Resource allocation for depression management in general practice: A simple data-based filter model

Breanne Hobden, Mariko Carey, Rob Sanson-Fisher, Andrew Searles, Christopher Oldmeadow, Allison Boyes

Competing Interests: The authors have declared that no competing interests exist.

https://doi.org/10.1371/journal.pone.0246728, Volume: 16, Issue: 2, Pages: 1-11

Article Type: research-article Article History

Publisher: Public Library of Science

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Table of Contents

Background
Methods
Results
Conclusions
Introduction
Materials and methods
Results
Discussion
Conclusions

Abstract

Background

This study aimed to illustrate the potential utility of a simple filter model in understanding the patient outcome and cost-effectiveness implications for depression interventions in primary care.

Methods

Modelling of hypothetical intervention scenarios during different stages of the treatment pathway was conducted.

Results

Three scenarios were developed for depression related to increasing detection, treatment response and treatment uptake. The incremental costs, incremental number of successes (i.e., depression remission) and the incremental costs-effectiveness ratio (ICER) were calculated. In the modelled scenarios, increasing provider treatment response resulted in the greatest number of incremental successes above baseline, however, it was also associated with the greatest ICER. Increasing detection rates was associated with the second greatest increase to incremental successes above baseline and had the lowest ICER.

Conclusions

The authors recommend utility of the filter model to guide the identification of areas where policy stakeholders and/or researchers should invest their efforts in depression management.

Hobden,Carey,Sanson-Fisher,Searles,Oldmeadow,Boyes,and Kuo: Resource allocation for depression management in general practice: A simple data-based filter model

Introduction

Depression is the most prevalent mental health illness worldwide and has demonstrated a 50% increase in incident cases from 1990–2017 [1]. Depression is among the leading causes of disease burden worldwide and is associated with a high economic burden [2–5]. Depression also impacts quality of life, as it has been associated with unemployment, adverse impacts on personal relationships, economic disadvantage and homelessness [6–8].

In many developed countries, primary care plays a central role in the management of depression [9–11]. The role of primary care is multifaceted and includes diagnosis, management and/ or referral to specialist mental health professionals such as psychiatrists, psychologists or clinical social workers. Given the important role of primary care practitioners in provision of mental health care, there is significant interest in developing ways to improve outcomes for people with depression within this setting. While there are evidence-based treatments for depression, there may be barriers which prevent those in need from receiving the care needed to optimise outcomes. Therefore, there is potential to improve outcomes by implementing strategies to improve care at specific points in the treatment trajectory. The key points in the care pathway include increasing the proportion: 1) of people who are accurately identified as depressed by their doctor; 2) who are offered evidence-based treatments; and 3) of patients who adhere to the recommended treatment.

A meta-analysis indicated that only 47% of people who are depressed are recognised as such by their general practitioner (GP) [12]. Similarly, our study involving over 1,500 Australian primary care patients found that GPs identified only 51% of patients with elevated depression scores on the Patient Health Questionnaire (9-items) as having clinically significant depressive symptoms [13]. Several factors may also impede GPs in offering evidence-based treatments to people with depression. Providers commonly report barriers related to inadequate skills to manage depression, as well as the time required to provide intensive psychological therapies [14–16]. When evidence-based treatments are offered, the effectiveness of such treatments may be hindered by poor patient adherence. Patients with depression have been found to be more likely to be non-adherent to prescribed treatments than those who are not depressed [17–20].

With increasing competition for the health dollar, there is interest among policy stakeholders in identifying priority research and investment areas. While complex mathematical modelling is typically the norm in decisional analytics [21], the level of sophistication required to use such methods may be prohibitive for decision or policy-makers and researchers without access to expertise [22]. A simplified decisional tool that could guide the identification of areas where policy stakeholders and/or researchers should invest their efforts seems warranted. Such a tool was developed by members of the research team [23, 24]. The model is derived from a decision tree concept, using a logic modelling approach to filter data through the sequence of steps associated with treatment outcomes in healthcare settings. The relationship to a decision tree is based on the filter model’s use of cost and outcome at key junctures. The model can be used to compare costs and patient outcomes for two or more scenarios. The application of the model in this paper is intended to highlight how the tool could be applied to compare the effectiveness and cost-effectiveness of intervention strategies for improving depression outcomes in primary care.

