Data collection

The investigation was carried out by analysing records pertaining to Dutch routine general practice and hospital outpatient treatment settings. Data were obtained from the IMS Health's longitudinal prescription database (Lifelink, affiliate Capelle ad IJssel, the Netherlands).13 This data source consists of anonymous longitudinal prescription records from a representative sample of pharmacies and dispensing general practitioners, covering 73% of the Dutch nationwide medication consumption of outpatients and primary care patients. The computerised medication-dispensing histories contain data regarding dispensed medications, type of prescriber, dispensing date, dispensed amount of medication, prescribed dosage and length of prescription. Data for each patient were anonymously and independently sampled without linkage of prescriptions to the same patient across pharmacies because patients in the Netherlands are usually loyal to a single pharmacy.14 Furthermore, research from the Dutch Foundation for Pharmaceutical Statistics (SFK) revealed that in the Netherlands, almost all patients make use of a pharmacy located in their area of living. Eighty-two per cent of patients are living in a radius of 3 km from their pharmacy.15 Potential bias caused by patients getting hospitalised, moving to another address or dying was minimised by studying chronic pharmacological pain treatment because there were dispensing records for these patients during the whole study period.

Patient groups

Patient selection started with the identification of chronic users of analgesic medication during a 6-month prescription period (hereafter: observation period). Chronic use was defined as in receipt of analgesic pharmacotherapy during at least two distinct moments covering an interval of at least 2 months. In order to track medication for other therapeutic indications (ie, psychotropic medication and pharmacotreatment for somatic disorders), patients were observed for a period of 6 months prior to initiation of analgesic treatment. Next, the cohort with chronic use of analgesics was divided into two groups. Starters were defined as patients who had not received any analgesics during the 6-month period prior to the observation period (hereafter: Starter group). Patients who continued with pain medication that was already prescribed in the 6 months before the observation period formed the second group (hereafter: Continuation group). The latter group consisted of all patients who had already received analgesics in the first month of the 6-month period prior to the observation period in order to define chronic analgesic treatment before observation. All data captured a calendar period from May 2008 to September 2009 (figure 1).

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Figure 1

Starter group and Continuation group of chronic analgesic treatment. Schedule of prescriptions (Rx) in the Starter group (top) and the Continuation group (bottom) of chronic analgesic treatment covering a 12-month period. Months 7–12 are the observation period; months 1–6 are the pre-observation period. Patients in the Continuation group received the first prescription of analgesics in month 1 of the pre-observation period; there was no follow-up whether analgesics were continued over the entire 6-month interval prior to the observation period. The Starter group did not use any analgesics during the 6-month interval prior to the observation period.

Data were obtained from the LRx database from months 1–12 as depicted in figure 1. Use of other medications (eg, psychotropic medication and medication for a broad spectrum of somatic conditions) was collected for all patients as well, covering the period of 12 months, consisting of (1) the pre-observation period (months 1–6) and (2) the observation period (months 7–12).

Escalation of pharmacological pain treatment

All individual prescriptions of analgesics were observed for each patient in both the Starter and the Continuation groups during the observation period and during the 6 months prior to the observation period. At each dispensing date, analgesics were classified a priori in five levels in order of analgesic potency (figure 2). Five escalation levels were provided, based on a minor adaptation of the three-step WHO analgesic ladder.16 Levels 5 and 4 are identical to WHO steps 3 (strong opioids) and 2 (weak opioids), respectively. WHO step 1 (non-opioid analgesics) was refined in order to enable further and clinically relevant differentiation between non-opioid analgesics (level 1: paracetamol, level 2: prostaglandin inhibitors and level 3: anticonvulsants).16–20 Furthermore, anti-epileptics were divided in anticonvulsants predominantly prescribed in pain conditions (level 3a: gabapentin and pregabalin) and anticonvulsants with best evidence for epilepsy treatment (level 3b: carbamazepine, valproic acid and lamotrigine).19–21 In order to avoid prescription for indications of mood stabilisation or epilepsy, the latter group was classified at level 3b only if prescribed in combination with analgesic medication at level 1 or 2 (ie, pain indication) (figure 2).

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Figure 2

Five levels of analgesic potency, modified from the WHO analgesic ladder.16 Level 1 (ie, lowest potency) to level 5 (ie, highest potency). (a) Gabapentin and pregabalin in the absence of other anti-epileptic drugs. (b) Carbamazepine, valproic acid and lamotrigine in combination with medication at level 1 or 2. (c) Tramadol and codeine. (d) Methadone, oxycodone, hydromorphone, morphine, buprenorphine, fentanyl, sufentanil and pethidine.

Confirmation of escalation was based on the comparison of analgesic potency at the first dispensing day and the last dispensing day within the observation period.

