2.1 Operational Research as a Collection of Modelling Techniques

Operational research (referred to as operations research in the USA) can be viewed as a collection of conceptual, mathematical, statistical, and computational modelling techniques used for the structuring, analysis, and solving of problems related to the design and operation of complex human systems. These techniques range from approaches that systematically map the perspectives of individuals, professions, or organisations impacted by the problem being addressed, through to approaches for building and experimenting with a highly detailed mathematical or computational analogue of a healthcare service. A common element in these techniques is that the operational researcher, at some point in the course of their work, develops a ‘model’ of the system or problem.

The term model means different things to different people. Pidd gives the following definition for what operational researchers mean by a model in his excellent book Tools for Thinking: Modelling in Management Science:

We note that Pidd explicitly avoids the term ‘improvement’ in his definition, to acknowledge that an improvement from one perspective may constitute a worsening from another equally valid perspective. That said, many of the techniques introduced in this Element assume that the purpose of change is clear and agreed. As we will discuss, this can limit the acceptability of operational research techniques in some healthcare contexts.

Although a definition of operational research as a collection of certain modelling techniques works at one level, it is incomplete. The list of techniques deployed by operational researchers evolves over time and many people may use one or more of the techniques without identifying what they do as operational research. Indeed, the set of techniques used in operational research includes the theory of constraints and overlaps with those used in systems engineering, operations management, and industrial techniques such as Lean (see the Elements on systems mapping,Reference Komashie, Kotiadis, Lamé, Clarkson, Dixon-Woods, Brown and Marjanovic⁵ operations management approaches,Reference Lewis, Vasilakis, Dixon-Woods, Brown and Marjanovic⁶ and Lean and associated techniques for process improvementReference Radnor, Lean, Dixon-Woods, Brown and Marjanovic⁷). To understand what binds the collection of techniques into a discipline, it is useful to cover the origins of operational research.

2.2 The Wartime Origins of Operational Research

Some of the techniques that comprise operational research were in use before the 1930s, for instance in the analysis of telecommunication networks and in the industrial time-and-motion studies of Taylor and others.Reference Clark, Spender and Kijne⁸ However, the term operational research was coined, and the discipline forged, immediately before and during the war effort of the Allied powers in the 1939–45 conflict of World War II.Reference Crowther and Whiddington⁹ Growing out of research related to the use of radar, academic scientists from different disciplines (including physicists, chemists, and geneticists) worked with the armed forces to frame and tackle the problems they faced, many of them related to the efficient deployment of resources. For example, one problem was to determine the optimal size of merchant convoys in the Atlantic Ocean that would minimise the losses of craft to submarine attacks given a fixed availability of escort vessels. Another was how to increase the flying time of aircraft providing cover to convoys during attacks.

Figure 1 gives some indication of the importance attached to operational research at the end of the war, with the 1947 HMSO publication Science at WarReference Crowther and Whiddington⁹ giving as many pages to discussing operational research as it does to the atomic bomb.

Figure 1 Front cover and table of contents of the 1947 HMSO publication Science at War,Reference Crowther and Whiddington⁹ showing the billing given to operational research

Cover design by Eileen Evans. Document held by The National Archives. Contains public sector information licensed under the Open Government Licence v3.0.

2.3 Operational Research as More than a Collection of Techniques

Key to the success of operational research during the war was the acknowledgment by scientists that while they had expertise in data analysis and in using scientific methods to understand complex physical or biological systems, they did not understand warfare. To be useful, they needed to spend time listening to, learning from, and working alongside staff at all levels of the armed forces.

This was epitomised by Patrick Blackett, a professor of physics (and 1948 Nobel Prize winner) who served during the war as scientific adviser to the commander in chief of anti-aircraft command and as director of operational research for the admiralty. His wartime principles for effective operational research, reproduced by Royston,Reference Royston¹⁰ included that it should be both:

• collaborative: ‘An operational research section should be an integral part of a command and should work in the closest collaboration with the various departments at a command’

• grounded: ‘All members of an operational research section should spend part of their time at operational stations in close touch with the personnel actually on the job’.