Aim

To illustrate the potential utility of a simple filter model in understanding the patient outcome and cost effectiveness implications for depression interventions in primary care.

Materials and methods

The development of the model has been described in detail elsewhere [23, 24]. The model is targeted at users without specialised economics or statistical skills or knowledge. It is underpinned by theoretical and modelling principles of decision trees and cost-effectiveness analysis to create a decisional analytic framework. Modelling is conducted using an Excel spreadsheet with built-in calculations for a series of steps. The user will follow the steps as outlined below.

Steps 1–3: Identify the relevant group data

Population: define and quantify the population of interest (e.g., general population, certain age cohorts);

Target group: define and quantify the target of the intervention (e.g., depressed individuals);

Setting attendance: enter the proportion of the target group attending the setting of interest (e.g., depressed individuals attending primary care);

Steps 4–6: Adding the filters representing different intervention scenarios

When the user enters the relevant proportions for the following steps, the number of persons at each level in the model is calculated and used as output in the subsequent step. For example, the calculated number of persons of the target group attending the setting of interest who are detected for the condition of interest (step 4) are used as the starting figure for reach and adherence (step 5).

4Detection: the proportion of the target group attending the setting of interest who are detected for the condition of interest. An intervention can be applied here to increase detection using relevant intervention effect (increase in proportion detected) and cost estimates.

5Reach and adherence: the following are estimated by the user. An intervention can be applied at each of these steps with the relevant intervention effect (increase reach or adherence proportions) and cost estimates required.

Reach: The proportion of individuals with the condition of interest who are offered treatment by their healthcare provider;

Adherence: The proportion of individuals with the condition of interest who would comply with the offered treatment;

6Effect on outcome: for a dichotomous outcome measure of treatment success, specify the expected proportion of those that are offered the intervention that will achieve a successful outcome following the intervention.

The outputs derived from the above data are outlined in Table 1.

Table 1

Model outputs and calculations used to derive outputs.

Outcome Data	Calculation
Cost per participant exposed to the intervention	(Total cost of the intervention(s) under a scenario across all targeted patients) (Number of patients who are offered the intervention)
Cost per successful outcome	(Total cost of the intervention(s) under a scenario across all targeted patients) (Number of patients who achieve a successful outcome)
Incremental cost compared to baseline	(Total cost of detection and intervention across all patients in one scenario)	-	(Total cost of detection and intervention across all patients for baseline or usual care)
Incremental number of successes compared to baseline	(Number of patients who achieve a successful outcome under a scenario)	-	(Number under baseline or usual care)
Incremental cost effectiveness ratio (ICER)¹	(Incremental cost compared to baseline). (Incremental number of successes compared to baseline)
Policy advice	The model provides a summary of whether each scenario is more or less expensive (in terms of the incremental cost) and more or less effective (in terms of the number of successful outcomes) compared to baseline or usual care.

¹The ICER is the ratio of the change in cost to the change in effectiveness between each scenario and usual care. This metric can be used to compare the relative cost-effectiveness of different alternatives against the cost and consequences of usual care.

Data analytic procedures: Application of the filter model to depression treatment

