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ISDS 2016 Conference Abstracts

Builiding Methods for a Proactive Prescription Drug 
Surveillance System
Fan Xiong*1, 2
1CDC / CSTE Applied Epidemiology Fellowship Program Class of XIII, Atlanta, GA, USA; 2Kansas Department of Health and 
Enviroment - Topeka, KS, Topeka, KS, USA

Objective
This study aims to show the application of longitudinal statistical 

and epidemiological methods for building a proactive prescription 
drug surveillance system for public health.

Introduction
Prescription Drug Monitoring Programs (PDMPs) are operating in 

49 states and several U.S. territories. Current methods for surveillance 
of prescription drug related behaviors, include the mean daily dosage 
of morphine milligram equivalent (MME) per patient, annual 
percentage of days with overlapping prescriptions per patient, and 
annual multiple provider episodes for multiple controlled substance 
prescription drugs per patient that are described elsewhere.1,2 This 
work builds on these efforts by extending longitudinal methods 
to prescription drug behavior surveillance in order to predict risks 
associated with prescription drug use.

Methods
Schedule II prescription opioids from January 1, 2014 to February 

29, 2016 from the Kansas Tracking and Reporting of Controlled 
Substances (KTRACS) was used for this analysis. Prescription opioids 
were linked to the 2016 version of the morphine milligram equivalent 
conversion table from the National Center for Injury Prevention 
and Control.3 Population estimates were based on the 2015 County 
Vintage single-year of age bridged-race estimates from the National 
Center for Health Statistics and used to calculate age-adjusted rates. A 
daily high dose opioid prescription was defined as having greater than 
or equal to 90 morphine milligram equivalent. Since this is a unit-day 
measure with patients experiencing multiple daily high dose opioid 
days, the Prentice, William, and Peterson (PWP) recurrent event 
model was used to estimate the number of high-dose opioid days for 
Kansas patients by gender and age groups.4,5 Start time was the first 
prescription date with a high-dose opioid and stop time was the next 
high-dose opioid date during a study period from January 1, 2014 
to Feb 29, 2016. The PWP model is a statistical model that allows 
for the estimation of covariates on an event history (i.e. total time 
with prescription opioids, specifically high-dose opioids). Analysis 
was completed with a stratified Cox-proportional hazard model, 
sandwich covariance for dependent observations, and statistical 
significance was assessed with a Wald Chi-square. PROC PHREG 
in SAS/STAT(R) 14.1 was used since it has a new FAST option for 
fitting large proportional counting process hazard model.

Results
The age-adjusted rate of daily high-dose opioid patients was  

3.2 patients per 100 Kansas population-year (95% CI: 3.1 – 3.2). 
Kansas patients aged 85 and older had the highest age-specific rate 
of 11.7 (95% CI: 11.5 –11.9). Preliminary recurrent event analysis 
shows on average nearly a quarter of approximately 50 million 
Schedule II opioid patient days were high-dose opioid patient days 
among 785,514 Kansan patients with any prescribed opioid history. 
In an initial result stratified by the number of high-dose opioid days 
and adjusting only for age, males on average had approximately 7% 
higher hazard of recurrent Schedule II high-dose opioid prescription 
days than females (β: 0.07, S.E: 0.002, p<0.0001). Kansas patients 

aged 45 to 54 compared to Kansas patients 85 and older on average 
had approximately 14% higher hazard of recurrent Schedule II high-
dose opioid prescription days (β: 0.14, S.E: 0.007, p<0.0001).

Conclusions
This work demonstrates the application of survival analysis 

techniques to estimate the population at risk for high-dose opioids, 
which varies by the length of the total opioid prescription history. Early 
results from the recurrent event analysis showed that Kansas male 
and patients aged 45 to 54 years had the longest history of high-dose 
opioids. Annual cross-sectional population estimates may incorrectly 
estimate the estimated risk of high-dose prescription opioids since 
it assumes all patients have the same prescription history. PDMPs 
are longitudinal databases. Survival analysis methods like recurrent 
event models can leverage the longitudinal structure to more precisely 
estimate risk statistics. Future work includes incorporation of health 
outcomes data and further prescription covariates to assess the timing 
and intensity of opioid potency escalation.

Keywords
Prescription opioids; morphine milligram equivalent; prescription 
drugs

Acknowledgments
This work was supported in part by an appointment to the Applied 
Epidemiology Fellowship Program administered by the Council of State 
and Territorial Epidemiologists (CSTE) and funded by the Centers for 
Disease Control and Prevention (CDC) Cooperative Agreement Number 
1U38OT000143-03. Dr. Belle Federman at the Kansas Department of 
Health and Environment for best methods to communicate the findings 
of this study.

References
1. Paulozzi LJ, Strickler GK, Kreiner PW, Koris CM. Controlled substance 

prescribing patterns—prescription behavior surveillance system, eight 
states. 2013. MMWR Surveill Summ. 2015 Oct 16;64(9):1-4.

2. Definitions of PBSS Measures. Brandeis’ University Center
of Excellence for Prescription Drug Monitoring Program’s
Prescription Behavior Surveillance System. Available at http://www.
pdmpexcellence.org/sites/all/pdfs/Definitions%20of%20PBSS%20
Measures.pdf

3. National Center for Injury Prevention and Control. CDC compilation
of opioid analgesic formulations with morphine milligram equivalent 
conversion factors, 2016 version. Atlanta, GA: Centers for Disease 
Control and Prevention. 2016. Available at http://www.pdmpassist.
org/pdf/BJA_performance_measure_aid_MME_conversion.pdf.

4. Prentice, R. L., Williams, B. J., and Peterson, A. V. (1981), “On the
Regression Analysis of Multivariate Failure Time Data,” Biometrika, 
68. 373–379.

5. Amorim LD, Cai J. Modelling recurrent events: a tutorial for analysis
in epidemiology. International journal of epidemiology. 2015 Feb 1. 
44(1):324-33.

*Fan Xiong
E-mail: fxiong@kdheks.gov

Online Journal of Public Health Informatics * ISSN 1947-2579 * http://ojphi.org * 9(1):e13, 2017