Abstract
Background
An increasingly ageing population presents many challenges for healthcare systems, including how to support older adults who are more likely to be both housebound and have complex medication needs. Community pharmacists may play a key role in medicines optimisation for this vulnerable population, however, the extent of literature exploring this topic is unclear.
Objective
To map existing literature on the role of community pharmacists in medicines optimisation for housebound older adults in the United Kingdom (UK).
Methods
A scoping review was conducted following PRISMA-ScR guidelines. Peer-reviewed primary research and grey literature published since 2000 were searched using relevant databases and websites. Data was charted using a standardised form based on TIDieR guidelines and EPOC taxonomies. A narrative synthesis was conducted to summarise and interpret the findings from included studies.
Results
Seven sources were included in the review – five peer-reviewed articles and two grey literature reports. Interventions consisted of domiciliary medication reviews conducted by pharmacists. Key medicines optimisation strategies addressed were medication review, deprescribing, addressing polypharmacy and facilitating communication between providers. Reported outcomes included identification of widespread issues with polypharmacy and medication-related problems, reduced hospital admissions, cost savings and improved patient care. Gaps identified were limited generalisability, lack of comparisons to standard care, and under-representation of minority groups.
Conclusions
The literature indicates promise for the role of community pharmacists in medicines optimisation for housebound older adults through domiciliary services. However, more research is needed to evaluate the effectiveness and feasibility of pharmacist-led interventions in this setting. Addressing identified gaps will help inform pharmacists’ roles in supporting medication needs of housebound patients.
Introduction
Rationale
The number of older adults in England and Wales is increasing rapidly, with the population aged 65 and over growing by over 1.8 million between 2011 and 2021 [1]. This ageing population presents significant healthcare challenges, as older individuals often suffer from multiple chronic conditions and take numerous medications (polypharmacy). Over 10% of those aged 65 and above take at least 8 different prescribed medications each week [2,3]. Polypharmacy increases the risks of drug interactions, impaired medication adherence, reduced quality of life [2,4–6], and adverse drug reactions, which are a leading cause of hospital admissions [4,5]. A person taking ten or more medications is 300% more likely to be admitted to hospital due to adverse drug reactions [7]. Furthermore, around 6.5% of hospital admissions are caused by adverse effects of medicines, rising to 20% in the over 65 age group, with two-thirds considered preventable [7].
An important, but ill-defined, target population for hospital admissions are housebound older adults. Housebound (US: ‘Homebound’) is generally defined as the condition in which a community-dwelling adult is confined to the home without support, implying a need for help with activities of daily living, mobility limitation and frailty [8,9]. Unlike care home residents, who – in the UK – benefit from regular multidisciplinary reviews and prioritisation for medication review [10] — housebound older adults face challenges with medication management due to isolation and reduced healthcare access [11,12]. The Community Pharmacy Contractual Framework focuses the currently shrinking workforce on in-pharmacy services, such as blood pressure monitoring and new medicine counselling, with no infrastructure for home visits, effectively excluding those unable to attend [13]. This creates a disparity in pharmaceutical care access for housebound older adults compared to care home residents, despite similar polypharmacy risks. Housebound older adults are missing services guaranteed to care home residents: weekly multidisciplinary team rounds, proactive personalised care planning within 7 days of health changes, systematic medication reviews , structured information sharing protocols between providers, and regular clinical oversight from a named healthcare lead.
Evidence syntheses have highlighted the need for further research into structured medication reviews for housebound older adults [14] and have called for evaluations of community pharmacist-led home visit models [15]. Some reviews also advocate for integrated approaches that offer proactive medicines optimisation comparable in quality and scope to those provided in care home services [14,15]. However, care home services are typically delivered through GP practices and practice-based pharmacists. In contrast, community pharmacy-led home visits is an approach that remains underexplored but may offer enhanced accessibility, continuity, and a broader reach beyond existing GP-led models. Recent studies by Latif et al. [16] and Kayyali et al. [17] found that pharmacist-led domiciliary medication reviews (dMURs) could identify and address medication-related problems, potentially preventing hospital admissions. However, these initiatives fall short of the comprehensive medicines optimisation approach proposed by the National Institute of Health and Care Excellence (NICE) in England [18].
Community pharmacists are well-positioned to support medicines optimisation for older adults [2,6]. The National Health Service (NHS) Long Term Plan commits to expanding access to medicines reviews and integrating pharmacists into local health teams [2,6]. However, a robust system for supporting the wider population of housebound older adults is lacking.
Despite clear policy recognition of this disparity, no comprehensive synthesis exists examining how community pharmacists contribute to medicines optimisation for housebound older adults. Previous reviews have not examined the full spectrum of medicines optimisation activities beyond basic medication reviews. This represents a knowledge gap given the UK’s unique healthcare structure and recent policy developments around structured medication reviews. This review provides the first systematic mapping of community pharmacist involvement in medicines optimisation specifically for housebound older adults within the UK healthcare context, examining both published research and grey literature to identify priority areas for future service development and research.
Aims and objectives
The primary research question is: What roles do community pharmacists currently play in medicines optimisation for housebound older adults in the UK, and what gaps exist in current service provision and research evidence?
This scoping review aimed to address the knowledge gap surrounding the role of community pharmacists in medicines optimisation for housebound older adults in the UK. By systematically mapping the existing literature, it will:
Map the existing evidence on the roles currently undertaken by community pharmacists in supporting medicines optimisation for housebound older adults.
Identify examples of pharmacist-led services that extend beyond medication reviews to more holistic medicines optimisation practices.
Examine evidence of collaboration or integration between community pharmacy and health and social care services in the delivery of medicines-related care.
Determine gaps in the literature and outline priorities for future research and service development.
Methods
Protocol and registration
The protocol (S1 Protocol) was drafted by two reviewers using the PRISMA Extension for Scoping Reviews and subsequently registered with the Open Science Framework. It was then published on ORDA [19]. This scoping review is reported in accordance with the “Preferred Reporting Items for Systematic reviews and Meta-Analyses extension for Scoping Reviews (PRISMA-ScR) Checklist” [20] (S2 Checklist).
Eligibility criteria
The eligibility criteria were formed with a specific view to determining the scope of literature regarding pharmaceutical services for housebound people, and therefore any reports concerning other home-based interventions for participants who could freely leave their homes were not included. Reports investigating any type of pharmacist intervention, including medication reviews, were included if they fit all other criteria. Peer reviewed primary research was accepted if it was published after 2000; was undertaken in the United Kingdom; and published in English. Evidence suggests that the exclusion of non-English studies rarely affects effect estimates or review conclusions [21]. Any reports including patients in care homes, hospitals, or non-domiciliary settings were excluded. Care home residents were excluded from this review as, in the UK, they receive structured pharmaceutical care through the Enhanced Health in Care Homes framework, which promotes weekly pharmacy-led medication reviews as best practice and established medicines optimisation protocols, whereas housebound community-dwelling older adults lack access to these systematic pharmacy services despite having similar polypharmacy risks and medication management needs [10].