This recognition – that collaboration with workers at different levels of organisations and respecting their knowledge and experience are crucial – characterised the successful use of operational research across many industries in the postwar period, with large operational research groups formed within the coal and steel industries and in the railways.

In this sense, operational research is better defined as an ethos of problem framing and solving: applying scientific method and modelling techniques in collaboration with problem owners and subject experts to help understand and change the operation of complex organisations to some defined purpose. The textbook description of an operational researcher is someone who helps decision-makers frame their problem in a way amenable to systematic, rational analysis and then deploys the right tool for the job to solve the problem at hand. In reality, individual operational researchers rarely have proficiency across the whole spectrum of operational research approaches.

2.4 A Selection of Operational Research Approaches

In this section, we give a brief comparative account of several key approaches from the operational research toolkit, highlighting some of their applications in healthcare. For simplicity, we have grouped these into broad categories based on whether the primary intent of using the approach is to solve a well-defined decision problem with an agreed objective, to account for multiple perspectives on a problem, or to describe the behaviour of a system. We then discuss the use of combined approaches and the development of hybrid models.

2.4.1 Approaches for Solving Well-Defined Problems

First, we introduce the concept of optimisation. A frequently used example is the manufacture of cylindrical tin cans. Both the surface area and the volume of a cylinder can be calculated as functions of its height and the radius of the circular ends. Optimisation techniques can be used to identify for the manufacturer the single combination of height and radius that minimises the surface area of tin used to contain a given volume of soup (see Figure 2A).

Figure 2 Examples of problems amenable to operational research

OR = operational researcher

A key step in many of the approaches outlined in this Element is defining, for the sake of analysis, the purpose of the modelled system. This chimes with the focus of other improvement methods on defining what ‘good’ looks like and addressing the question: ‘how will we know if we’ve made an improvement?’ In operational research, this often involves writing down an ‘objective function’, which is a mathematical expression to quantify a key aspect of system performance. For a tin can, this is the equation expressing the surface area of the can in terms of its height and radius. In healthcare applications, this might be the distance travelled by a district nurse in terms of the order in which patients are visited (Figure 2B), or the duration of a clinic depending on the sequence of patients (Figure 2C).

Mathematical Programming

Mathematical programming is a group of optimisation techniques designed to identify how a system can be optimised by changing those features of a service considered to be under the control of decision-makers (called the design parameters or decision variables). A set of equations is constructed to relate the decision variables to the objective function and to other aspects of the system considered important (for instance, resource constraints or performance standards that must be met). A step-by-step process of calculation (called an algorithm) is deployed to identify a set of values for the decision variables that achieve the highest (or lowest) value for the objective while meeting the constraints. The algorithms used in mathematical programming are proven to work only for objective functions where the relationships between decision variables and objectives and constraints are relatively simple. Even then, they can be impractical for problems with a very large number of decision variables and constraints. Some problems in healthcare, while theoretically amenable to mathematical programming, would take many hours or even days or weeks of computer time to solve using these methods, which is too long if the problem needs to be solved on a daily basis. In such circumstances, researchers often turn to heuristic approaches, as described in the following paragraphs. For an overview of mathematical programming and other optimisation approaches applied in healthcare, see Crown et al.Reference Crown, Buyukkaramikli and Thokala¹¹

Heuristics and Heuristic Search

Heuristic approaches to problem-solving involve devising a set of rules to be applied, often iteratively, for obtaining acceptable solutions to problems, typically without any guarantee of finding an optimal solution. For the district nurse in Figure 2B, a simple heuristic would be to iteratively apply a rule of visiting the nearest patient they have not yet visited. Heuristic problem-solving has particular value in areas of scheduling and transportation and in staff rostering (see the discussion on nurse rostering in acute settings in Section 4.5).

Heuristic search is an alternative approach to improving the performance of a modelled system, in which a set of rules guides an iterative search of possible combinations of decision variables for a particular problem. Again the intent is to find a sufficiently good solution within acceptable computational time, without a guarantee that the solution is optimal.

