Pharmacist-led New Medicines Service for cardiovascular patients transitioning to primary care: A real-world study on drug-related problems, satisfaction, and self-efficacy

doi:10.21203/rs.3.rs-4731807/v1

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Research Article

Pharmacist-led New Medicines Service for cardiovascular patients transitioning to primary care: A real-world study on drug-related problems, satisfaction, and self-efficacy

https://doi.org/10.21203/rs.3.rs-4731807/v1

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Background

Patients transitioning from hospital to home while starting long-term cardiovascular medicines are likely to experience drug-related problems. The New Medicine Service may support their readmission to primary care.

Aim

To evaluate the implementation of the NMS on drug-related problems, satisfaction with information and self-efficacy in patients who start with cardiovascular medicines. Secondary objectives included identifying risk factors for DRPs and first-fill discontinuation.

Methods

A living-lab study in an outpatient pharmacy and 14 community pharmacies in Almere, the Netherlands, involved patients ≥18 years receiving new cardiovascular prescriptions. Two weeks after dispensing, a telephone counseling session aimed to identify and resolve DRPs. Patient satisfaction and self-efficacy were assessed during a follow-up call. First-fill discontinuation was measured using dispensing data, and logistic regression identified risk factors for DRPs.

Results

Of the 1647 eligible patients, 743 received the NMS. Pharmacist unavailability (33.3%, n=548) led to substantial drop-out. Of all patients, 72.5% experienced ≥1 DRP. NMS improved patients’ satisfaction with information and self-efficacy (p<0.001). Outpatient visits (adj. OR 0.64), cardiovascular medicine in use (adj. OR 0.65), and use of chronic medicines (adj. OR 1.71) influenced DRPs. First-fill discontinuation was the same post-NMS, but patients who experienced a DRP discontinued more often (14.8% vs. 8.6%, p=0.030).

Conclusions

Implementing the NMS in a real-world transitional care setting allowed pharmacists to identify DRPs and provide counseling tailored to patient needs. Patients reported higher satisfaction with information and increased self-efficacy. Priority should be given to at-risk patients for DRPs, and deploy other pharmacy staff to perform the NMS.

Medication initiation

drug-related problems

community pharmacist

transitional care

primary care

medication counseling

Performing the New Medicine Service after initiation of cardiovascular medication in transitional care increases patient safety.
The NMS can contribute to reduce patients’ self-efficacy issues, affiliated with transitional healthcare.
This study was performed in a living lab setting and therefore provides more information about real world evidence, therefore results can probably be easily transferred to other real-life settings.

Cardiovascular diseases are commonly managed with medications, but various barriers, including communication issues and lack of immediate effects, can lead to poor adherence [1–3], which may even be more prominent in transitional care settings due to the involvement of multiple healthcare providers [4, 5]. Cardiovascular medicines typically have long-term prognostic goals and often lack immediate noticeable effects [6]. Consequently, patients’ perceptions can be negatively influenced, leading to intentional or unintentional deviations from their newly prescribed regimen [3, 7–9]. Studies show up to 19% of patients discontinue antihypertensive medication after the first fill, and up to 50% stop within the first six months [10–13].

Supporting patients' adherence to medicines at the beginning of therapy is crucial. Addressing barriers is essential to maximize implementation over time. Adherence, in this context, refers to the extent to which a patient's actual dosing matches the prescribed dosing regimen [14].

The New Medicine Service (NMS) is a pro-active, pharmacist-led intervention designed to support patients at therapy initiation, by identifying drug-related problems and providing tailored information and tools [15]. Studies on the NMS have shown improvements in patient satisfaction, medication knowledge, and medication adherence, as well as cost-effectiveness [15–19].

However, only a few countries have integrated this effective service into usual care provided by pharmacists [15, 16]. In the Netherlands, the NMS has been studied in a randomized controlled trial in primary care, although results may not directly translate to real-life settings, especially in transitional care [17, 18]. Understanding barriers related to healthcare providers and patients is crucial, as they both play important roles in medication adherence [20].

Utilizing a living-lab approach in healthcare settings has proven to enhance innovation development and implementation [21]. This approach involves real-world testing and iterative improvements based on stakeholder feedback.