A full copy of the inclusion and exclusion criteria for this review is provided in the appendices (S3 Appendix).
Information sources and search strategy
The search strategy is listed in its entirety in the appendices (S4 Appendix). Searches were last completed 22nd September 2024 on MEDLINE and EMBASE. Best evidence suggests that MEDLINE and EMBASE would capture the most relevant studies with little impact on results from missing studies [22–24]. Information from the articles found from the search were transferred onto Rayyan for review.
Selection of sources of evidence
Rayyan was used to aid the selection of sources of evidence, and a PRISMA flow diagram developed to demonstrate the process. The titles and abstracts from articles identified were screened independently by five reviewers to increase consistency, with any conflicts resolved through discussion. Meta-epidemiological research shows that single screening is suboptimal [25], especially with inexperienced reviewers [26]. Full texts were located for the remaining reports, and these underwent a secondary screening and data charting process.
The list of identified websites was searched for grey literature (S5 Appendix).
Search terms included the site name, ‘housebound’, ‘pharmacy/ist/eutical’, ‘domiciliary’, and ‘medication review’.
Data charting process
Data was charted on a standardised form developed by two reviewers using a small sample of eligible papers. The final form had 45 carefully chosen variables to extract the most amount of information from the texts. Four reviewers independently charted the data, with any conflicts resolved through discussion. Where needed, authors were contacted for information not available in the publication. We did not assess study quality or risk of bias, consistent with current methodological guidance that scoping reviews do not require critical appraisal [27–29].
Data items
A comprehensive list of the data charted for is included in the appendices (S6 Appendix). Within these variables, reviewers reported on characteristics of the literature, participant characteristics, details of the intervention elements, barriers and facilitators to engagement, and further utilisation or research recommendations. The sources were also compared with a list of interventions, services or initiatives related to medicines optimisation, included in the protocol.
Synthesis of results
A narrative synthesis was undertaken, to provide a structured summary of both the included papers and grey literature. We extracted descriptive data using a standardised data charting form based on TIDieR guidelines and EPOC taxonomies. Four reviewers (JB, YB, RI, AF) independently charted the data, capturing key intervention characteristics, objectives, implementation features, and reported outcomes. The charted data were then analysed using an iterative narrative synthesis approach. This process involved identifying patterns and relationships across studies, grouping similar intervention components and contextual factors, and organising findings into coherent thematic categories aligned with the frameworks used. Discrepancies in data interpretation were resolved through discussion among reviewers. Senior members of the research team (RC, DH) provided oversight and methodological guidance during synthesis, ensuring consistency and rigour in the identification of cross-cutting themes and gaps in the literature. This approach allowed for identification of patterns and relationships across studies, while accommodating variations in study design and outcomes. The synthesis aimed to highlight common themes, contextual factors, and areas of divergence relevant to the review.
Results
Selection of sources of evidence
The search initially identified 195 articles. Duplicates were then identified and removed, leaving 188 potentially eligible records. Screening at the title and abstract stage excluded 178 records as irrelevant. The full texts for all 10 articles were retrieved.
Sources were excluded at the full-text level due to ineligible population (n = 5) [30–34]. These had undertaken research into delivery of a similar service for people who were not housebound, or who had been admitted into care homes. This secondary screening left five eligible reports for the review. This process was reported in a PRISMA diagram (Fig 1).
Fig 1. PRISMA 2020 flowchart diagram.
The search process for grey literature found 3 articles, of which two were eligible. All seven sources were data charted to develop a detailed understanding.
Study characteristics
Data sources consisted of peer reviewed articles (n = 3) [16,17,35] and conference abstracts (n = 2) [36,37] between 2017 and 2022 (Table 1), including cross sectional studies (n = 3) [16,17,37], and case series (n = 2) [35,36]. Amongst the two grey literature sources there was one report [38] and one online publication regarding guidance recommendations [39], both published by the Royal Pharmaceutical Society.
Table 1. Study characteristics.
| Author | Document type (grey literature; peer reviewed article; conference abstract) | Study design | Patient group | Numbers and types of medicines | Brief name |
|---|---|---|---|---|---|
| Kayyali R, Funnell G, Harrap N, Patel A. 2018 | Peer reviewed article | Cross-sectional study | 133 patients – 49–98, housebound, mean age 81.7 years | Average 9.4 medications | dMUR |
| Garfield SF, Wheeler C, Etkind M, Ogunleye D, Williams M, Boucher C, et al. 2022 | Conference abstract | Cross-sectional study | 50 patients – mean age 68 years (26–93 years) | 1 long term medication | Medication safety interview |
| Hurley D. 2018 | Conference abstract | Case series | 69 patients – mean age 81.2 + /- 8.1 years 90% of patients housebound – patients had been referred to falls service | Not stated | Full level 3 medication review |
| Latif A, Mandane B, Anderson E, Barraclough C, Travis S. 2018 | Peer reveiwed article | Cross-sectional study | 1092 – patients were housebound, 76.9% were over 75 years old | Not stated | dMUR |
| Souter C, Kinnear A, Kinnear M, Mead G. 2017 | Peer reviewed article | Case series | 35 patients completed the study- 18 inpatients, and 17 outpatients mean age 74.2 | Not explicitly stated | Pharmacist complex intervention |
| Royal Pharmaceutical society 2014 | Grey literature | N/a | 322 housebound patients | Not stated | dMUR |
| Royal Pharmaceutical society | Grey literature | N/a | 169 frail elderly housebound patients across 7 GP practices | Not stated | Multidisciplinary pharmacy review |
Patient population sizes ranged from 35 [35] to 1092 [16]. The terminology and wording of the interventions delivered to patients varied: three studies referred to domiciliary medicines use reviews [16,17,38] but elsewhere, pharmacist complex intervention [35], full level 3 medication review [36] and multidisciplinary review [39] were used to describe interventions with. One study not specifically naming the intervention [37]. Five sources explicitly described patient demographics; most had a female majority (n = 4) [16,17,35,37]. Heterogeneity in patient populations limited comparability across studies. Latif included a broad housebound population [16]; Kayyali focused on older adults with complex social needs [17]; Hurley on frail, fall-prone patients [36]; Souter on post-stroke patients [35]; and Garfield included younger adults (mean age 68) with varied conditions [37]. Differences in clinical needs were marked: Souter involved patients requiring stroke rehabilitation [35]; Hurley targeted those at risk of falls [36]; Latif encompassed a wide range of conditions, diluting condition-specific insights [16]. Age and frailty also varied—Garfield had a younger cohort [37] compared to Kayyali and Hurley, both with mean ages over 81—limiting generalisability to older populations [17,36]. Levels of complexity and dependency were uneven: Kayyali described substantial social care and functional needs [17], while Garfield lacked detail on patient dependency [37]. Definitions of “housebound” varied. Latif defined patients as “unable to attend the pharmacy” and not in residential or nursing care [16]. Kayyali included those “who would otherwise not be able to access the pharmacy,” often referred by GPs or district nurses [17]. Souter did not use the term but included patients discharged home post-stroke, implying housebound status through functional limitation and exclusion of those in long-term care [35]. Garfield referred to people “unable to attend pharmacies,” but did not specify criteria [37]. Hurley did not define housebound [36].