2.5 Preparatory Steps to Modelling

As indicated, operational research comprises a wide range of approaches. The approach that an operational researcher might recommend for supporting a given improvement initiative depends on several factors. These include the nature of the service to be improved, the decisions and decision processes to be informed, the budget and time available for model development, and a degree of personal taste or comfort on the part of the operational researcher.

However, a unifying feature of operational research is that whatever modelling approach an operational researcher favours or chooses in a particular instance, a preparatory step in most operational research exercises is in-depth discussion of the problem as presented by clinicians and managers.Reference Pagel, Banks and Pope^33,Reference Harper and Pitt³⁴ This typically involves site visits, shadowing and non-participant observation of relevant processes, and asking stupid and not-so-stupid questions. In our view this is an essential component of any high-quality piece of work. The operational researcher may wish to analyse exploratory data to check the self-diagnosis of the client organisation. This can often lead to useful insights for all parties. Indeed, sometimes a large proportion of the value added by an operational research exercise can be in this learning process and to have a problem studied from an operational researcher’s perspective.

4.1 Use of Simulation Modelling to Improve Acute Stroke Care

In 2010, a hospital in the south-west of England was concerned that too few of its new stroke patients were being treated with the thrombolytic drug alteplase.Reference Monks, Pitt, Stein and James⁴⁴ At that time, alteplase was licensed for use only among patients who could be treated within 3 hours of onset of a confirmed ischaemic stroke. Within this 3-hour time window, a patient had to get to hospital, be identified as a likely stroke victim, and, crucially, have an MRI scan to rule out a haemorrhagic stroke (administering alteplase to a patient whose stroke is due to bleeding rather than to a clot would be catastrophic). The required time standard was met and thrombolysis administered in only 4% of stroke patients and the stroke team felt that the hospital could and should be doing better.

The acute stroke team worked with a team of operational researchers. Early discussions suggested that stroke patients were often caught up in congestion and delays within the hospital’s emergency department, which generated some ideas for improvement. The operational research team built a discrete event simulation model to investigate the roots of the problem and estimate the likely impact of possible changes. They began by modelling the flows of acute stroke patients at the hospital up to and including the MRI scan and the commencement of any thrombolysis. Importantly, they converted the process measures (receipt of thrombolysis and time to thrombolysis) obtained through the simulation to a clinical measure of long-term disability outcome. In addition to these measures, they used the simulation to estimate the level of stroke team call-outs and high-priority MRI scans.

The simulation approach allowed the operational research team to account for time-of-day and day-of-week effects observed in emergency department processes and the availability of MRI scans. The simulation software generated animations of patient flow that facilitated feedback from clinicians on the completeness and accuracy of the workflows depicted. In discussion with the stroke team and a lead emergency department clinician, the operational research team used the simulation to explore the potential impact of having a triage clinician in the emergency department applying a screening tool to identify likely stroke patients, with the intention that likely candidates could then be referred directly to the stroke team, bypassing other processes in the emergency department. When other emergency department clinicians reviewed these analyses, they suggested that ambulance staff could also apply the screening tool and send a pre-alert for the stroke team to see the patient on arrival.

Using the simulation, researchers assessed the potential impact of these two interventions (screening followed by immediate stoke referral at triage in the emergency department, and screening by ambulance staff followed by pre-alert to the stroke team) alone and in combination with extending the time window for thrombolysis from 3 hours from stroke onset to 4.5 hours, as well as extending the eligibility criteria for thrombolysis to include people over 80 years old. The findings suggested that these changes could increase the level of thrombolysis treatment from 3% of all stroke patients other than existing inpatients (current practice) to 8.5% (screening and referral at emergency department triage), 10.4% (pre-alert from ambulance crew), or up to 22.8% (pre-alerts in combination with extending treatment time window and extending to the over-80s).