The comparison of the first and the last prescription of analgesics resulted in the following categories of analgesic escalation: neutral (ie, no change of analgesic potency), escalation in analgesic treatment (ie, change to a higher level of analgesic potency) or de-escalation in pharmacological pain treatment (ie, change to a lower level of analgesic potency) (table 1).

If patients received several analgesics on the same day, both the highest and the second highest level of analgesic potency were included in the analyses in order to define escalation categories (eg, a change from level 5 plus level 2 to level 5 plus level 3 indicating that escalation had occurred).

Determinants of escalation in analgesic treatment

Three groups of variables hypothesised to act as mediators or confounders were included in the analyses. The first group were patient characteristics such as sex (0=male, 1=female), age (in years) and the location of patient's pharmacy (defined by postal code). The latter variable defined the level of urbanisation following the definition of the Dutch Central Bureau of Statistics (CBS). Conform previous work, and in line with the classification developed by CBS, level of urbanisation was defined as the number of addresses relative to area surface.22 Level 1 (ie, highest level of urbanisation) consists of more than 2500 addresses/km² (level 2=1500–2500 addresses/km², level 3=1000–1500 addresses/km², level 4=500–1000 addresses/km²). Level 5 (ie, rural environment) consists of <500 addresses/km², described in more detail elsewhere.23 Moreover, neighbourhood deprivation was defined dichotomously (0= no, 1= yes). The dichotomous measure of neighbourhood deprivation was developed by the Netherlands Institute of Research in Healthcare (NIVEL) using socioeconomic indicators such as unemployment rate, average income, population density and ethnic variation. On the basis of empirical research in the Netherlands, NIVEL's neighbourhood deprivation index (NDI) is calculated as follows: NDI = ((ln percentage unemployed people − 3.0236)/0.37 706) − ((ln average income − 2.8641)/0.14 441) + ((ln population density − 7.0132)/1.06 699) + ((ln percentage people of ‘non-western’ ethnicity)/1.11 147). NDIs were expressed continuously by NIVEL from low to high. Furthermore, NIVEL defined a dichotomous measure of deprivation at a cut-off of 5.5% (ie, 885 000 people) in order to assess trends in the proportion of the Dutch population inhabiting an area with the highest NDI and for use in epidemiological research.24 Healthcare professionals receive higher levels of funding for their services in these deprived areas.25 Neighbourhood deprivation was associated with level of urbanisation: 86% of the sample living in deprived neighbourhoods lived in an area with the highest level of urbanisation. The other patients (14%) living in deprived neighbourhoods lived in an area with the second highest level of urbanisation. The majority (76%) of those living in an area of the highest level of urbanisation did not live in a deprived neighbourhood (table 1).

Furthermore, psychotropic co-medication was classified into its different classes, and somatic co-medication was similarly grouped in 10 classes (ACE inhibitors and angiotensin II inhibitors; antidiabetics; β-blockers; calcium antagonists; functional bowel drugs; laxatives; migraine medication; respiratory medication; steroid antiphlogistics; stomach protectors) (tables 1–3). In the Starting group, occurrence of co-medication was time coded at three levels according to the day of first occurrence (ie, co-medication prescription before start with analgesics at the same day or after start of analgesic treatment) (table 3). In the Continuation group, occurrence of co-medication was recorded dichotomously (presence/absence) since it was impossible to distinguish occurrence of co-medication as before or at start of analgesic treatment (table 4).

Statistical analysis

First, we analysed the pattern of (de-) escalation in analgesic treatment by means of an ordered logistic multivariable regression model with adjusted ORs (and 95% CI) using SAS V.9.26 Statistical significance for the model was defined at conventional α of 0.05. The dependent variable in this model was the development of a patient's analgesic treatment (de-escalation, neutral, escalation). Independent variables, entered simultaneously in the model, were demographic characteristics, neighbourhood deprivation, and urbanisation, use of psychotropic medication and use of somatic medication. In the Starter group, we also included first occurrence of co-medication. The modelling strategy was to build, first, a fully saturated model (including all variables) in order to avoid missing relevant information by leaving out non-significant variables. Second, backward elimination was carried out to find the best model fit.

Models for the Starter and Continuation groups were run separately, given different sample selection criteria. The ordered logistic multivariable regression model was chosen above the multinomial model, as the latter does not consider the natural order in our data regarding development of chronic pain treatment, ranging from de-escalation to neutral to escalation. Proportional odds were assumed in the models of escalation and de-escalation of analgesic treatment and analyses inspected for violation of this assumption. Test on the proportional odds assumption showed significance, which gave us the confidence to use the ordered logistic model. If a determinant was positively associated with escalation of analgesics, absence of this variable was associated negatively with escalation or positively with de-escalation in analgesic treatment (and vice versa). This offered advantage compared with separate models for escalation and de-escalation (such as consistency of model estimates) and avoided double use of patients with a neutral development of analgesic treatment.