Intervention objectives
Study interventions involved the use of medication reviews (n = 6) [16,17,35,36,38,39]; patient education and counselling (n = 4) [16,17,37,38]; deprescribing (n = 4) [16,36,38,39]; adherence support (n = 3) [16,17,35]; addressing polypharmacy and inappropriate prescribing (n = 6) [16,17,35,36,38,39]; facilitating communication between healthcare providers (n = 5) [16,17,35,37–39]; and use of technology or information sharing to support medicines optimisation (n = 2) [16,39] (Table 2).
Table 2. Intervention objectives.
| Author | Medication review | Patient education and counselling | Deprescribing | Adherence support | Addressing polypharmacy and inappropriate prescribing | Facilitating communication between healthcare providers | Use of technology or information sharing to support medicines optimisation | Rationale, evidence-base theory or goal of intervention elements | EPOC taxonomy Intervention category: |
|---|---|---|---|---|---|---|---|---|---|
| Kayyali R, Funnell G, Harrap N, Patel A. 2018 | Yes | Yes | No | Yes | Yes | Yes | No | Medication support and social care needs of housebound older patients | Site of service delivery |
| Garfield SF, Wheeler C, Etkind M, Ogunleye D, Williams M, Boucher C, et al. 2022 | No | Yes | No | No | No | Yes | No | Safe medicine practices for housebound patients | Use of information and communication technology and educational materials |
| Hurley D. 2018 | Yes | No | Yes | No | Yes | No | No | Reduce hospital admissions for patients at risk of falls | Site of service delivery |
| Latif A, Mandane B, Anderson E, Barraclough C, Travis S. 2018 | Yes | Yes | Yes | Yes | Yes | Yes | Yes | To evaluate feasibility of providing dMURs for housebound patients | Site of service delivery |
| Souter C, Kinnear A, Kinnear M, Mead G. 2017 | Yes | No | No | Yes | Yes | Yes | No | Testing practicality, acceptability, and feasibility to inform the design of a definitive RCT | Site of service delivery |
| Royal Pharmaceutical society 2014 | Yes | Yes | Yes | No | Yes | No | No | Not stated | Site of service delivery |
Five of the data sources described a specific intervention and specified the goals and rationale [16,17,35,37,38] (Table 2). The goal of intervention elements included: evaluating medication needs (n = 4) [16,17,37,38]; feasibility tests (n = 2) [16,35]; an exploration of medicines practices and safety (n = 1) [37]; and an assessment of whether the intervention would reduce hospital admissions (n = 1) [38]. Rationale for all five interventions centred around barriers faced by the ageing population in accessing healthcare services and effectively using medicines, especially as they have a higher risk of likelihood of multiple comorbidities and therefore polypharmacy. EPOC taxonomy intervention categories were site of service delivery (n = 6) [16,17,35,36,38,39], and use of information and communication technology and Educational materials (n = 1) [37].
Intervention characteristics
Where stated, physical materials used included the PharmOutcomes system (n = 2) [16,35], and the dMUR form (n = 1) [17] (Table 3). One source specified an intervention cost of a £56 reimbursement alongside the standard MUR payment of £28 per dMUR carried out by the pharmacist [16].
Table 3. Intervention characteristics.
| Author | Physical or informational materials used (information materials; training materials) | Intervention costs/resource requirements | Intervention duration | Intervention provider background/expertise (pharmacist; nurse; physician; multidisciplinary team) | Number of intervention providers | Any specific training given to providers | Organisation: Type, size, number of study sites, ratings | Location: Area demographics | Necessary infrastructure or relevant features of locations |
|---|---|---|---|---|---|---|---|---|---|
| Kayyali R, Funnell G, Harrap N, Patel A. 2018 | dMUR form | Cost not stated | Each visit was completed within 30–45 min | Community pharmacist following MUR training | 12 pharmacists | dMUR information sessions | 133 patients, 12 community pharmacists | London Borough of Richmond, UK | Community pharmacist to conduct review in home of patient |
| Garfield SF, Wheeler C, Etkind M, Ogunleye D, Williams M, Boucher C, et al. 2022 | Not explicitly stated | Cost not stated | Not stated | Pharmacist | Not stated | None sated | 50 people interviewed remotely | Uk wide | Not stated |
| Hurley D. 2018 | GP records system | Cost of intervention not stated | Not stated | Pharmacist | Not stated | Not stated | Not stated | East Staffordshire, UK | Device to review patient records |
| Latif A, Mandane B, Anderson E, Barraclough C, Travis S. 2018 | PharmOutcomes system | £56 reimbursement fee for each dMUR on top of the standard £28 MUR fee | Not stated | Community pharmacists | 91 pharmacies | Interested pharmacies were provided a service specification& a checklist | 91 pharmacies undertaking 1092 reviews | Nottinghamshire and Derbyshire | Community Pharmacist |
| Souter C, Kinnear A, Kinnear M, Mead G. 2017 | Machine for BP measurements, GP patient record systems, | Not stated | Not stated | Community pharmacists | Not stated | Not stated | Not stated | Not stated | Community pharmacist to perform review |
| Royal Pharmaceutical society 2014 | Not stated | Not stated | Not stated | Pharmacist in primary care | Not stated | Not stated | Not stated | Croydon | Not stated |
| Royal Pharmaceutical society | Not stated | Not stated | Not stated | Not stated | Not stated | Not stated | 7 GP practices | Scotland | Not stated |
Five studies used a pharmacist to conduct the intervention [16,17,35,36,38]; one used a researcher [37] and one did not state the professional [39] (Table 3). The sources were not clear on the number of intervention providers, one stated the use of one pharmacist [35], another stated the use of twelve pharmacists [17], one stated the involvement of 91 pharmacies [16] and four did not specify [16,36–39]. One source gave official training to the pharmacists [17], whereas one provided guidance to the pharmacists completing the reviews [16].