For many operational research studies, this is where the story would end. However, in this case, the hospital acted on the findings. They implemented stroke screening and referral at emergency department triage in December 2011, and worked with the local ambulance trust to introduce a stroke screening and pre-alert system in August 2012. Along the way, results from an international trial prompted the extension of thrombolysis to the over-80s.

The operational research team analysed process times and the proportion of stroke patients who were thrombolysed between January 2009 and August 2013. This analysis showed a 40% reduction in process times and an increase from 4.7% of all strokes thrombolysed in the period before the introduction of screening at emergency department triage to an average of 11.5% in the period after. Some of this increase was due to the extension of thrombolysis to the over-80s, but the increase of thrombolysis from 3.8% to 6.9% among patients under 80 whose stroke occurred outside the hospital showed the benefit of faster processes.Reference Monks, Pearson, Pitt, Stein and James⁴⁵

The redesign of the acute stroke pathway at this hospital was a success, and the simulation modelling was important in allowing teams to safely experiment with different candidate interventions in silico and in providing a focus for discussions among the stroke team, physicians in the emergency department, and the ambulance trust. The simulation model was also valuable as a communication aid in explaining the work to other nearby trusts and led to similar exercises at four other hospitals.

4.2 Location of Urgent Care Centres

A recent example of location analysis in healthcare was the siting of urgent care centres in Cornwall, England.Reference Chalk⁴⁶ The Sustainability and Transformation Partnership for Cornwall needed to provide urgent care while reducing demand at the county’s emergency department. The partnership decided to establish urgent care centres in the county, but did not know how many to provide or where they should be sited.

The 13 locations in the county that already offered some form of urgent care were considered as candidate locations for a substantial urgent care centre. The partnership judged one of these candidates to be an obvious choice because of the existing services at that site. They also acknowledged that some Cornish residents would use urgent care providers in their neighbouring county.

The operational researcher working with the partnership used a form of location–allocation optimisation analysis to inform these decisions. Using 3 years’ worth of data on the home postcode of patients receiving urgent care, they built a computer model that allowed evaluation of any proposed configuration of urgent care centres. A configuration was defined by choosing how many and which of 12 sites to use alongside the one obvious choice and three centres in the bordering county. Each configuration was evaluated on the weighted mean travel time between the centre of postcode districts in the county and the nearest urgent care centre under that configuration. The contribution from each postcode was weighted by the historic demand for urgent care among patients resident in that postcode.

By evaluating every possible configuration, the researcher identified the relationship between the number of urgent care centres and average travel times, and was able to identify the best combination of sites if a fixed number were chosen. Informed by this analysis, the partnership chose to establish three urgent care centres in the county and sited them at the locations identified by the model. The analysis predicts a patient will travel on average for 19 minutes. This analysis includes caveats, notably an assumption that patient journeys start from the home address, but it was a systematic way for decision-makers to explore one important facet of this facility location problem.

The analysis was facilitated by the limited number – 4,096 – of possible configurations of urgent care centres in Cornwall, making it feasible to evaluate each one. For larger-scale problems, this isn’t the case. King et al. explored the location of specialist paediatric intensive care retrieval teams in England and Wales, choosing between 8 and 12 locations from a possible 35.Reference King, Ramnarayan, Seaton and Pagel⁴⁷ This corresponds to over 1.5 billion possible configurations. In such cases, optimisation and heuristic search techniques of operational research are computationally efficient ways to find very good or optimal combinations of location. Using open-source libraries of optimisation routines, the authors established that 55% of patients could be reached by a retrieval team within 90 minutes and 98% of patients could be reached by a retrieval team within 3 hours (travelling by road). But they also found that if the current time-to-bedside standard of 3 hours was tightened, the service would struggle to meet it without expanding the use of aircraft and/or increasing the number of retrieval team locations. They identified that the optimal location of 11 teams could increase the percentage of patients likely to be reached within 90 minutes from 55% under the current configuration to 70%. Their analysis was deliberately simplistic, providing a preliminary exploration of the potential room for improvement in any reconfiguration of services, but illustrates the value that operational research could bring to an ongoing national review of paediatric intensive care and retrieval.

