To the Editor,

I read with interest the article by Karlsen, et al. concluding that here was an association between clinically significant uterine fibroids and pre-term birth. (1) The study has several significant shortcomings. The likely inaccuracies of the use of a large retrospective, administrative, coded database and the low prevalence of fibroids only identified clinically and not confirmed by ultrasound or other imaging modality were mentioned by the authors in the limitations section of the article. However, the degree of these limitations makes the data uninterpretable and the conclusions unfounded.

Administrative databases are inadequate to answer clinical questions as they are subject to clinical misdiagnosis and coding errors which are blind to the goals of the study. The only way to assure accuracy of such a data set is to adjudicate the data by chart review, which was not done by the authors.

Reliance on clinical examination to determine the presence of uterine fibroids, especially submucous fibroids that might more significantly impact pregnancy, is inaccurate. (3) Virtually all women in the developed world currently have an ultrasound as part of their early pregnancy evaluation. Most studies using ultrasound for the diagnosis of fibroids in early pregnancy report a prevalence of 3-4%. One such study found that among 64,047 pregnant women, 2058 had fibroids diagnosed with 1st trimester US, a prevalence of 3.2%. (Stout)

The current study captured 124 women with fibroids coded among 92,696 pregnancies, for a prevalence of 0.13%. If we assume that the prevalence of fibroids is approximately that found in other studies, then we would expect to find 2,966 pregnancies with concurrent fibroids in the Karlsen study. Therefore, 2,842 pregnancies were likely undetected clinically or improperly coded and thus misclassified as not having fibroids. The authors suggest that mistakenly including women with fibroids in the control group would attenuate the association between fibroids and pregnancy outcomes. I disagree. If these women had adverse outcomes, the findings would be diluted by the outcomes of the other 89,730 pregnancies. However, if the women had favorable outcomes, then that data would significantly decrease the adverse outcome conclusions reported in this study. To emphasize this point, 95% of the data is missing and basing any conclusions on this degree of incomplete data is misleading and irresponsible.

Another important question considered in this study, which remains controversial in the literature, is whether myomectomy prior to pregnancy improves outcomes. However, based on the inaccurate data, I am disappointed that no conclusions can be made for this or any other fibroid-related pregnancy outcome the authors attempted to study.

William H. Parker, MD
Department of Ob Gyn and Reproductive Sciences
UC San Diego
La Jolla, California

Email: w1parker@health.ucsd.edu

(1) Karlsen K, Schiøler Kesmodel U, Mogensen O, Humaidan P, Ravn P. Relationship between a uterine fibroid diagnosis and the risk of adverse obstetrical outcomes: a cohort study. BMJ Open. 2020;10:e032104
(2) L. Flickinger, G. D’Ablaing III, D.R. Mishell Jr. Size and weight determinations of nongravid enlarged uteri Obstet Gynecol, 68 (Dec (6)) (1986), pp. 855-858
(3) Stout MJ, Odibo AO, Graseck AS, Macones GA, Crane JP, Cahill AG. Leiomyomas at routine second-trimester ultrasound examination and adverse obstetric outcomes. Obstet Gynecol. 2010;116:1056-63.

Katzke et al. conducted a prospective study to assess the relationships of alkaline phosphatase (ALP), gamma-glutamyltransferase (GGT), alanine aminotransferase (ALT), aspartate transaminase (AST) and the De Ritis ratio (AST/ALT) with mortalities (1). There were significant positive associations of all-cause mortality with ALP, GGT and AST. In addition, a combined liver risk score had positive associations with all-cause and cause-specific mortality. I have two concerns about their study.

First, Oh et al. conducted a cross-sectional study to investigate the association between renal hyperfiltration and serum ALP level (2). Renal hyperfiltration was defined as exceeding the age- and sex-specific 97.5th percentile, and odds ratio (95% confidence interval [CI]) of the highest ALP quartile for renal hyperfiltration was 1.624 (1.204-2.192). Higher ALP levels are significantly associated with renal hyperfiltration, and renal hyperfiltration was closely associated with several metabolic disorders. As renal hyperfiltration can be considered as early-stage of renal damage, serum ALP level might be related to renal damage. Mechanism of the association should be specified by further study.

Second, Kunutsor et al. conducted a meta-analysis to evaluate the associations of baseline levels of liver enzymes with all-cause mortality in general populations (3). The pooled relative risks (95% CI) per 5 U/l increment in GGT and ALP levels were 1.07 (1.04-1.10) and 1.03 (1.01-1.06), presenting linear dose-response relationships. As the magnitude of effect sizes are not so large, further studies are required to verify the association.

References

1. Katzke V, Johnson T, Sookthai D, et al. Circulating liver enzymes and risks of chronic diseases and mortality in the prospective EPIC-Heidelberg case-cohort study. BMJ Open. 2020;10(3):e033532. doi: 10.1136/bmjopen-2019-033532

2. Oh SW, Han KH, Han SY. Associations between renal hyperfiltration and serum alkaline phosphatase. PLoS One. 2015;10(4):e0122921. doi: 10.1371/journal.pone.0122921

3. Kunutsor SK, Apekey TA, Seddoh D, et al. Liver enzymes and risk of all-cause mortality in general populations: a systematic review and meta-analysis. Int J Epidemiol. 2014;43(1):187-201. doi: 10.1093/ije/dyt192

We read Dr. Karlsen’s paper entitled “Relationship between a uterine fibroid diagnosis and the risk of adverse obstetrical outcomes: a cohort study” with great interest. We understand the authors evaluated a large and complicated set of data and appreciate their effort. However, the authors used a database fraught with errors without validation of said database, made incorrect assumptions and conclusions about the data, and incompletely discussed some of the major queries in the discussion.

