88 to 1.23 87 0.95 0.76 to 1.17 37 1.02 0.72 to 1.41 10 0.83 0.40 to 1.53 
Pancreas (157) 145 0.97 0.82 to 1.14 95 0.93 0.75 to 1.14 43 1.07 0.78 to 1.44 0.67 0.31 to 1.28 
Lung (162–163) 281 0.90 0.80 to 1.01 191 0.92 0.79 to 1.06 86 1.10 0.88 to 1.35 26 1.07 0.70 to 1.57 
Breast (170) 555 0.96 0.88 to 1.04 355 0.92 0.82 to 1.02 163 1.06 0.90 to 1.23 52 0.96 0.72 to 1.26 
Cervix (171) 45 1.02 0.75 to 1.37 23 0.83 0.53 to 1.25 0.39 0.10 to 0.99 1.74 0.64 to 3.78 
Corpus uteri (172) 143 1.10 0.93 to 1.30 71 0.83 0.65 to 1.05 32 0.96 0.66 to 1.36 0.26 0.05 to 0.76 
Ovary (175) 129 1.19 0.99 to 1.41 55 0.80 0.60 to 1.04 25 0.98 0.63 to 1.44 10 1.20 0.57 to 2.20 
Prostate (177) 807 1.14 1.07 to 1.22 652 1.21 1.12 to 1.31 244 1.10 0.96 to 1.24 86 1.15 0.92 to 1.43 
Kidney (180) 134 1.07 0.89 to 1.26 90 1.09 0.88 to 1.34 48 1.54 1.13 to 2.04 13 1.31 0.70 to 2.24 
Bladder (181) 231 0.98 0.86 to 1.11 188 1.11 0.95 to 1.28 75 1.09 0.86 to 1.36 33 1.42 0.98 to 1.99 
Malignant melanoma of skin (190) 108 1.00 0.82 to 1.21 87 1.17 0.94 to 1.44 41 1.37 0.98 to 1.85 19 1.83 1.10 to 2.86 
Skin (nonmelanoma) (191) 261 1.16 1.02 to 1.31 176 0.98 0.84 to 1.13 105 1.28 1.05 to 1.56 32 1.01 0.69 to 1.43 
Brain (193) 99 1.16 0.94 to 1.41 51 0.95 0.71 to 1.25 17 0.86 0.50 to 1.38 0.82 0.27 to 1.92 
Thyroid (194) 20 0.75 0.46 to 1.16 17 0.98 0.57 to 1.57 0.92 0.34 to 2.00 0.47 0.01 to 2.62 
Bone (196) 1.14 0.37 to 2.66 1.07 0.22 to 3.12 — 0.00 to 3.54 — 0.00 to 11.29 
Connective tissue (197) 30 1.08 0.73 to 1.54 18 0.93 0.55 to 1.47 0.65 0.21 to 1.51 0.76 0.09 to 2.74 
All hematopoietic (200–209) 330 0.97 0.87 to 1.08 239 0.99 0.87 to 1.13 90 0.93 0.75 to 1.14 29 0.88 0.59 to 1.26 
Lymphoma (200–202, 205) 150 0.98 0.83 to 1.15 109 1.00 0.82 to 1.21 38 0.86 0.61 to 1.18 0.59 0.27 to 1.11 
Multiple myeloma (203) 88 1.12 0.90 to 1.38 57 1.03 0.78 to 1.33 22 0.99 0.62 to 1.50 14 1.86 1.01 to 3.11 
All leukemia (204–207) 92 0.84 0.68 to 1.04 73 0.96 0.75 to 1.20 30 0.98 0.66 to 1.41 0.59 0.21 to 1.28 

Table 4.
Hematopoietic and digestive cancers among hip implant patients with a rheumatoid arthritis indication*
Cancer type Obs Exp SIR 95% CI 
*Obs = observed number of cases; Exp = expected number of cases; SIR = standardized incidence ratio; CI = confidence interval. 
Hematopoietic cancer 
    All hematopoietic 34 24.56 1.38 0.96 to 1.93 
    All leukemia 11 7.43 1.48 0.74 to 2.65 
    All lymphoma 18 11.68 1.54 0.91 to 2.44 
    Hodgkin's disease 0.92 3.25 0.67 to 9.51 
    Non-Hodgkin's lymphoma 15 10.6 1.41 0.79 to 2.33 
    Multiple myeloma 5.46 0.92 0.30 to 2.14 
    Acute lymphocytic leukemia 0.25 4.01 0.10 to 22.35 
    Chronic lymphocytic leukemia 3.17 1.26 0.34 to 3.24 
    Acute nonlymphocytic leukemia 2.28 2.63 0.97 to 5.73 
    Chronic nonlymphocytic leukemia 0.69 — 0.00 to 5.37 
Major digestive cancers 
    Colon 16 29.18 0.55 0.31 to 0.89 
    Rectum 13 16.57 0.78 0.42 to 1.34 
    Stomach 14 12.92 1.08 0.59 to 1.82 
Funded by the International Epidemiology Institute.