4.3 Organising Home Care in Sweden

Delivering care in people’s own homes presents tough organisational problems.

• Providers face demand for visits to patients that are potentially subject to constraints on when the visit should happen, and to the minimum set of qualifications required of the staff member for the activities planned.

• The total number of staff available is limited, as is the availability of individual staff members within the planning period.

• The number of individuals to visit a patient over the duration of their care should be as low as possible, both for continuity of care and so that patients are not exposed to too many different people.

• The care required can change at short notice.

• Regulations limit the total number of hours that individuals can work and further stipulate the number and durations of breaks they are permitted.

• Different members of staff have different preferred modes of transport.

• Allocation of workload across staff should be as fair as possible.

• In some settings, staff need to start and finish their working day at a base unit.

Planners are routinely tasked with constructing staff visit schedules and routes that satisfy these demands within the constraints and avoid excessive travelling time for staff. In many organisations in the UK and elsewhere, this job is left for senior nurses to do manually, with information technology used only to provide information and to check and record solutions. Finding a workable solution, let alone a good one, is very time-consuming and cognitively very challenging.

In 2001, local authority care providers in Danderyd, Sweden, worked with a software company to build an operational research-based tool to address the combination of staff-to-patient allocation, staff scheduling, and staff routing problems. The resulting system, Laps Care, has since been adopted by over 200 providers across 50 municipalities in Sweden.Reference Eveborn, Rönnqvist and Einarsdóttir⁴⁸

The operational research algorithm at the heart of Laps Care is an example of heuristic search. A key consideration for the developers was to limit the time taken by the software to return a solution to 5–10 minutes, to facilitate repeated use on a daily basis. The first step in the process is to assign every visit to a different staff member, with all of these staff members given a route that visits just one patient. This inefficient starting set of staff routes is then reduced by iteratively amalgamating routes, finding the best combinations at each iteration (in terms of route duration and compatibility with patient time windows and staff competencies), and then testing the new set of routes against the current best set. If no improvement is found, the algorithm either stops or (if sufficient computational time remains) takes some of the routes from the current best set, breaks them up, and restarts the amalgamation process. This approach finds good solutions in less time than taken by staff performing the job manually. The system increases the number of patient visits per member of staff per hour by 5–15% and reduces the time spent by staff on constructing schedules by around a third. Across the customer base of Laps Care, these and other indirect benefits have been estimated to have a monetary value of around €100 million.Reference Eveborn, Rönnqvist and Einarsdóttir⁴⁸

Some of the algorithms deployed in Laps Care are very sophisticated (our description is simplified). However, especially striking is the careful iterative design work, both in building the interface around the algorithms and in ensuring the appropriateness of the information feeding the algorithms. For example, the map tools that form the basis of the routing came from the automotive industry and the developers manually adjusted maps to account for routes open to workers on foot or bicycle that were not open to those driving.

4.4 Shaping Postnatal Care Improvement Using Multi-Criteria Decision Support

The postnatal care pathway for mothers and newborns in the UK is delivered in acute hospitals, the mother’s home, and in community clinics. Isolated quality improvements may be possible within each setting, but differences in the priority attached to different aspects of quality may mean that isolated initiatives are misaligned. Crucially, changes in one part of the pathway can require additional resource that may not be available without reducing the resource invested elsewhere in the pathway.

Operational researchers worked closely with nursing and midwifery researchers to develop a tool to support improvement initiatives in postnatal care.Reference Bowers, Cheyne and Mould⁴⁹ The resulting Postnatal Resource Allocation Model (PRAM) explores the impact of altering resource allocation across the postnatal care pathway. To develop PRAM, researchers used a mix of qualitative methods to understand the current operation of services and different stakeholder perspectives on quality in postnatal care. They collated a knowledge base from the literature, augmented by case studies and expert opinion. These fed into the development and use of a quantitative modelling framework that incorporated explicit assumptions about the links between changes in resource allocation and changes in quality.