The first issue surrounds the use of the Danish National Birth Cohort, Patient Registry and Birth Registry. Although the authors write about the limitations of a registry that uses codes “more closely connected to hospital budgets than hospital diagnosis codes”, they rely on a single study to prove the quality of their database.

Multiple authors have shown that administrative databases are inadequate to answer clinical questions. They are are set up for billing purposes only, not epidemiological research (1,2), and elaborate statistical machinations do not overcome the impact of anomalous data (3). Several studies have shown that the very registry used in this report; the Danish National Patient Registry, is highly inaccurate from a clinical standpoint. The authors from a study in 2009 have a self-proclaimed 10% inaccuracy rate in their diagnoses addressing oral contraceptive research (4). Other authors have found higher erroneous rates for diagnoses of hypertension, rheumatoid arthritis and uterine rupture (5). Another independent review of the database revealed a 41% misclassification rate in women with alleged hormone-related thromboembolic events (6) In fact, in 2010, Shapiro et al (7) recommended ignoring data from unconfirmed data base reports, citing unreliable data from the Danish National Patient Registry.

The attempt by the authors to compare women with symptomatic uterine fibroids is laudable, as this has not been covered in the existing literature, but unfortunately it is not clear that they were able to accomplish this. Simply having a diagnostic code for “fibroid” does not ensure that the fibroid was indeed symptomatic; in fact, an unknown number may have been given the diagnosis due to ultrasound detection in the absence of symptoms. Unfortunately, the authors did not attempt to validate this assumption.

There are other issues with this manuscript. Hysteroscopic myomectomy was presumed if the operation codes included “resection and excision of pathological tissue”, but we do not know this to be the case, and again no attempt at validation was conducted by the authors. When a fibroid diagnosis was given, there was no concern regarding number or size of fibroids, both potential confounders that were not corrected for in the regression analysis. Finally, the authors included women with multiple separate pregnancies, stating that this was valid due to “robust standard errors”. Which standard errors were robust, how robust were they, and why did this correct for an obvious methodologic flaw of including some women multiple times?

The conclusions reached by the authors regarding preterm delivery and caesarean section are incompletely reviewed in the discussion. To date, ten studies have addressed the effect of fibroids on the rate of preterm delivery, with six showing an increased risk with fibroids and four showing no difference. However, five of the six that adjusted the risk ratio for known confounders found an increase, similarly found this study (8). Including this information would have strengthened their findings. Regarding caesarean section, 13 of 15 published studies show an increase in the presence of fibroids, including all 11 studies that adjusted for confounders via regression analysis (as does this manuscript) (8). The authors, however, do not focus on cesarean sections that were acute in nature; these were not different between the two groups. This is an interesting and novel finding, implicating surgeon or patient choice as the driving force behind increased cesarean sections in women with fibroids.

Whether myomectomy prior to pregnancy improves outcomes for women and their children is the crucial unanswered question in the current literature. The authors state that risk of preterm birth is decreased, and cesarean section rates increased among women with untreated fibroids compared with women with surgical excision. However, this appears to be based upon raw numbers and not statistical analysis, as the two groups (fibroids in situ versus fibroids removed) were never compared. At first glance, it appears that there is no significant difference between these groups for any outcome measure, although without appropriate statistical analysis we cannot be sure. This shortcoming diminishes the value in addressing this important issue.

In conclusion, this paper has important methodologic flaws, and deficient conclusions. We would be interested in further publications from these authors.

(1) Grimes DA. Epidemiologic research using administrative databases. Obstet Gynecol 2010;116(5):1018-19.
(2) Grimes DA. Epidemiologic research with administrative databases: red herrings, false alarms and pseudo-epidemics. Hum Reprod 2015;30(8):1749-52.
(3) Ault MR. Combating the garbage-in, gospel-out syndrome. Rad Protect Manage 2004;20:26-30.
(4) Lidegaard O, Lokkegaard, E, Svendsen AL, Agger C. Hormonal contraception and risk of venous thromboembolism: national follow-up study. BMJ 2009;339:b2890.
(5) Pedersen M, Klarlund M, Jacobsen S, Svendsen AJ, Frisch M. Validity of rheumatoid arthritis diagnoses in the Danish National Patient Registry. Eur J Epidemiol 2004;19:1097-1103.
(6) Severinsen MT, Kristensen SR, Overvad K, Dethlefsen C, Tjonneland A, Johnsen SP . Venous thromboembolism discharge diagnoses in the Danish National Patient Registry should be use with caution. J Clin Epidemiol 2010;63:223-8.
(7) Shapiro S, Dinger J. Risk of venous thromboembolism among users of oral contraceptives: a review of two recently published studies. J Fam Plann Reprod Health Care 2010;36:33-8.
(8) Pritts EA, Olive DL. Fibroids and reproduction. In Modern Management of Uterine Fibroids. Cambridge University Press, 2020.

Sincerely and Appreciatively,

Elizabeth A. Pritts
David L. Olive