To demonstrate the potential utility of the decision analytical filter model for improving depression outcomes, data for four scenarios, including ‘usual care’, and three hypothetical conditions, are presented. A successful outcome for the following scenarios was defined as an individual reaching ‘remission’, i.e., below threshold depression levels. The baseline scenario attempted to model standard care in the identification and treatment of depression for primary care patients, using data drawn from the literature (see Table 2). This scenario assumed no interventions were implemented and that usual care was provided. The three hypothetical scenarios represent an improvement above usual care in each of the filters. An estimation of the intervention effect and relevant costs associated with achieving these improvements were entered into the model. While efforts were made to draw these estimates from the literature, the aim of the model, in its current status, is to illustrate hypothetical scenarios. Further, the population and target group can be adjusted for different countries, regions or settings. The Australian population has been used in the model presented for illustrative purposes, however, the derived data is drawn from international references. Filter one, i.e., detection, examined an intervention aimed at increasing detection of depression in primary care. This involved administering a free validated depression measure to primary care patients electronically using a touchscreen computer upon presentation to their appointment. Filter two, i.e., reach, involved increasing the offer of evidence-based depression treatment from providers. This intervention is based on training and support for GPs in appropriate management of depression. Filter three, i.e., adherence consisted of increasing patient adherence to offered treatment. This involved a telephone intervention to monitor the progress of patients undergoing treatment for depression and provide adherence strategies. All filters were assumed to operate independently from one another, for example an increase in the proportion of patients detected for depression did not increase the proportion of patients offered treatment by GPs. Dollar amounts are presented in Australian Dollars (AUD).

Table 2

Model parameters and output under usual care and three hypothetical intervention scenarios.

Step	Definition	Proportion	Unit Cost of intervention	No. of persons
(1) Population	Australian population aged 18-75yrs	n/a		15,055,403
(2) Target group	Current depression ^a	8.9%		1,339,931
(3) Opportunity for Detection	Proportion of target group attending GP at least once per annum ^b	81%		1,085,344
(4) Detection	Proportion detected as at risk
	Baseline: (no intervention) ^c	47%	$0	510,112
	Filter 1: (intervention: implementation of routine screening for depression) ^d	77%	$5	835,715
	Filter 2: (no change to baseline) ^c	47%	$0	510,112
	Filter 3: (no change to baseline) ^c	47%	$0	510,112
(5) i. Reach	Proportion detected who were offered treatment
	Baseline: (no intervention) ^e	28%	$0	142,831
	Filter 1: (no change to baseline) ^e	28%	$0	234,000
	Filter 2: (GP intervention: education and training) ^f	69%	$247	351,977
	Filter 3: (no change to baseline) ^e	28%	$0	142,831
(5) ii. Adherence	Proportion detected, offered treatment who are adherent
	Baseline: (no intervention) ^g	51%	$0	72,844
	Filter 1: (no change to baseline) ^g	51%	$0	119,340
	Filter 2: (no change to baseline) ^g	51%	$0	179,508
	Filter 3: (Patient intervention: telephone follow-ups) ^h	65%	$98	92,840
(6) Effect on outcome	Proportion achieving remission at 6 months follow-up
	Baseline: (no intervention) ⁱ	37%	$0	26,952
	Filter 1: (no change to baseline) ⁱ	37%	$0	44,156
	Filter 2: (no change to baseline) ⁱ	37%	$0	66,418
	Filter 3: (no change to baseline) ⁱ	37%	$0	34,351
MODEL OUTCOMES
Cost/exposure	Cost per participant exposed to intervention
	Baseline:	$0
	Filter 1:	$5
	Filter 2:	$247
	Filter 3:	$98
Cost/outcome	Cost per successful outcome
	Baseline:	$0
	Filter 1:	$95
	Filter 2:	$1,309
	Filter 3:	$265
Incremental cost	Incremental cost compared to baseline
	Filter 1:	$4,178,574
	Filter 2:	$86,938,336
	Filter 3:	$9,098,352
Incremental number successfully treated	Incremental number of successes compared to baseline
	Filter 1:	17,204
	Filter 2:	39,466
	Filter 3:	7,399
ICER	Incremental cost effectiveness ratio
	Filter 1:	$243
	Filter 2:	$2,203
	Filter 3:	$1,230

Active intervention components at relevant steps are bolded.

Results

Table 2 presents the data inputs for each of the steps used in the model’s hypothetical scenarios. The literature used to inform the filters are presented as footnotes in Table 3.

Table 3

References and explanation for data used in the model (footnotes refer to those used in Table 2).