Intervention locations varied: one referred to the United Kingdom more generally [37] but most were related to specific areas including Nottinghamshire and Derbyshire (n = 1) [16], London (n = 1) [17], East Staffordshire (n = 1) [36] Croydon (n = 1) [38], and Scotland (n = 1) [39]. Two sources did not specify locations [35,36]. One source stated the duration of each review, between 30–45 minutes [17].
Intervention delivery
Two sources referred to initial contact with the patient and/or a carer to organise a suitable time for a meeting, done either by a pharmacist [17], or unspecified [36] (Table 4). Most interventions were delivered face-to-face (n = 5) [16,17,35,36,38]; one was not stated [39], and one was delivered over video or telephone calls [37]. All were delivered on an individual basis except one, which did not specify [37]. Similarly, all were delivered in patients homes except two, which did not specify [37,38]. Follow-up appointments were conducted in two sources [35,36]. Visit frequency varied substantially. Latif involved a single opportunistic dMUR per patient, with low average numbers per pharmacy, reflecting limited capacity and non-mandated follow-up [16]. Kayyali delivered a mean of 2.4 visits, shaped by proactive identification, GP collaboration, and broader optimisation goals [17]. Souter scheduled three visits per patient as part of a protocolised trial [35]. Frequency in Garfield and Hurley was unclear or fixed at one; both lacked detail on service design or rationale, limiting interpretation [36,37].
Table 4. Intervention delivery.
| Author | Procedures, activities, processes used | Modes of delivery (e.g. Face-to-face; telephone; Internet) | Whether delivered individually or in a group | Number of locations | Number of times delivered | Schedule of delivery | If intervention was personalised or adapted, how and why (e.g. based on patient characteristics) | - If/how adherence or fidelity was assessed (e.g. independent assessors; validated tools) |
|---|---|---|---|---|---|---|---|---|
| Kayyali R, Funnell G, Harrap N, Patel A. 2018 | Telephone call to prospective patients to organise visit with family/carer. Review completed and data analysed | Initial phone call to organise a suitable time for subsequent home visit | Individually | Patients home | One dMUR per patient | Visits took place between May 2015 and January 2016 | The pharmacists used the same form for each patient. The exact intervention would depend on the medication prescribed and the individual’s circumstances | Pharmacist service lead assessed forms for completeness and guidance when necessary |
| Garfield SF, Wheeler C, Etkind M, Ogunleye D, Williams M, Boucher C, et al. 2022 | Participants recruited through personal contact or social media, interviews conducted and data analysis carried out. | Telephone or video conference | Individually | Non stated – interviews were remote | Once per patient | Not stated | initial delivery the same, however intervention dependent on patient medication. only medications with no indication or limited efficacy, potentially contributing to falls, were deprescribed. | Not stated |
| Hurley D. 2018 | Medical records reviewed of patients referred to falls service, meeting arranged and carried out, changed were made at GP surgery and followed up after 1–2 months | Medical records reviewed, face to face meeting with patient | Individually | Not stated | One review per patient – follow up after 1–2 months | None stated | None Stated | Not stated |
| Latif A, Mandane B, Anderson E, Barraclough C, Travis S. 2018 | Service advertised to pharmacies and those expressing interest given information. Review conducted and risk of hospital admission scored. Results recorded on PharmOutcomes. | Face to face visit | Individually | Patients homes | Once per patient | April 16 to march 17 | The delivery was the same for each patient, but the exact intervention and outcome would vary dependent on the individual’s circumstances. | Not stated |
| Souter C, Kinnear A, Kinnear M, Mead G. 2017 | Patients recruited following stroke unit discharge and permission obtained. Interviews carried out at 1, 3 and 6 months – concerns highlighted with GP | Face to face visit | Individually | Patients homes | 3 | Visit at 1, 3 and 6 months | Initial delivery the same, but specific actions taken dependent on patient’s circumstances | Not stated |
| Royal Pharmaceutical society 2014 | Not stated | Face to face | Individually | Patients homes | Not stated | Not stated | None Stated | Not stated |
| Royal Pharmaceutical society | Not stated | Face to face | Individually | Patients homes | Not stated | Not stated | None Stated | Not stated |
Four intervention deliveries were personalised according to the patients’ situations (n = 4) [16,17,35,36]. Assessment of fidelity was only mentioned once in which dMUR forms were assessed for completeness by pharmacist service lead [17].
Intervention duration lasted either 6 months (n = 2) [35,38], 9 months (n = 1) [17], or 12 months (n = 1) [16].
TIDieR item 10 has not been reported as no modifications were reported by any of the included papers.
Findings
There was variation in the extent of pharmacist activity across the interventions and sources: four referred to only one instance of a pharmacist activity per patient [16,17,36,37], with another referring to one additional follow-up per patient [36]. In one study, three pharmacist visits per patient were reported [35] (Table 5). Outcome Characteristics included medication access issues (n = 3) [17,35,37], risk of hospital admissions (n = 3) [36,38,39], polypharmacy (n = 2) [17,38], patient- reported concerns (n = 3) [35,37,40], adherence (n = 4) [17,35,37,40] side effects (n = 4) [17,35,36,40], and prescribing appropriateness (n = 6) [16,17,35–38]. One paper described experiences of twelve pharmacists following testimonies from those involved [16], and all sources reported that the dMUR highlighted issues with medications.