The primary objective of this study was to evaluate the implementation of the New Medicine Service (NMS) in a real-world setting, using a living lab approach, for patients transitioning from hospital to primary care with newly prescribed cardiovascular medicines intended for long-term use. Specifically, we aimed to assess:

The identification and resolution of patient-reported drug-related problems

Patient satisfaction with medication information

Patient self-efficacy in medication management

Secondary objectives included:

Identifying risk factors associated with drug-related problems

Assessing the rate of and factors contributing to first-fill discontinuation

The study protocol was approved by the Institutional Review Board of the Division of Pharmacoepidemiology and Clinical Pharmacology at Utrecht University (registration number UPF2009, date 28 September 2021). The study was conducted in accordance with the ethical standards laid down in the 1964 Declaration of Helsinki and its later amendments.

To ensure transparent and comprehensive reporting, we adhered to the STROBE (Strengthening the Reporting of Observational Studies in Epidemiology) guidelines. The STROBE checklist, detailing our compliance with these reporting standards, is provided in Appendix 3 [29].

Patient confidentiality and data protection were prioritized. All medical and pharmacy data were anonymized with unique patient IDs and stored on password-protected computers in the outpatient pharmacy. Access was restricted to two researchers (HE, NK) to maintain data security and integrity.

Informed consent was obtained from all individual participants included in the study. Patients were provided with information about the study's purpose, procedures, potential risks and benefits, and their right to withdraw at any time without affecting their medical care.

This study was performed in line with the principles of the General Data Protection Regulation (GDPR) to ensure the protection of personal data.

Study design and setting

A living-lab study was conducted between April 2021 and August 2022 [22]. This study primarily focused on implementing the New Medicine Service (NMS) in participating community pharmacies. Additionally, the NMS was evaluated on several patient-reported outcome measures and first-fill discontinuation. This approach enabled pharmacists' participation and co-creation for a sustainable NMS implementation. Fidelity was promoted through an online self-report system, which tracked call duration, attempts, exclusions, and a limited-information selection list, and was reviewed during monthly meetings [23]. Sharing experiences in meetings led to ongoing improvements, monitoring and facilitating the implementation progress.

The study was conducted at the outpatient pharmacy and 14 community pharmacies of Zorggroep Almere (ZGA), a large multidisciplinary primary healthcare organization in Almere, the Netherlands. ZGA’s community pharmacies are organized in three geographic clusters and gradually implemented the New Medicine Service. The outpatient pharmacy is based within and closely collaborates with the sole general non-teaching hospital (Flevoziekenhuis, 385 beds). City healthcare providers share a unified system for easy information exchange. Outpatient pharmacists have access to hospital files, enabling long-term patient monitoring.

Participants

Community-dwelling patients aged ≥ 18 years, who filled a prescription for a new cardiovascular medicine intended for at least three months (defined as long term use) were eligible for inclusion. The following medicine classes were included: antithrombotic agents (ATC-code: B01), cardiac therapy (C01), diuretics (C03), beta blocking agents (C07), calcium channel blockers (C08), agents acting on the renin-angiotensin system (C09) and lipid modifying agents (C10). According to Dutch healthcare laws, a new cardiovascular prescription means no dispensing’s for that medicine in the prior year, regardless of strength. The new medicine was initially prescribed by a hospital physician at discharge or an outpatient clinic. Patients using automated drug-dispensing systems or receiving pro re nata (PRN) or short-term prescriptions were excluded.

New Medicine Service

In this study, usual care was complemented with the New Medicine Service (NMS) (Appendix 1), consisting of (Fig. 1):

Information transfer: Patients' medicine information was transferred to their GP and community pharmacist after visiting the outpatient pharmacy. The community pharmacist assessed patients' eligibility for participation on a weekly basis using an automated generated list.
Telephone counselling: Eligible patients received a telephone call from their community pharmacist in the second week after starting their new cardiovascular medicine. A semi-structured interview protocol consisting of five open-ended questions with possible follow-up questions was used to identify practical and perceptual barriers to taking medicine (Appendix 2).

Definition of outcomes and data collection

The primary outcome measures were: (1) Drug-related problems (DRPs) experienced by patients at initiation of their medicine, (2) patients’ satisfaction with the information received from the pharmacist and (3) patients’ medicine understanding and self-efficacy. The secondary outcomes were first-fill discontinuation and patient characteristics as risk factors for experiencing a DRP.

Drug-related problems

Community pharmacists collected data on DRPs using the TRIAGE protocol during telephone counselling [26]. The protocol included nine domains of DRPs: (1) practical intake problem, (2) problem with incorporating medicine in daily routine, (3) complexity of medicine regimen, (4) self-reported side effect, (5) failure to recognize necessity, (6) concern about medicine, (7) knowledge gap, (8) patient vulnerability and (9) costs. Pharmacists were also given follow-up actions to address identified DRPs, such as providing advice, assessing discontinuation risk, consulting the prescriber, and providing written information or a medicine schedule [26].

