Impact of 30-day prescribed opioid dose trajectory on fatal overdose risk: A population-based, statewide cohort study

We analyzed statewide time-to-event data in a cohort comprising all patients ages 12 and older with any opioid prescription recorded in California’s prescription drug monitoring program database between March 1 and December 31, 2013. Our primary independent variable was a categorical, time-varying indicator denoting the trajectory of patients’ prescribed daily opioid dose over the previous 30 days. Our dependent variable was fatal opioid overdose during the subsequent 15 days measured using California death certificate records. Patients’ trajectories and outcomes were assessed in 15-day intervals through December 31, 2013. We chose 2013 because, prior to the 2016 CDC guidelines, both overall opioid prescribing and variation in prescribed opioid dose were much greater than they are today, increasing our ability to examine the inherent risks associated with dose changes. Moreover, most opioid-related deaths in 2013 involved prescription rather than illicit opioids; overdoses involving illicit synthetic opioids, particularly fentanyl, were rare in California before 2016.²⁹

This study was approved by the California Committee for the Protection of Human Subjects and the University of California, Davis Institutional Review Board.

Controlled substance prescription data were obtained from California's prescription drug monitoring program, which contains records for all outpatient Schedule II-IV prescriptions dispensed in California. In addition to prescriber and pharmacy identifiers, each prescription record included date dispensed, National Drug Codes, quantity, strength per unit, days’ supply, patient sex, date of birth, name, and address.

Statewide death certificate records were obtained from the California Department of Public Health. Each record was linked to the CDC’s Multiple Cause of Death file, which assigns one ICD-10 code for the underlying cause of death and up to 20 additional ICD-10 codes for contributing causes of death to each death certificate.

We linked 2013 death certificate and prescription drug records using The Link King,³⁰ a publicly available SAS record linkage program that performs deterministic and probabilistic linkage³¹ and performs well on prescription drug monitoring program data.³² We first assigned a unique identifier to each death record and then identified all prescription records that matched to each death record. We then linked all prescription records not already associated with a death record that the program identified as belonging to the same person. We used the resulting patient-level file to identify our study cohort.

Our cohort included all patients in California who filled any Schedule II-IV opioid analgesic prescription between March 1 and December 31, 2013, and who were between 12 and 111 years old when they filled their first prescription. Data from other projects³³ indicate that 98% of opioid prescriptions in November and December 2012 had days’ supply ≤30. We therefore chose March 1, 2013, as the earliest inclusion date because it was the first date for which we had complete data on prescribed opioid dose for both the date of assessment and the date 30 days previously. We excluded prescriptions to animals, duplicate prescriptions, prescriptions with missing fill date, with missing or zero quantity, or prescriptions filled after a patient’s date of death (see Fig. 1).

Our dependent variable was a drug overdose death involving any opioids as defined by the CDC³⁴: specifically, any underlying cause of death code indicating drug poisoning (X40-X44, X60-X64, X85, Y10-Y14) and any multiple cause-of-death code indicating opioids (T40.0, T40.1, T40.2, T40.3, T40.4, or T40.6). In a sensitivity analysis, we used overdoses involving prescription opioids (i.e., by excluding overdoses that involved heroin, T40.1) as the dependent variable. Patient status and all time-varying independent variables were assessed in 15-day increments.

Our primary, time-varying independent variable was prescribed daily opioid dose. We calculated patients’ daily dose using standard conversion factors⁴ to calculate total prescribed dose in MME and then dividing that total by the prescription’s days’ supply. When patients had multiple active opioid prescriptions, we summed the daily dose for all prescriptions. Consistent with CDC recommendations, we set the conversion factor for buprenorphine (2% of all opioid prescriptions) to zero because of its unique pharmacodynamics and risk profile.^{4, 35} Finally, we grouped daily dose into 4 ordinal categories: 0-29 MME, 30-59 MME, 60-89 MME, and ≥90 MME. To evaluate the impact of 30-day prescribed opioid dose trajectories, we created a 16-level variable for all possible combinations of patients’ current daily dose and their daily dose 30 days previously, using the same 4 categories for each.

We identified additional independent variables through a literature review and our own prior work.^{33, 36} Patient sex (male, female, unknown) and age (12-24, 25-64, ≥65) were analyzed as fixed variables. All other variables were time varying.

Additional opioid-related independent variables included indicators for whether patients had 1) any active opioid prescription, 2) two or more active opioid prescriptions, 3) any active prescription for a long-acting opioid formulation, 4) any active prescription for a liquid opioid formulation, and 5) any active prescription for a transdermal opioid (i.e., non-pill, non-liquid) formulation. A categorical variable for opioid type (hydrocodone, oxycodone, morphine, buprenorphine, codeine, fentanyl, methadone, hydromorphone, other, multiple types) was also included. Tramadol was not added to Schedule IV until 2014 and so was not included in our study data.

To account for risks associated with receiving opioids from multiple prescribers and pharmacies, we included indicator time-varying variables identifying whether patients had active prescriptions 1) written by two or more different prescribers and 2) filled by two or more different pharmacies.

To account for risks associated with concomitant use of other controlled substances, we included time-varying indicator variables identifying whether patients had an active prescription for 1) any benzodiazepine, 2) carisoprodol, 3) any psychostimulant, and 4) any Z drug (zolpidem, eszopiclone, or zaleplon).³⁷ We included a 4-level variable describing the combination of patient’s current benzodiazepine status with their status 30 days previously.

We began by examining monthly counts of our outcome variable versus the month of each patient’s first opioid prescription and the distribution of independent variables among patients who did versus did not experience a fatal opioid overdose.

We then constructed a time-varying Cox proportional hazards model to examine the relationships between 30-day prescribed opioid dose trajectory and fatal overdose risk. Follow up time was measured from the day of each patient’s first opioid dose on or after March 1, 2013, until the patient first experienced the outcome, died of some other cause, or reached the end of the study period. The follow up period ranged from 0 to 305 days.

To construct the model, we first added patient age, sex, and 30-day prescribed opioid dose trajectory as independent variables. We then added other opioid-related prescription-level variables, prescriber- and pharmacy-level variables, and finally, variables for other controlled substance prescriptions. We parameterized the model based on avoiding multicollinearity and optimizing overall model fit by minimizing Akaike information criterion. We explored models that measured daily opioid dose using both quantity of pills and MME per day; MME-based models were superior. We chose cutoffs for ordinal opioid dose categories that reflected clinically relevant dose intervals; models with categories for higher doses (e.g., ≥120 MME) had wide confidence intervals and poor model fit due to influence from outlier values. When adding a new variable caused major changes in other parameter estimates, we examined variable distributions to determine why the estimates changed. The optimal parameterization for many independent variables was binary indicator variables. For example, parameterizing overlapping prescriptions using number of days of overlap did not improve model fit compared to using a binary variable indicating whether patients had two or more active opioid prescriptions. We constructed separate tables of parameter estimates for the 16-level trajectory variable to facilitate examining the impact of 30-day change in daily opioid dose on overdose risk. We used the same model for both primary and sensitivity analyses.

Data preparation and analyses were conducted using SAS 9.4 and R 4.2.1.