Table 5. Intervention findings.
| Author | Number of instances of pharmacist activity | Outcome characteristics | Experiences of pharmacists, patients and other stakeholders | Outcomes in relation to medicines optimisation | Prescribing appropriateness (e.g., number and type of medication changes, use of tools like MAI, Beers criteria) | Adverse drug reactions | Adherence |
|---|---|---|---|---|---|---|---|
| Kayyali R, Funnell G, Harrap N, Patel A. 2018 | One visit per patient | Issues with medication access, clinical issues, cognitive issues, social care issues, medication for disposal, polypharmacy, adherence | Not stated | Not explicitly stated, 52 patients with medication for disposal, 13 patients who no longer need medication, 14 taking medication the wrong way | 13 cases of patients taking meds they no longer needed | 37 cases of adverse effects due to drugs | 14 cases of patients taking medication the wrong way |
| Garfield SF, Wheeler C, Etkind M, Ogunleye D, Williams M, Boucher C, et al. 2022 | One per patient | Medicine safety issues of omitting doses, and use of less effective formulations, issues obtaining medications | Not stated | Not stated | Some reports of less effective formulations being used | None stated | Not stated |
| Hurley D. 2018 | One visit and one follow up per patient | Medications with no indication or limited efficacy potentially contributing to falls | Not stated | 124 medications deprescribed in 64 patients – 38 of these considered as contributing to poor balance in 38 patients | 124 medications deprescribed in 64 patients | 38 drugs considered to contribute to falls risk | Not stated |
| Latif A, Mandane B, Anderson E, Barraclough C, Travis S. 2018 | Once per patient | Patient reported concerns, reported side effects, reported missed doses, identification of discontinued medications, security of drugs, stockpiling medications, expired medications | 12 pharmacist testimonies were taken and all stated that the dmur highlighted issues with patients’ medications | Two thirds of patients reported concerns, missed doses or side effects over 1/4 had expired or stockpiled medications | 58 change of dose forms recommended | 77 cases likely to prevent emergency hospital admission – 178 cases of reported side effect | Not stated |
| Souter C, Kinnear A, Kinnear M, Mead G. 2017 | 3 visits | Bp and cholesterol measurements, lifestyle records, social and practical support, mmse and current medications (effects and physical abilities of device use. | Not stated | 104 care issues identified, (mean 5.8 per patient) including additional, unnecessary and wrong medicines and adverse reactions, interactions or inappropriate compliance. | Additional, unnecessary, wrong and doses too low | 11 cases | 18 cases of inappropriate compliance |
| Royal Pharmaceutical society 2014 | Not stated | Polypharmacy and risk of hospital admissions | Not stated | 83 emergency hospital admissions prevented | Not stated | Not stated | Not stated |
| Royal Pharmaceutical society | Not stated | Risk of hospital admissions | Not stated | 162 medicines stopped of which 40% were high risk, 113 dose/formulation changes and 20 medicines started | 162 medications stopped and 113 doses changes | 40% of stopped medications were high risk | Not stated |
Outcomes
All sources mention barriers and facilitators to medicines optimisation (Table 6). These include housebound patients’ inability to leave home to receive healthcare (n = 2) [16,17], lack of access to healthcare and reduced mobility increasing medication management challenges of housebound people (n = 1) [37], frail elderly people prescribed medications contributing to falls (n = 1) [36], stroke patients’ inability to visit the pharmacy causing lack of pharmacist contact (n = 1) [35] and vulnerability and polypharmacy of housebound patients (n = 2) [38,39]. Patient satisfaction was reported positively in two papers [17,35], with 100% of patients or carers finding the dMUR helpful in one study [17]. One study found a patient satisfaction rate of 77.8% in the intervention group comparing more favourably that the 76.5% in the usual care group [35]. Only one source allowed decision making to be shared between pharmacists and patients [37]. Shared-decision making was not explicitly described in any papers. Quality of life was discussed in one paper in which two houses were found to have damp, and over 10% of patients with unaddressed mobility problems. [17] The data sources mentioned some methods of healthcare utilisation such as: the role of pharmacists in medicines management (n = 2) [17,37]; prevention of hospital admission (n = 3); [16,38,40] and cost savings (n = 2) [36,38]. No study directly measured the impact of medicines optimisation on hospital admissions. Latif used a pharmacist-applied scoring system to self-assess admission risk and the impact of dMURs: Score 1 = no likelihood; Score 2 = possible; Score 3 = likely emergency hospital admission prevented [16].
Table 6. Outcomes.
| Author | Barriers and facilitators to medicines optimisation | Patient satisfaction | Shared decision-making | Quality of life | Health care utilization and costs (e.g., hospital admissions, medication costs) | Gaps in literature/ uncertainties identified |
|---|---|---|---|---|---|---|
| Kayyali R, Funnell G, Harrap N, Patel A. 2018 | Bringing community pharmacists to housebound patients | 133 (100%) patients or carers finding the dMUR helpful | Not stated | Two houses found to have damp and one with major tripping hazards. Over 10% of patients had unaddressed mobility problems two patients had issues preventing them from easily reaching the toilets/bathrooms, leading to poor hygiene. | Community pharmacists may assist in the care pathway to help involve aspects of care of older people with multi-morbidities. | Elements of the patients social networks and connections to assess the best interventions. Access to full medical records would provide a complete understanding of their medical situation. Recordings of the dMURs could allow service improvement. |
| Garfield SF, Wheeler C, Etkind M, Ogunleye D, Williams M, Boucher C, et al. 2022 | Housebound patients may face challenges to their medicines management due to reduced household mobility and potential lack of access to healthcare services. | Not stated | Not stated | Not stated | Pharmacists to support housebound patients by synchronization of medicines, delivering medications and education about the importance of communication | Findings are Uk only and may limit generalisability of findings to other countries. Little work on patient-family perspective of medication needs of housebound patients. Lack of equal research between genders |
| Hurley D. 2018 | Frail elderly patients are often prescribed multiple medications, frequently contributing to falls and hospital admissions. Falls services often overlook medicinal causes | Not stated | Not stated | Not stated | Discontinued medication saving £11,423 (if they were still taking for another 12 months) and interventions preventing 2.51 hospital admissions, saving £7,000 (based on predicted procedures upon admission) | Has never been possible to directly link interventions to prevented hospital admissions |
| Latif A, Mandane B, Anderson E, Barraclough C, Travis S. 2018 | dMURs is typically delivered from a community pharmacy, and patients who are homebound may not be receiving the service. | Not stated | Not stated | Not stated | Role of pharmacists in reducing hospital admissions | Further evaluation needed to assess cost effectiveness. Potential lack of consistency in scoring systems between individual pharmacists. Majority white British population, indicating a lack of patients from underserved communities. No comparison between usual MUR service and dMUR. |
| Souter C, Kinnear A, Kinnear M, Mead G. 2017 | A proportion of patients with stroke on discharge do not have contact with the community pharmacist because they are unable to visit the pharmacy in person.3 |
77.8% in intervention group 76.5 in usual care | Not stated | Not stated | Not stated | Further feasibility testing for the measurement of BP. Generalisability is difficult due to one researcher visiting all patients, despite this researcher being a clinical pharmacist. |
| Royal Pharmaceutical society 2014 | Housebound patients are often taking a lot of medications | Not stated | Not stated | Not stated | Cost avoidance of £234,000 from reduced hospital admissions | Not stated |
| Royal Pharmaceutical society | Increased vulnerability of housebound people | Not stated | Not stated | Not stated | Not stated | Not stated |
Five sources identified and highlighted gaps and uncertainties within their research as follows: no comparison between standard intervention and research intervention, and lack of patients from underserved communities [16]; investigation of social connections and access to full medical records [17]; difficult to directly link interventions and hospital admissions [36]; unequal gender participation [37]; and lack of generalisability [35].