Footnote and description	Reference and notes
(a) Depression prev	• ABS 2015 [25].
(b) Size of target group attending GP	• ABS 2013 [26]: Data is for the proportion of the Australian population aged 15 years and over who attend a GP at least once annually.
(c) Detection: baseline	• GP detection of depression was assumed to be 47% based on detection rates reported by Mitchell (2009) [12].
(d) Detection: intervention	• An increase in detection of 30% (from 47% to 77%) was based on studies indicating the sensitivity of the PHQ-9 screening test to be 88% accurate in detecting depression [27]. This increase in detection was slightly reduced to account for false positives.
(d) Detection: intervention	• For an iPad waiting room screening intervention, a cost of $5 per person screened was estimated.
(e) Reach: baseline	• Offer of treatment was assumed to be 28% based on findings reported by Rost (2001) [28].
(f) Reach: intervention	• A 41% (from 28% to 69%) improvement rate for offering treatment was used based on intervention data reported by Rost, 2001[28] for training and educating GPs in depression management.
(f) Reach: intervention	• Costing for the intervention to improve treatment provisions was based on Pyne, 2003 [29] which indicated that implementation and training costs of the GP training intervention were $247 per person.
(g) Adherence: Baseline	• Adherence to depression treatment was assumed to be 51% based on findings reported by Dietrich (2004) [30].
(h) Adherence: Intervention	• Dietrich 2004 [30] found a 14% (from 51% to 65%) improvement in ≥1 follow-up appointments at six-months follow-up. While this study did not directly measure adherence to a particular treatment, attending additional follow-ups was used as a proxy measure for this.
(h) Adherence: Intervention	• Simon 2009 [31] estimated a telephone management intervention project to cost $98 per patient.
(i) Treatment effectiveness	• Six-month remission rates were derived from Dietrich 2004 [30], which found the intervention group to have a 37% remission rate. As remission was derived from those who adhered to treatment in step (f), the intervention group statistics were used for this filter.

Table 2 highlights the findings of the hypothetical interventions applied in the filter model for managing depression in primary care. All three filters were found to be both more effective and more expensive than baseline. Filter one, involving a waiting room intervention to increase detection rates for depressed patients, resulted in an estimated increase of 17,204 patients reaching remission at six-months follow-up (compared to baseline), at an estimated cost of $95 per successful outcome. Filter two, consisting of an intervention to educate and train GPs in better management of depression, resulted in an estimated increase of 39,466 patients with depression reaching remission at six-months follow-up (compared to baseline) and cost $1,309 per successful outcome. Filter three, involving a telephone intervention to improve patient adherence to depression treatment, resulted in an estimated increase of 7,399 patients with depression reaching remission at six-months follow-up (compared to baseline) and costs $265 per successful outcome.

When examining incremental costs of each filter (as compared to baseline), filter one was the least expensive filter option with an incremental cost of $4,178,574 and an ICER of $243. Filter two was the most expensive filter with an incremental cost of $86,938,336 and an ICER of $2,203.

Discussion

Primary care presents a unique opportunity to identify and assist individuals who may be experiencing depression. Nevertheless, scarcity in funding for service delivery requires careful consideration of where to invest research funds and healthcare budgets. The simple filter model used in this paper can help to inform decisions behind such allocation to reduce reliance on opinions or assumptions of decision-makers. The utility of the model in its application to hypothetical interventions for depression in primary care highlights its potential usefulness.

Comparison with existing literature

Interestingly, the findings of the model in the example above indicated that filter one, which aimed to increase detection through a screening intervention using touchscreen computer tablets, was the most cost-effective filter. While there is some contention regarding screening for depression in primary care [32–34], this method of intervening represents a relatively low cost and low maintenance strategy while greatly increasing the number of successes in the hypothetical scenarios. Further, the considerable investment placed on technological health advancements [35], including mobile health [36, 37], could provide opportunities to explore remote screening options via smartphone messages and apps that link in with primary care medical records. This approach could be conducted automatically and notify healthcare providers if their patients are at-risk of depression, which would further reduce hardware and personnel time associated with in-clinic screening. Electronic screening options therefore present a feasible intervention option to improve administration rates of depression treatment. While interventions relating to reach and adherence are important areas to examine, the greater level of intensity required to undertake these interventions, as well as a smaller proportion of patients accessed, resulted in much higher ICERs for these interventions. As previously stated, the findings presented from the model are intended to be illustrative, however, where possible, the data were drawn from the literature. Therefore, the approach of targeting and comparing these different filters within primary care still warrant consideration.