Satisfaction about medicines and self-efficacy

The day after telephone counselling, a pharmacy technician contacted the patient for a follow-up survey, including Satisfaction with Information about Medicines Scale (SIMS) and Medication Understanding and Use Self-Efficacy Scale (MUSE) questionnaires, translated to Dutch [27, 28]. Some questions were removed due to redundancy in translation. SIMS (action and usage (scored 0–7) and potential problems (scored 0–8)) had a maximum score of 15, and MUSE (taking medication (scored 3–12) and learning about medication (scored 4–16)) had a maximum score of 28.

An attempted sample size of 200 patients in the NMS group and 100 in the control group were to complete the questionnaires. This size was chosen to reduce burden on pharmacy staff while ensuring statistical power to detect a clinically significant difference of 2 in the SIMS score at an alpha level of 0.05.

Baseline characteristics and first-fill discontinuation

Patient characteristics and prescription data were obtained from pharmacy and hospital systems. A secondary outcome was the proportion of patients who discontinued their cardiovascular medicine after the first fill, defined as no refills within three months [12].

Data coding and analysis

Baseline characteristics of patients in the NMS and control groups were compared using appropriate statistical tests. Mann-Whitney tests were used for numerical characteristics with non-normal distributions, while Chi-square tests were employed for categorical variables. As a secondary outcome, logistic regression was performed to identify risk factors for DRPs. Akaike's Information Criterion (AIC) and Hosmer and Lemeshow goodness-of-fit test were used to determine the best-fitting model. All data were analysed using SPSS statistics (v28.0.1.1). A p-value of 0.05 was considered statistically significant.

General characteristics

During the study, 2165 patients filled a first prescription for cardiovascular medicines, with 1647 (76.1%) being eligible for inclusion (Fig. 2). The main reasons for exclusion were temporary or pro re nata (PRN) prescriptions (9.6%, n = 208) and pharmacist assessment (8.6%, n = 186). Among the eligible, 743 (45.1%) patients received the NMS, averaging 12.3 ± 4.3 patients, who received telephone counselling per week across the 14 pharmacies. In the NMS group, 240 questionnaires were completed (target was 200).

Of the eligible patients, 904 (54.9%) did not receive the NMS. Unavailability of the pharmacist (33.3%, n = 548) was the primary reason for patients not receiving counselling. Additionally, the NMS could not be provided to 356 patients (21.6%) due to patient-related factors, with the majority being unreachable by the pharmacist (10.6%, n = 174). In the control group, 96 questionnaires were completed out of the targeted 100 (Appendix 4).

Patient characteristics were similar between the NMS group and control group (Table 1). Patients were on average 63.6 ± 12.6 years old, with 44.0% (n = 327) female and 56% (n = 416) male. On average, the NMS was performed 13.5 ± 2.6 days (range 3–27) after first dispensing, lasting approximately 6 minutes (06:18 ± 03:30, range 1–24 minutes).

Table 1

Baseline sociodemographic, medical and medicine-related characteristics of the NMS and control group.
Patient characteristic	NMS group (n = 743)	Control group (n = 96)	P-value
Female (%, (n))	44.0 (327)	47.9 (46)	0.469
Age, year (mean, (SD))	63.6 (12.6)	61.4 (13.5)	0.180
Hospital department (%, (n))
Cardiology	54.5 (405)	37.5 (36)	0.109
Internal medicine	16.4 (122)	21.9 (21)
Neurology	11.7 (87)	17.7 (17)
Emergency	8.6 (64)	10.4 (10)
Surgery	4.7 (35)	6.3 (6)
Pulmonary	3.5 (26)	5.2 (5)
Other	0.5 (4)	1.0 (1)
Cardiovascular (CV) medicines
Discharge prescription* (%, (n))	43.9 (326)	46.9 (45)	0.578
Outpatient clinic prescription (%, (n))t	56.1 (417)	53.1 (51)
CV medicines in use (mean, (SD, range))	1.9 (1.9, 0–9)	1.9 (1.8, 0–7)	0.850
CV medicines started (mean, (SD, range))	1.8 (1.1, 1–6)	1.7 (1.2, 1–6)	0.318
Other prescription medicines in use
Other prescription medicines in use (mean, (SD, range))**	2.4 (2.4, 0–16)	2.4 (2.6, 0–17)	0.696
* The other prescriptions originated from the outpatient clinics
** Medicines for long-term use only, topical treatments excluded

Fewer patients (43.9%, n = 326) filled their prescription after hospital discharge compared to those who visited the outpatient clinic. Approximately two-thirds of the patients (67.0%, n = 498), had no cardiovascular medicines in use at time of dispensing the new prescription. Most patients (78.6%, n = 584) used other prescription medicines.