Synthesis of results
Important findings are illustrated in a logic model to summarise the roles community pharmacists may play in medicines optimisation for elderly housebound people (Fig 2).
Fig 2. Pipeline logic model of main findings.
Discussion
Summary of evidence
This scoping review identified a small but growing body of literature on the role of community pharmacists in medicines optimisation for housebound older adults in the UK. The principal findings suggest that pharmacist-led domiciliary medication reviews (dMURs) can effectively identify and address medication-related problems, potentially reducing inappropriate polypharmacy, non-adherence, adverse drug reactions, and hospital admissions in this vulnerable population. None of the included studies assessed the impact of medicines optimisation on hospital admissions using direct measures.
It is important to note that none of the included studies presented findings that contradicted the potential benefits of pharmacist-led interventions for housebound older adults. All included sources either reported positive outcomes or were neutral in their conclusions. The absence of contradictory evidence does not equate to conclusive proof of effectiveness; however, it does support the rationale for further investigation through more rigorous and controlled studies.
Strengths and limitations
This scoping review involved an extensive search of both academic and grey literature to understand the breadth of evidence in the relevant field. The comprehensive eligibility criteria provided a thorough overview of the topic, permitting consideration of various intervention types, outcomes, and study designs, and providing information on the range of roles available for pharmacists within home-based medicines optimisation. The screening process involved a team of five reviewers to increase austerity.
Established frameworks such as TIDieR and EPOC taxonomy were utilised to ensure data was systematically extracted and narrated, including placing an emphasis on identifying gaps in research, and generating recommendations for future research and practice.
However, this scoping review was intended as a descriptive narrative of available literature, and thus a formal quality appraisal was not conducted to assess the strength of evidence within individual studies. Instead, where there was confusion about the validity of a study, another researcher provided an opinion. Similarly, the grey literature screened for eligibility may not provide commentary on all unpublished case studies, and thus this review may be at risk of publication bias.
The data sources included in this review were restricted to publishing dates after 2000, published in English and relevant to the United Kingdom. This made some relevant literature ineligible for inclusion in the review, and a wider search may be warranted for further review. The methodology of a scoping review does not allow for synthesis of effectiveness data or analysis of methodological limitations of data provided, and therefore a systematic review may be in order.
Relation to other studies
The findings of this scoping review are broadly consistent with previous studies about pharmacist-led interventions in similar populations. Abbott et al. [41] found no effect on hospital admissions among individuals at risk of medication-related problems receiving pharmacist home visits, while Spinewine et al. [42], reported improvements in pharmacotherapy for older patients. Abbott et al. proposed that a lack of interprofessional communication may have explained the absence of any effect on admissions observed in their systematic review [41]. Specifically, they noted that in the one study showing reduced admissions, the pharmacist routinely communicated findings to both the general practitioner and local pharmacist, a practice rarely reported in other studies [43]. They also suggest that pharmacists conducting home visits alongside normal duties, rather than as dedicated roles, and longer follow-up periods may dilute observable effects [41].
Our review similarly identified mixed evidence on the impact of pharmacist-led medicines optimisation on healthcare utilisation and clinical outcomes for housebound older adults.
The themes identified in our review, such as collaborative working, patient involvement in goal setting and action planning, and the provision of additional support and follow-up, align with the findings of Craske et al. [44], who explored the components of pharmacist-led medication reviews. However, our review extends
these insights by focusing specifically on the unique needs and challenges of housebound older adults and the role of community pharmacists in this context.
Consistent with the conclusions of Saeed et al. [45], who investigated medicines optimization interventions for frail older inpatients, our review found that while pharmacist-led interventions may improve prescribing appropriateness, there is a lack of high-quality evidence on their impact on clinical outcomes in housebound populations.
Our findings also resonate with studies highlighting the importance of pharmacists’ willingness and competence in driving medication optimisation in care home settings [46]. However, the specific focus of our review on housebound older adults in the community setting distinguishes it from research in institutional contexts, where medication management processes and challenges may differ.
Policy implications
Our findings reinforce NHS England’s guidance that housebound individuals with problematic polypharmacy, frailty, recent hospitalisations or fall risk are key candidates for structured medication reviews and demonstrate the feasibility of pharmacist-led interventions in identifying and addressing such risks in this population [47]. However, the variability in service provision and underrepresentation of underserved groups point to the need for strengthened policy mechanisms to ensure equitable, systematic implementation of structured medication reviews across primary care networks, supported by targeted workforce planning, commissioning frameworks and integration into routine care through formal referral pathways and shared clinical records.
Future research
While randomised controlled trials are needed to robustly evaluate the effectiveness and cost-effectiveness of pharmacist-led medicines optimisation interventions for housebound older adults, important foundational work is first required. Building on the findings of this scoping review, future research should focus on the co-design of potential interventions in collaboration with key stakeholders, including patients, carers, pharmacists, and other healthcare professionals, to ensure their feasibility, acceptability, and relevance to the specific needs of this population. Frameworks for intervention development [48,49] should be used to guide this process, to integrate diverse perspectives, prioritising intervention components and outcome measures. This developmental work would lay the groundwork for future pilot and definitive evaluations.
Conclusions
There is a clear need to establish a precedent for caring for this vulnerable population. This scoping review lays the groundwork to build upon existing research in this field, yet significant gaps remain. Understanding the evidence surrounding community pharmacists’ contribution is crucial for developing services that enhance care, reduce adverse events, and promote health equity.
The NHS’ medicines optimisation opportunities [4] indicated a place for pharmacists in providing for this population, and this review highlights the capacity of their role. Given the limited depth of available data, a more systematic approach may be needed to assess the feasibility and impact of specific interventions. With further research, there is a vast opportunity for filling this gap in care.
Supporting information
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Data Availability
All relevant data are within the paper and its Supporting Information files.
Funding Statement
The author(s) received no specific funding for this work.