Conceptions of quality within healthcare are essential to this form of analysis and are highly contested (see the Element on values and ethicsReference Cribb, Entwistle, Mitchell, Dixon-Woods, Brown and Marjanovic⁵⁰). In this instance, the team mapped aspects of postnatal care to the internationally recognised quality domains of safety, effectiveness, timeliness, equity, and the extent to which care is recipient-centred.⁵¹

The inputs for PRAM are the amount of resource devoted to particular activities (for instance, staffing of the postnatal ward, the typical length of stay on the postnatal ward, and the number of home visits made by a midwife following discharge). Outputs are numeric values for the anticipated quality of the service under that scenario of resource allocation. A prediction of quality for a scenario is calculated separately for each quality domain and in aggregate for each of four groups of new mothers who have ascending levels of medical, mental health, and social need.

The equations to predict quality assume that each measure of quality increases proportionally with resource input up to a maximum level, beyond which no further improvement is possible. A separate equation is used for each pairing of design parameter and domain of quality. In developing the model, each of these equations has to be calibrated. Additionally, each domain is given a weighting, which is used in calculating aggregate quality scores. To calibrate the model, the research team reviewed the literature on quality in postnatal care, filling gaps in the scientific evidence base using expert opinion and/or data and knowledge gathered outside research. The PRAM tool includes a facility for users to explore and question the sources used, which are categorised by relevance and rigour.

One service in the north of England used PRAM to inform changes to their postnatal service. The team validated PRAM by using it to assess the current allocation of resources, then checking through discussions with staff that the deficits in quality highlighted by the PRAM analysis were consistent with their perceptions of the service. The research team then used PRAM to explore with staff the potential impact of several scenarios for revised allocation of resources. One scenario entailed: earlier discharge from the postnatal ward; a net reduction in staffing, but an increase in feeding support on the ward; additional home visits for higher need groups; and an additional feeding and parenting support clinic for all groups. This scenario was anticipated to reduce total costs by 7% and to improve quality for all groups, with marked improvements among higher need groups.

An ongoing process evaluation found that the use of PRAM had increased participation of staff in the redesign process compared with previous improvement initiatives, had acted as a useful focus for sharing knowledge and service data between stakeholders, and led to increased understanding of current services and the perspectives of different stakeholders on options for change.Reference Bowers, Cheyne and Mould⁴⁹

4.5 Nurse Rostering in Acute Settings

We described in Section 4.3 the use of operational research methods to schedule staff activities in home-based care in Sweden. A related problem in acute settings involves determining which nurses will work which shifts. The roster for a ward needs to ensure adequate staffing (in terms of the numbers and competencies of staff members) and a degree of fairness across staff while meeting regulatory constraints on shift durations and working patterns. Rosters should account for requested leave, be robust to staff sickness, and perhaps be able to take into account individual staff preferences.

Many approaches have been developed to tackle this problem.Reference De Causmaecker and Vanden Berghe⁵² Formulations go well beyond the criteria given in the last paragraph, including work from Kuwait on incorporating any need for administering the last rites by ensuring that adherents of dominant religions are represented among the nurses on duty.Reference M’Hallah and Alkhabbaz⁵³ The problem is typically framed as a mathematical programming problem. The decision variables indicate whether each member of staff is scheduled for each shift. Hard constraints (those that have to be met by solutions) enforce stipulated staffing requirements, working patterns, and account for staff availability and other essential features. The objective function is typically a weighted function of the salary costs of a solution and the extent to which a solution breaches soft constraints such as staff preferences. The developers of new algorithms can use test cases to benchmark their approach against approaches proposed by other researchers. Adequate solutions to this technically complex rostering problem can be obtained in a matter of minutes on a standard PC. But poor take-up of this kind of operational research approach is the norm in healthcare, where staff still spend many hours each month constructing rosters manually – an arduous, cognitively difficult, and usually thankless task of combinatorial optimisation seen as a rite-of-passage by senior staff but rarely covered in the syllabus of nursing degrees.Reference Drake⁵⁴ In our own work, we have seen talented senior nurses struggle to construct rosters using software that offers no help, and working with information on staff availability recorded on spreadsheets and post-it notes, or even a napkin.