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Sunday, April 8, 2018

GBM

Surgery, radiation and chemo didn’t stop the tumor, but an experimental treatment did


Fritz Anderson and his wife, Carmen Alicia, on a visit to southern Argentina in 2009. More than a year later, the retired cardiologist suffered a seizure that led to the discovery of his malignant brain tumor. (Family Photo)
 
It was hot that Sunday morning in February 2011 in Old San Juan. I had just retired after 40 years of cardiology practice in the suburbs of Washington, and my wife and I were spending the winter in Puerto Rico.
A couple of friends had arrived by cruise ship, and I took them to see the 450-year-old Spanish fortress that sits above the entrance of the harbor. The fortress walls radiated heat, and after reentering the city we walked to our home for a breather and a refreshing ceiling fan. While sitting in the kitchen and sipping a beer, I suddenly passed out. I woke up a bit dizzy and confused; my friend, an internist from Arlington, told me I had had a grand mal seizure.
My wife, Carmen Alicia, called a local friend, also a cardiologist, who sent us to a nearby hospital; there, an MRI exam revealed a small spot on my brain. The neurologist felt it needed to be biopsied to obtain a tissue diagnosis. I immediately returned to Virginia and went to several specialists, who suggested further testing before I decided to have an invasive brain biopsy. I also had a blood test for cysticercosis, an infection that results from eating undercooked pork contaminated with Tenia solium. This common parasite produces cysts all over the body, including the brain. It is the most common reason for seizures in many countries, particularly in India, where children with seizures are first treated for this disease even before other studies are done. My blood test was strongly positive. I started a course of oral medicine to treat it. The test reassured me.
Unfortunately, my spot grew a bit over the course of three months, reaching the size of a grape. A biopsy and excision were now indicated.
The results were terrible. I had a glioblastoma multiforme (commonly called a GBM) grade IV. This is the most malignant brain tumor; no grade II or III exist. A glioblastoma is what killed Sen. Edward M. Kennedy (D-Mass.) in 2009. While rare, it is the most common of the brain tumors. The prognosis is dismal; on average, patients survive only 14 months after diagnosis even with chemotherapy and radiation. After five years, only 5 percent of patients are still alive.
(Arthur E. Giron)
Surgery is tricky, because the brain has the consistency of gelatin and it’s easy to damage neurologically important tissues. I was lucky in that my tumor was easily accessible in the left temporal lobe, and I awoke from surgery six months after my San Juan seizure with all my senses and functions intact.
My oncologist prescribed a regimen of chemotherapy and concurrent radiation for six weeks, to be followed by continuing chemotherapy once my surgical wound healed. But he did not factor in our joie de vivre. Carmen Alicia and I had been married just six months before my seizure — we’re both in our early 70s — and a few months before this crisis I had sent her an e-mail that said nothing but the word “PARIS” 120 times. She got the hint, awakened me one morning just after the surgery and said let’s go have lunch at the Eiffel Tower. So we did. A few days’ delay in treatment wouldn’t hurt me.
We spent the week in the City of Louis XIV, visiting the Isle de la Cite and the Sainte-Chappelle stained-glass windows, taking a bateau-mouche trip on the Seine, touring the Sorbonne and seeing Richard Strauss’s “Salomé” at the lovely Paris Opera auditorium. As a teenager seeing this opera in Buenos Aires, I had been more interested in whether the soprano would remove all of her seven veils in front of King Herod than in the gorgeous music, which I now appreciated to its fullest. We completed the trip by visiting Monet’s garden at Giverny, holding hands and behaving like young lovers.
The life of a patient with a brain tumor has its ups and downs. I decided to have all my white hair cut off, since it was going to fall out in any case. Radiation to the brain starts with a plastic mask (like an Olympic fencing mask) molded to the face and then placed over it and locked to the stretcher. The radiation treatment is not painful, though the mask induces a bit of claustrophobia; luckily, the treatment lasts only 10 to 20 minutes each session. The chemotherapy, though, is another story: It gave me nausea, lethargy, fatigue, general weakness, muscle aches and tingling in my extremities. It also dropped my platelets and white blood counts, requiring weekly blood studies and leaving me vulnerable to bacterial and viral infections.
I began to study this tumor in detail, nearly overwhelmed by the massive medical literature on it: I found that more than 22,000 scientific articles had been written on glioblastoma over the past 40 years. So I concentrated on the most recent 15 years of articles, most of them depressing. It was clear that radiation and chemo, which I was doing, prolonged a typical patient’s life for only a few months. The emphasis now was aimed at modifying molecules in the DNA of the tumor, finding new chemotherapeutic agents. I also found a few articles discussing viruses as a possible treatment for GBMs, but only mouse studies had been done.
Why me?
Why did this tumor happen to me? I never smoked and had had no brain injuries, and there is no history of such tumors in my family. As a cardiologist, I had implanted close to 400 pacemakers in my life and during the procedure was exposed to ionizing radiation (X-rays). In the early days we used portable X-ray machines and gave ourselves some protection by using thin lead gowns. Nowadays, heavy lead gowns are worn, and doctors and technicians protect their thyroid and eyes with shields and glasses. We also use heavy sheets of radiation-protective glass that hang from the ceiling.