References
- 1.Office for National Satistics. Profile of the older population living in England and Wales in 2021 and changes since 2011 [Internet]. [cited 2025 Mar 1]. https://www.ons.gov.uk/peoplepopulationandcommunity/birthsdeathsandmarriages/ageing/articles/profileoftheolderpopulationlivinginenglandandwalesin2021andchangessince2011/2023-04-03
- 2.Age UK. Age UK calls for a more considered approach to prescribing medicines for our older population [Internet]. [cited 2025 Mar 9]. https://www.ageuk.org.uk/latest-press/articles/2019/august/age-uk-calls-for-a-more-considered-approach-to-prescribing-medicines-for-older-people/
- 3.Age UK. Age UK | The UK’s leading charity helping every older person who needs us [Internet]. [cited 2025 Mar 9]. https://www.ageuk.org.uk/
- 4.NHS England. NHS England » National medicines optimisation opportunities 2024/25 [Internet]. [cited 2025 Mar 9]. https://www.england.nhs.uk/long-read/national-medicines-optimisation-opportunities-2023-24/
- 5.Duerden M, Avery T, Payne R. Polypharmacy and medicines optimisation: Making it safe and sound. 2013. [Google Scholar]
- 6.GOV.UK. National overprescribing review report [Internet]. [cited 2025 Mar 9]. https://www.gov.uk/government/publications/national-overprescribing-review-report
- 7.Department of Health and Social Care. Good for you, good for us, good for everybody: a plan to reduce overprescribing to make patient care better and safer, support the NHS, and reduce carbon emissions. [Google Scholar]
- 8.Ankuda CK, Husain M, Bollens-Lund E, Leff B, Ritchie CS, Liu SH, et al. The dynamics of being homebound over time: A prospective study of Medicare beneficiaries, 2012-2018. J Am Geriatr Soc. 2021;69(6):1609–16. doi: 10.1111/jgs.17086 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 9.Schirghuber J, Schrems B. Homebound: A concept analysis. Nurs Forum. 2021;56(3):742–51. doi: 10.1111/nuf.12586 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 10.NHS England. NHS England » Enhanced health in care homes [Internet]. [cited 2025 Jul 2]. https://www.england.nhs.uk/community-health-services/ehch/
- 11.Molokhia M, Majeed A. Current and future perspectives on the management of polypharmacy. BMC Fam Pract. 2017;18(1):70. doi: 10.1186/s12875-017-0642-0 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 12.Cook EA, Duenas M, Harris P. Polypharmacy in the Homebound Population. Clin Geriatr Med. 2022;38(4):685–92. doi: 10.1016/j.cger.2022.05.008 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 13.Community Pharmacy Contractual Framework: 2024 to 2025 and 2025 to 2026 [Internet]. GOV.UK. [cited 2025 Jul 2]. https://www.gov.uk/government/publications/community-pharmacy-contractual-framework-2024-to-2025-and-2025-to-2026/community-pharmacy-contractual-framework-2024-to-2025-and-2025-to-2026 [Google Scholar]
- 14.Kolle AT, Lewis KB, Lalonde M, Backman C. Reversing frailty in older adults: a scoping review. BMC Geriatr. 2023;23(1):751. doi: 10.1186/s12877-023-04309-y [DOI] [PMC free article] [PubMed] [Google Scholar]
- 15.Sterling-Fox C. Access to five nonprimary health care services by homebound older adults: an integrative review. Home Health Care Management & Practice. 2019;31(1):55–69. [Google Scholar]
- 16.Latif A, Mandane B, Anderson E, Barraclough C, Travis S. Optimizing medicine use for people who are homebound: an evaluation of a pilot domiciliary Medicine Use Review (dMUR) service in England. Integr Pharm Res Pract. 2018;7:33–40. doi: 10.2147/IPRP.S160149 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 17.Kayyali R, Funnell G, Harrap N, Patel A. Can community pharmacy successfully bridge the gap in care for housebound patients? Res Social Adm Pharm. 2019;15(4):425–39. doi: 10.1016/j.sapharm.2018.06.011 [DOI] [PubMed] [Google Scholar]
- 18.National Institute for Heath and Care Excellence. Overview | Medicines optimisation: the safe and effective use of medicines to enable the best possible outcomes | Guidance | NICE [Internet]. [cited 2025 Mar 9]. https://www.nice.org.uk/guidance/ng5 [PubMed]
- 19.Hind D, Cooper R. Protocol: The Role of Community Pharmacists in Medicines Optimisation for Housebound People [Internet]. [cited 2025 Mar 9]. https://orda.shef.ac.uk/articles/workflow/Protocol_The_Role_of_Community_Pharmacists_in_Medicines_Optimisation_for_Housebound_People/27083167?file=49350031 [DOI] [PubMed]
- 20.Tricco AC, Lillie E, Zarin W, O’Brien KK, Colquhoun H, Levac D, et al. PRISMA Extension for Scoping Reviews (PRISMA-ScR): Checklist and Explanation. Ann Intern Med. 2018;169(7):467–73. [DOI] [PubMed] [Google Scholar]
- 21.Dobrescu AI, Nussbaumer-Streit B, Klerings I, Wagner G, Persad E, Sommer I, et al. Restricting evidence syntheses of interventions to English-language publications is a viable methodological shortcut for most medical topics: a systematic review. J Clin Epidemiol. 2021;137:209–17. doi: 10.1016/j.jclinepi.2021.04.012 [DOI] [PubMed] [Google Scholar]
- 22.Ewald H, Klerings I, Wagner G, Heise TL, Stratil JM, Lhachimi SK. Searching two or more databases decreased the risk of missing relevant studies: a metaresearch study. J Clin Epidemiol. 2022;149:154–64. [DOI] [PubMed] [Google Scholar]
- 23.Frandsen TF, Eriksen MB, Hammer DMG, Christensen JB, Wallin JA. Using Embase as a supplement to PubMed in Cochrane reviews differed across fields. J Clin Epidemiol. 2021;133:24–31. doi: 10.1016/j.jclinepi.2020.12.022 [DOI] [PubMed] [Google Scholar]
- 24.Hartling L, Featherstone R, Nuspl M, Shave K, Dryden DM, Vandermeer B. The contribution of databases to the results of systematic reviews: a cross-sectional study. BMC Med Res Methodol. 2016;16(1):127. doi: 10.1186/s12874-016-0232-1 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 25.Edwards P, Clarke M, DiGuiseppi C, Pratap S, Roberts I, Wentz R. Identification of randomized controlled trials in systematic reviews: accuracy and reliability of screening records. Stat Med. 2002;21(11):1635–40. doi: 10.1002/sim.1190 [DOI] [PubMed] [Google Scholar]