The poor penetration of operational research approaches for staff rostering in healthcare practice has prompted its own literature. A survey of the authors of academic nurse rostering optimisation models found that only 30% of models had been implemented by hospitals, with many of these limited to single sites. Some authors openly admitted that they had developed their approach with no explicit intent for their work to be implemented. Where academic models were implemented at some scale, there was little focus in the literature on sharing and learning the lessons from successful implementation.Reference Kellogg and Walczak⁵⁵ Surveying the approaches to rostering in US hospitals highlighted that the dominant software systems with a nurse-scheduling function do not take an optimisation approach and that standalone optimisation approaches to narrowly defined problems are not attractive commercially.Reference Kellogg and Walczak⁵⁵

A mixed-methods analysis of rostering practice and roster quality in Malaysia suggests other reasons for the poor uptake of operational research rostering methods.Reference Drake⁵⁴ A key point is that many of the criteria for a roster viewed in the literature as hard constraints are often violated in practice, and so are not truly hard constraints. Also, many of the considerations that influence the construction of rosters in practice are absent from model formulations. Rostering was found in this study be to a highly political exercise with planners aiming to balance the technical merits of the roster with tacit considerations, including power dynamics, granting favours, and avoiding conflict.

From this perspective, we argue that operational researchers need to avoid a narrow gaze that only sees the technical complexity of problems and not the social complexity. If clinicians and managers are struggling with a technically complex operational problem, the researcher should not assume that it is the technical complexity alone that causes the difficulty.

5.1 Strengths of Operational Research

The systematic and disciplined construction of explicit models (quantitative or qualitative) that relate aspects of system performance to those elements of a system that people feel they control offers several advantages.

First, operational research models can reveal and quantify relationships between different aspects of system performance, including trade-offs among different aspects of performance that are considered beneficial for organisations, staff, or patients. Second, such models can help place realistic expectations on the scale of impact on different aspects of performance that is achievable.

Operational research analyses can be used to screen ideas for which aspects of a service to alter, or to identify and target improvement initiatives on those changes that are likely to have the most beneficial impact.Reference Monks⁴¹ In the example discussed in Section 4.1 about improving acute stroke care, the team explored and discarded several interventions as being unlikely to lead to a marked improvement before settling on those that were seriously considered for implementation. Operational research also offers a range of approaches that can help organisations to place relative values on the different aspects of system performance that may be changed through improvement initiatives.

Finally, for circumstances where an explicit goal can be framed, operational research provides a set of sophisticated algorithms for identifying the changes to a system likely to give the biggest improvement. This means that operational research can add value to other improvement methods that focus only on generating ideas for change, or on helping organisations implement change, or on the empirical evaluation of changes as they are implemented.

5.2 Challenges of Operational Research

5.3 Finding and Working with Operational Researchers

As discussed in Section 5.2.2, the need for a bespoke (or at least made to measure) modelling process limits the extent to which operational research solutions can readily be translated from one organisation to another. It also raises the question of whether there are enough operational researchers working in healthcare to serve the needs of improvement in the NHS. While some parts of the UK are particularly well served by modelling teams, notably Wales and the south-west of England, others are less so.

Finding good operational researchers can be difficult. A directory of operational research academics and modelling practitioners interested and/or active in healthcare is available online.⁶³ Those looking to engage with an operational research team should reasonably expect that they:

• show a genuine interest in the service to be improved, wanting to meet on site and shadow or observe processes in action

• ask questions that probe and challenge the objectives of the improvement initiative, potentially to a slightly annoying extent

• present a number of ideas on potential approaches and how this choice might be influenced by the nature of the decision processes within the organisation, data availability, and resource considerations.

While an operational researcher should rightly be interested in the details of how services work, be wary of complexity fetishism. Some modellers like building complex models, and people working in healthcare often like to be told how complex their problems are. If indulged too much, this tendency can encourage very large, very complex models that give a good description of the status quo but are unwieldy when wanting to study the potential impact of change.