Drug-related problems

A total of 1,043 DRPs were identified for 679 patients (91.4% of all the patients who received the NMS (743), 64 were excluded due to missing data-collection sheets), a mean number of 1.5 ± 1.5 DRPs per patient (range 0–9) (Table 2, Appendix 5). For 187 (27.5%) patients, pharmacists identified no DRPs, while 291 (42.9%) patients experienced multiple DRPs. The three major DRP categories were “Self-reported side effect” (28.7%, n = 299), “Complexity of medicine (regimen)” (25.7%, n = 268), and “Knowledge gap” (11.3%, n = 118) (Appendix 5). Patients discharged from the hospital (78.3%, n = 238 versus 67.7%, n = 254; p = 0.002) and those not previously using cardiovascular medicine (77.9%, n = 173 versus 69.8%, n = 319; p = 0.026) were more prone to experience a DRP.

Table 2

Number and categories of identified DRPs and performed follow-up actions to address that DRP by the pharmacist.
DRP category	Identified DRPs (n = 1043) (%, (n))	Performed follow-up actions (n = 1711) (%, (n))
Practical intake problem	5.5 (57)	4.4 (76)
Problem with incorporating medicine in daily routine	4.6 (48)	3.2 (54)
Complexity of medicine (regimen)	25.7 (268)	16.6 (284)
Self-reported side effect	28.7 (299)	24.4 (418)
Fail to recognize the necessity of medicine	9.8 (102)	25.9 (443)
Concern about medicine	9.1 (95)	12.0 (206)
Knowledge gap	11.3 (118)	9.1 (156)
Vulnerable patient	5.1 (53)	4.1 (70)
Costs	0.3 (3)	0.2 (4)

The 1,043 DRPs resulted in 1,711 follow-up actions by pharmacists, averaging 3.3 ± 2.1 per patient and 1.7 ± 1.0 per DRP. The most common issues were patients’ “Failure to recognize the necessity of their medicine” (25.9%, n = 443), “Self-reported side effect” (24.4%, n = 418), and “Complexity of medicine regimen” (16.6%, n = 284). Pharmacists provided counselling, reassurance, and guidance on medication management in response to these issues.

A multivariate regression analysis identified potential risk factors associated with DRPs (Table 3). Patients using prescription medicines for other comorbidities had an 1.71 times higher odds (95%-CI 1.10–2.66) of experiencing a DRP, compared to patients with no other medicines in use. Prescriptions from outpatient visits had an lower odds (OR 0.64, 95%-CI 0.43–0.94) of resulting in DRPs compared to prescriptions received after hospital discharge. Patients already using other cardiovascular medicines had lower odds (OR 0.65, 95%-CI 0.42-1.00) of experiencing a DRP. Finally, the odds of experiencing a DRP decreased with age (OR 0.98, 95%-CI 0.97-1.00 per year).

Table 3

Univariate and multivariable logistic regression analysis for patient characteristics and their effect on experiencing a DRP.
Characteristic	Compared to	OR unadjusted (95% CI)	P-value unadjusted	OR adjusted (95% CI)	P-value adjusted
Age (years)	Age (years)	0.99 (0.97-1.00)	0.060	0.98 (0.97-1.00)	0.025
Female sex	Male sex	0.93 (0.66–1.30)	0.654	0.97 (0.69–1.38)	0.875
Outpatient clinic prescription	Hospital discharge prescription	0.58 (0.41–0.83)	0.002	0.64 (0.43–0.94)	0.024
Prescription from cardiology department	Prescription from other department	1.18 (0.84–1.66)	0.332	1.21 (0.84–1.74)	0.298
CV medicines in use	No CV medicines in use	0.66 (0.45–0.95)	0.027	0.65 (0.42-1.00)	0.048
> 1 CV medicines started	≤ 1 CV medicines started	1.40 (0.99–1.98)	0.054	1.11 (0.76–1.63)	0.298
Other prescription medicines in use	No other prescription medicines in use	1.52 (1.02–2.27)	0.039	1.71 (1.10–2.66)	0.018

Satisfaction about medicine and self-efficacy

Pharmacy technicians collected 240 follow-up questionnaires for the NMS group and 96 for the control group (Table 4).