- 26.Waffenschmidt S, Knelangen M, Sieben W, Bühn S, Pieper D. Single screening versus conventional double screening for study selection in systematic reviews: a methodological systematic review. BMC Med Res Methodol. 2019;19(1):132. doi: 10.1186/s12874-019-0782-0 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 27.Khalil H, Tricco AC. Differentiating between mapping reviews and scoping reviews in the evidence synthesis ecosystem. J Clin Epidemiol. 2022;149:175–82. doi: 10.1016/j.jclinepi.2022.05.012 [DOI] [PubMed] [Google Scholar]
- 28.Pollock D, Davies EL, Peters MDJ, Tricco AC, Alexander L, McInerney P, et al. Undertaking a scoping review: A practical guide for nursing and midwifery students, clinicians, researchers, and academics. J Adv Nurs. 2021;77(4):2102–13. doi: 10.1111/jan.14743 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 29.Peters MDJ, Marnie C, Tricco AC, Pollock D, Munn Z, Alexander L, et al. Updated methodological guidance for the conduct of scoping reviews. JBI Evid Implement. 2021;19(1):3–10. doi: 10.1097/XEB.0000000000000277 [DOI] [PubMed] [Google Scholar]
- 30.Holland R, Lenaghan E, Harvey I, Smith R, Shepstone L, Lipp A, et al. Does home based medication review keep older people out of hospital? The HOMER randomised controlled trial. BMJ. 2005;330(7486):293. doi: 10.1136/bmj.38338.674583.AE [DOI] [PMC free article] [PubMed] [Google Scholar]
- 31.Pacini M, Smith RD, Wilson ECF, Holland R. Home-Based Medication Review in Older People. PharmacoEconomics. 2007;25(2):171–80. [DOI] [PubMed] [Google Scholar]
- 32.Raynor DK, Nicolson M, Nunney J, Petty D, Vail A, Davies L. The development and evaluation of an extended adherence support programme by community pharmacists for elderly patients at home. Int J Pharm Pract. 2000;8(3):157–64. [Google Scholar]
- 33.Lenaghan E, Holland R, Brooks A. Home-based medication review in a high risk elderly population in primary care--the POLYMED randomised controlled trial. Age Ageing. 2007;36(3):292–7. doi: 10.1093/ageing/afm036 [DOI] [PubMed] [Google Scholar]
- 34.Thomas C. Evaluation of home-based medicines reviews for elderly patients no longer able to self-manage their medicines. Int J Pharm Pract. 2017;25:48. [Google Scholar]
- 35.Souter C, Kinnear A, Kinnear M, Mead G. A pilot study to assess the practicality, acceptability and feasibility of a randomised controlled trial to evaluate the impact of a pharmacist complex intervention on patients with stroke in their own homes. Eur J Hosp Pharm. 2017;24(2):101–6. doi: 10.1136/ejhpharm-2016-000918 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 36.Hurley D. Accurately attributing reduced hospital admissions to medications optimisation? Pharmacoepidemiol Drug Saf. 2018;27:8. [Google Scholar]
- 37.Garfield SF, Wheeler C, Etkind M, Ogunleye D, Williams M, Boucher C. Providing pharmacy support to housebound patients: learning from the COVID-19 pandemic. Int J Pharm Pract. 2022;30(Supplement_1):i22-3. [Google Scholar]
- 38.Royal Pharmaceutical Society. Pharmacists and GP Surgeries [Internet]. 2014. https://www.rpharms.com/Portals/0/RPS%20document%20library/Open%20access/Policy%20statements/pharmacists-and-gp-surgeries.pdf
- 39.Royal Pharmaceutical Society. Care Home and Housebound Multidisciplinary Polypharmacy Reviews [Internet]. Polypharmacy. [cited 2024 Oct 20]. https://www.rpharms.com/recognition/setting-professional-standards/polypharmacy [Google Scholar]
- 40.Latif A. Community pharmacy medicines use review: current challenges. Integr Pharm Res Pract. 2018;7:83. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 41.Abbott RA, Moore DA, Rogers M, Bethel A, Stein K, Coon JT. Effectiveness of pharmacist home visits for individuals at risk of medication-related problems: a systematic review and meta-analysis of randomised controlled trials. BMC Health Serv Res. 2020;20(1):39. doi: 10.1186/s12913-019-4728-3 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 42.Spinewine A, Fialová D, Byrne S. The role of the pharmacist in optimizing pharmacotherapy in older people. Drugs Aging. 2012;29(6):495–510. doi: 10.2165/11631720-000000000-00000 [DOI] [PubMed] [Google Scholar]
- 43.Naunton M, Peterson GM. Evaluation of Home‐Based Follow‐Up of High‐Risk Elderly Patients Discharged from Hospital. Pharmacy Practice and Res. 2003;33(3):176–82. doi: 10.1002/jppr2003333176 [DOI] [Google Scholar]
- 44.Craske ME, Hardeman W, Steel N, Twigg MJ. Components of pharmacist-led medication reviews and their relationship to outcomes: a systematic review and narrative synthesis. BMJ Qual Saf. 2024;33(12):808–22. doi: 10.1136/bmjqs-2024-017283 [DOI] [PubMed] [Google Scholar]
- 45.Saeed D, Carter G, Parsons C. Interventions to improve medicines optimisation in frail older patients in secondary and acute care settings: a systematic review of randomised controlled trials and non-randomised studies. Int J Clin Pharm. 2022;44(1):15–26. doi: 10.1007/s11096-021-01354-8 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 46.Birt L, Wright DJ, Blacklock J, Bond CM, Hughes CM, Alldred DP, et al. Enhancing deprescribing: A qualitative understanding of the complexities of pharmacist-led deprescribing in care homes. Health Soc Care Community. 2022;30(6):e6521–31. doi: 10.1111/hsc.14099 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 47.NHS England. NHS England » Structured medication reviews and medicines optimisation [Internet]. [cited 2025 Jul 2]. https://www.england.nhs.uk/primary-care/pharmacy/smr/
- 48.Skivington K, Matthews L, Simpson SA, Craig P, Baird J, Blazeby JM, et al. A new framework for developing and evaluating complex interventions: update of Medical Research Council guidance. BMJ. 2021;374:n2061. doi: 10.1136/bmj.n2061 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 49.O’Cathain A, Croot L, Duncan E, Rousseau N, Sworn K, Turner KM, et al. Guidance on how to develop complex interventions to improve health and healthcare. BMJ Open. 2019;9(8):e029954. doi: 10.1136/bmjopen-2019-029954 [DOI] [PMC free article] [PubMed] [Google Scholar]
Associated Data
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Supplementary Materials
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Data Availability Statement
All relevant data are within the paper and its Supporting Information files.