At some point in my research, I was surprised by an article by a Johns Hopkins-trained cardiologist who now practices in Israel. He had collected data on 23 invasive radiologists and cardiologists who had developed tumors, of which 17 were GBMs on the left side of the brain. I wrote to the author, who told me that he had learned of several more such cases since his article was published, and he added mine to his file.
During lulls in the chemo/radiation cycles, my wife and I escaped as often as we could to Old San Juan, where she has a home. We sang and danced at the San Sebastian Festival, a huge street bacchanal that is celebrated in January each year. Once, we escaped to my native city, Buenos Aires, and found that the International Tango Festival was happening. Though we don’t dance tango well, we marveled to see the world’s best dancers on the parquet floors. The final day is celebrated on a pedestrian street when more than 1,000 couples dance tango in unison. I often felt tired, but I just sat down when I needed to.
From mice to men
The Preston Robert Tisch Brain Cancer Center at Duke University has the largest experience on the East Coast with my sort of tumor, so I went there for further consultation and treatment.
As doctors there examined me, it was obvious that my tumor had already grown again; in fact, it had quadrupled in size since my initial chemo and radiation. I was offered several treatments and experimental protocols, one of which involved implanting a modified polio virus into my brain. (This had been very successful in treating GBMs in mice.) Duke researchers had been working on this for 10 years and had just received permission from the FDA to treat 10 patients, but for only one a month. (A Duke press release last May explained that the treatment was designed to capitalize “on the discovery that cancer cells have an abundance of receptors that work like magnets in drawing the poliovirus, which then infects and kills the cells. The investigational therapy . . .uses an engineered form of the virus that is lethal to cancer cells, while harmless to normal cells. The therapy is infused directly into a patient’s tumor. The virus-based therapy also triggers the body’s immune system to attack the infected tumor cells.”)
After thinking about this, reviewing the animal studies and discussing it with my wife and children, I decided to do it, becoming the second patient enrolled in the study. I was, of course, worried; during my youth I had seen a lot of polio in Argentina and knew well the ravages of this virus on the neurological system. Now I was having this virus implanted into me.
The procedure
I was given the Salk polio vaccine to prevent a systemic polio infection. Three weeks later, in May 2012, I was ready for my operation. We decided to enjoy the trip from Washington to Duke. We spent two nights in a fancy B&B in Richmond and visited the Virginia Museum of Fine Arts, where my wife, who has a PhD in medieval history, found a 15th-century painting from Bruges and I enjoyed seeing the largest collection of Faberge eggs in an American museum.
At Duke, my skull was opened under local anesthesia and I had the viral infusion dripped through a small catheter directly into the tumor in my brain for six hours.
It is difficult not to get depressed when you are a cancer patient, confronting such things as writing a will or even one’s obituary, all the while dealing with the emotional response of family and friends.
For me, classical music, a passion all my life, has been particularly helpful in those down moments. Beethoven’s quartet Opus 131, Schubert’s piano quintet “The Trout” or a symphony by Mahler helped a lot, though too much Mahler would induce his weltschmerz in me. I switched to Mozart or Liszt at those moments.
I returned to Duke a month after the infusion, and though an MRI showed some expected swelling, the more significant fact was that the tumor had stopped growing. I have gone back to Duke every two months since then, and the tumor, initially the size of a grape, is now a scar, the size of a small pea. It’s been two years since the initial biopsy and radiation, and one year since the experimental polio viral treatment, and I have no evidence of recurrence nor tumor regrowth.
According to a presentation about the research that the Duke doctors gave last May, the results so far are promising: “The first patient enrolled in our study (treated in May 2012) had her symptoms improve rapidly upon virus infusion (she is now symptom-free), had a response in MRI scans, is in excellent health, and continues in school 9 months after the return of her brain tumor was diagnosed. Four patients enrolled in our trial remain alive, and we have observed similarly encouraging responses in other patients. One patient died six months following . . . infusion, due to tumor regrowth.” They added: “Remarkably, there have been no toxic side effects . . . whatsoever, even at the highest possible dose.”
That has been true for me. I feel as fit as I was three years ago, before the first symptoms of the glioblastoma made their appearance. I remain only on an anti-
seizure medication. This fall, my wife and I will travel to Chile and Argentina. Of course we will try a pisco sour in Chile and a fine Malbec in Argentina. We shall continue dancing and enjoying our lives as intensely as ever — perhaps more so — even though at times it may just be dancing a slow bolero in the kitchen.
As the immortal Chilean poet and composer Violeta Parra wrote: “Gracias a la vida que me ha dado tanto.” Thanks to Life, which has given me so much.
Andersen practiced cardiology for 35 years in Arlington and Fairfax with the Virginia Heart Group.