Table 4

SIMS and MUSE scores for the NMS and control group.
Scores (median, [IQR])	NMS group (n = 240)	Control group (n = 96)	P-value
SIMS score	13 [10–15]	10 [7–12]	< 0,001
Action and Usage	7 [6–7]	5.5 [4-6.75]	< 0,001
Potential problems	7 [4–8]	4.5 [2-6.75]	< 0,001
MUSE score	22 [21–28]	21 [20–21]	< 0,001
Taking medication	9 [9–12]	9 [9–9]	< 0,001
Learning about medication	12 [12–16]	12 [12–12]	< 0,001

Overall, patients who received the NMS were more satisfied with the information they received, with a median score of 13 (IQR 10–15) versus 10 (IQR 7–12) for the control group (p < 0.001). They also scored higher on both subscales: action and usage (7 (IQR 6–7) versus 5.5 (IQR 4-6.75)) and potential problems (7 (IQR 4–8) versus 4.5 (IQR 2-6.75)) (p < 0.001).

Furthermore, patients who received the NMS reported higher medicine understanding and self-efficacy (median score of 22 (IQR 21–28) versus 21 (IQR 20–21) (p < 0.001)) including both their scores for the taking medication (9 (9–12) versus 9 (9–9)) and learning about medication (12 (IQR 12–16) versus 12 (IQR 12–12)) subscales (p < 0.001). Experiencing a DRP did not affect SIMS and MUSE scores.

First-fill discontinuation

Patients in the NMS group and control group were comparable regarding first fill discontinuation (13.3% versus 12.5%, p = 0.822) and late collection of their first refill (3.0% versus 4.2%, p = 0.521). Patient who experienced a DRP were more likely to discontinue their medicine after their initial first fill compared to patients who did not experience a DRP (14.8% versus 8.6%, p = 0.030). There was no difference in late refills (3.9% versus 1.1%, p = 0.060). Finally, the SIMS and MUSE scores were comparable between patients who discontinued or continued after their first fill (p = 0.293 and p = 0.373, respectively).

Statement of key findings

This study demonstrated that implementing the New Medicine Service (NMS) in a real-world setting upon readmission to primary care led to successful initiation of cardiovascular medicines. The NMS enabled pharmacists to identify Drug-Related Problems (DRPs) in most patients and provide additional counselling. Patients were more satisfied with the information received about their medicine and reported higher self-efficacy and medicine understanding. Those at higher risk of DRPs were recently discharged from the hospital, new to cardiovascular medication, taking other prescriptions, and younger. However, the NMS did not improve first-fill discontinuation.

Previous studies align with our findings, showing that DRP frequency varies by classification, patient population, medication type, and follow-up time [30]. Primary care studies show that many patients, starting new cardiovascular medicines, experience DRPs, including side effects, practical problems, and information needs [5, 9, 19].

At care transitions, adequate patient communication is crucial to ensure continuity of care and reduce DRPs [31]. Patient-provider communication is known to be an important predictor of patient satisfaction [32, 33]. Providing adequate pharmacy counselling and detailed medication information can improve patients' knowledge, beliefs, adherence [34], and attitudes towards services aimed at improving medication outcomes [19].

Patients only learn how a medicine affects them once they start taking it, leading to new questions and concerns about necessity, side effects, and long-term consequences. These issues influence adherence and are not typically addressed in standard pharmacy care [2]. This study showed that the NMS, when added to usual care, effectively fills the information gap, improving patients’ self-efficacy and understanding of their medicine, similar to other telephone-based strategies [35].

Telephone follow-up is a flexible, cost-effective way to improve patient adherence [36]. However, about a quarter of patients did not receive the NMS due to pharmacist time constraints (15.3%) or assessments (8.6%) Several efforts were made to facilitate implementation, including engagement with the pharmacists, co-creation and piloting of the protocol, and monthly monitoring meetings to discuss and solve implementation barriers [37, 38]. However, these efforts alone seem to be insufficient. Therefore, deploying well-trained pharmacy practitioners or pharmacy technicians to perform the NMS together with pharmacists could be a potential facilitator to overcome time constraints and increase patient counselling [17].