Strengths and limitations

Use of the model should be considered in light of its limitations. Firstly, the information derived from the model is only as strong as the input data provided. It is therefore limited by any inaccuracies or biases that exist in the studies the data is derived from. Further, some data used in the model were based on research which was more than ten years old. This was due to the model requiring specific information to meet the parameters, such as intervention costs per person, relevant targeted interventions (e.g., provider training) and binary study outcomes (e.g., remission rates). While this limited the data available for use, the parameters of cost and outcome are of high importance to policy and health services decision makers. This limitation is also a strength of the model, as outcomes and costs for a single intervention can also be compared when there is uncertainty in key parameters. Nevertheless, future decision-makers utilising the model to allocate large amounts of resources may consider applying quality checklists to included studies, such as the risk of bias criteria from the Effective Practice of Care (EPOC) collaboration [38] to ensure relevant information can be drawn from high quality research trials.

Additionally the model assumes that intervening at one filter does not alter rates at other filters. For instance, in the worked example, training GPs in depression management may increase the quality of the information provided to patients or improve the likelihood of GP follow-up, which may inadvertently increase patient adherence to treatment. Furthermore, incorporating the complexity of certain conditions in to this simple model is difficult. For example, depression is associated with different levels of severity and treatment pathways differ based on this severity. The presented model only accounted for intervention-related costs and did not include health care costs associated with severity of illness and hence, increased treatment intensity, healthcare provider time, nor the patient perspective in estimating costs. Severity of conditions and health care costs could be considered in future applications of the model. The model is also not able to account for inaccuracy of detection, such as false positives and false negatives and therefore issues such as unnecessary treatment and intervention were not considered. A further strength of the model is its ability to let the user enter a range of values for key input parameters. Hence, the user can vary the value of any of the filter model’s input parameters that might be associated with meaningful levels of uncertainty. This then produces a range of outcome values (or boundaries) that can be considered in decision making.

Implications for research and/or practice

This theoretical filter model, developed using economic cost-effectiveness principles, has the potential to influence discussions on resource allocation involving decision or policy-makers for depression management in primary care. The simplicity and accessibility of the filter model represent the strengths of this approach. It is stored within a Microsoft Excel file and can be used by individuals without specialised skills, including those working within relevant care settings for depression. While the model can be applied at a national level, as was demonstrated in this paper, it could also be used to make decisions at a local level such as within a singular health services. Further, using this tool to examine depression could be expanded beyond the primary care setting to specialised mental health or hospital settings. Such an application of the tool could be used to examine the ICER of different aspects of treatment being offered by these services. The calculator is cost-free which makes it a feasible option for health care facilities to optimise cost-effective treatment outcomes.

Input data required for the tool should be evidence-based regarding target populations, reach and effectiveness. Generally, these data are likely to be available in the scientific literature and population health reports. However, another useful aspect of this model is that it highlights gaps in the current literature that prevent examining certain aspects of selected care pathways. For instance, when considering the depression literature examined, there was a lack of economic analysis reported for intervention studies undertaken. While the effectiveness of interventions in improving depression outcomes is of great importance, the cost-effectiveness is equally valuable for determining the feasibility of implementing research findings in to actual care. Future research examining depression interventions in primary care should carefully consider this aspect of research.

Conclusions

This study highlights the utility of a simple and free filter model to conduct cost-effectiveness analysis for depression management in primary care, without complex software or specialised statistical or economic skills. Given the substantial economic burden of depression and ongoing competition for limited health care resources, there is a need to focus on strategies that optimise depression outcomes. The use of evidence-based information to assist with decision-making in these circumstances is an important undertaking. The authors recommend utility of the filter model to individual health services, researchers and decision-makings at a policy or funding level, to help inform future strategies for the management of depression in healthcare settings.

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