To increase efficiency, pharmacists should identify patients most likely to benefit from NMS by considering their risk factors for drug-related problems. Different beliefs about service goals among pharmacists can affect fidelity to the NMS [37]. This study found that patients experiencing a DRP were more likely to discontinue medication after the first fill [39]. Consistent with other studies, patients using non-cardiovascular medicines, indicating regimen complexity and comorbidity, were at higher risk for DRPs [12, 13]. Additionally, younger patients and those discharged from the hospital who had not used cardiovascular medicines before were more at risk.

Strengths and limitations

This study’s main strength was its real world setting, providing insights into the practical implementation of the NMS. Potential selection bias due to pharmacists' professional assessments was minimized by providing a limited-information selection list and monthly reviews of exclusion reasons. Additionally, patients with positive attitudes towards pharmaceutical care may have been more likely to participate in follow-up, potentially overestimating satisfaction and self-efficacy, though this likely affected both groups equally, and a significant effect was still observed.

The study aimed to evaluate the NMS's real-world impact without standardizing intervention delivery. Pharmacists shared their experiences and barriers during scheduled meetings. Lastly, pharmacy technician contact with the control group might have increased awareness of medication effects, potentially influencing adherence and reducing differences between groups.

Interpretation

This study is the first to implement the NMS in transitional care using a pragmatic living-lab approach [21]. By involving pharmacists in the design and real-life testing of the intervention, the study addressed challenges and enhanced generalizability for real-world practices.

The evaluation aimed to assess the NMS's effectiveness and feasibility in supporting patients during medication initiation after hospital discharge or outpatient visits, using real-world data to inform clinical practice and policy decisions on pharmacist-led interventions in transitional care.

Further research

Earlier studies show the applicability of the NMS to other medicines as well; therefore, the NMS performed in this setting could serve as the basis for an extended follow-up adherence intervention. Additionally, a cost-effectiveness analysis could enhance the evaluation of the intervention [17, 40].

Implementing the NMS in a real-world transitional care setting enabled pharmacists to identify drug-related problems and provide tailored counselling. Patients were more satisfied with the information and had higher self-efficacy after counselling. This shows that the NMS is valuable for patients starting cardiovascular medicines at readmission to primary care. Pharmacist unavailability was the main reason for patients not receiving the NMS. Pre-selecting high-risk patients and involving other pharmacy staff to perform the NMS might be warranted to improve implementation and reach more patients who could benefit from this service.

Acknowledgements

We would like to thank the pharmacists and patients for their cooperation.

Funding

This work was supported by ZonMW, The Netherlands Organization for Health Research and Development, The Hague, The Netherlands (grant number 848024021). The funding source had no role in the design, data collection, analysis or interpretation of the study, or in the decision to submit the manuscript for publication.

Conflict of interest

None.

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APPENDIX1HealthcareinAlmereTheNetherlandsjuly2024.doc
Appendix 1. Dutch usual healthcare and the adoption of the New Medicine Service (NMS) in this setting.
APPENDIX2Interviewprotocoljuly2024.doc
Appendix 2. Semi-structured interview protocol of the New Medicine Service.
APPENDIX3STROBEstatementjuly2024.doc
Appendix 3. STROBE Statement.
APPENDIX4Inclusionparticipantscontroljuly2024.ppt
Appendix 4. Patient flow chart for the control group.
APPENDIX5IdentifiedDRPsandactionsextendedjuly2024.doc
Appendix 5. Number and categories of identified DRPs (n = 1043, left) and performed follow-up actions (n = 1711, right) to address that DRP by the pharmacist (extended).
STATEMENTNMScardiopatientjuly2024.doc

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Editorial decision: Major revisions
26 Sep, 2024
Reviewers agreed at journal
04 Sep, 2024
Reviewers invited by journal
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Editor invited by journal
27 Aug, 2024
Editor assigned by journal
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Pharmacist-led New Medicines Service for cardiovascular patients transitioning to primary care: A real-world study on drug-related problems, satisfaction, and self-efficacy

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Version 1

Abstract

Figures

Impact of findings on practice statements

Introduction

Aim

Ethics approval

Method

Study design and setting

Participants

New Medicine Service

Definition of outcomes and data collection

Drug-related problems

Satisfaction about medicines and self-efficacy

Baseline characteristics and first-fill discontinuation

Data coding and analysis

Results

General characteristics

Drug-related problems

Satisfaction about medicine and self-efficacy

First-fill discontinuation

Discussion

Statement of key findings

Strengths and limitations

Interpretation

Further research

Conclusion

Declarations

Acknowledgements

Funding

Conflict of interest

References

Supplementary Files

Status:

Version 1