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Background:
Systematic Review

Community Pharmacist-Led Interventions to Improve Preconception and Pregnancy Health: A Systematic Review

by
Polly A. Scott
1,
Ola F. Quotah
1,
Kathryn V. Dalrymple
1,
Sara L. White
1,
Lucilla Poston
1,
Jessica Farebrother
2,
Shivali Lakhani
3,
Marsha Alter
3,
Mitch Blair
4,
John Weinman
5 and
Angela C. Flynn
6,*
1
Department of Women and Children’s Health, School of Life Course Sciences, King’s College London, London SE1 7EH, UK
2
Human Nutrition Laboratory, Institute of Food, Nutrition and Health, ETH Zurich, 8092 Zurich, Switzerland
3
The Middlesex Pharmaceutical Group of LPCs, 1278 High Road, Whetstone, London N20 9HH, UK
4
Department of Primary Care and Public Health, Imperial College London, London SW7 2AZ, UK
5
Institute of Pharmaceutical Sciences, King’s College London, London SE1 9NH, UK
6
Department of Nutritional Sciences, School of Life Course Sciences, King’s College London, London SE1 9NH, UK
*
Author to whom correspondence should be addressed.
Pharmacy 2021, 9(4), 171; https://doi.org/10.3390/pharmacy9040171
Submission received: 27 September 2021 / Revised: 13 October 2021 / Accepted: 13 October 2021 / Published: 16 October 2021
Browse Figure
Versions Notes

Abstract

:
Background: Community pharmacist-led interventions are effective in improving health outcomes; however, their impact in improving preconception and pregnancy health is not clear. This study evaluated the effectiveness of community pharmacist-led interventions which aimed to improve health outcomes of preconception and pregnant women. Methods: A systematic review of the literature, consistent with PRISMA guidelines, was performed. Five electronic databases were searched up to February 2021. Results: Four studies, three in pregnant women and one in preconception women, were identified. The studies focused on improving micronutrient status and smoking cessation. The studies increased knowledge about, and use of, iron supplements, and improved iron status and smoking cessation rates in pregnant women, while improving knowledge regarding, and increasing the use of, preconception folic acid. The studies were ranked as weak to moderate quality. Conclusion: This review provides preliminary evidence for the potential benefit of community pharmacist-led interventions to improve the health of women before and during pregnancy.

1. Introduction

Over the last decade, the prevalence of obesity has increased [1] with significant consequences for maternal, infant and childhood outcomes. This has stimulated a public health focus to promote healthier lifestyles amongst pregnant women and those contemplating pregnancy [2,3]. It is also well recognised that sub-optimal nutrition during pregnancy can increase the risk of micronutrient deficiencies implicated in poor foetal growth and development [4]. Unhealthy dietary patterns and micronutrient deficiencies amongst pregnant women are commonly reported [5,6,7] in addition to low physical activity levels [8], smoking [9] and alcohol consumption [10].
Sub-optimal health behaviours and risk factors for adverse pregnancy outcomes are usually established well before conception. Our recent survey, which described health behaviours of over 130,000 UK women planning pregnancy, showed that 20% were smokers, less than one third took folic acid supplements and approximately half were consuming alcohol. Only half were undertaking the weekly recommended physical activity level or were consuming five portions of fruit or vegetables 4 days a week [11].
Whilst antenatal services provide point of care opportunities to deliver health behaviour advice in pregnancy, preconception care is notably absent [12]. Community settings have intrinsic, yet unmet, advantages for delivering public health initiatives to improve preconception—as well as pregnancy—health. Community pharmacists are ideally placed to inform and disseminate key health messages, which may be particularly advantageous in engaging women in areas of high deprivation. A UK study demonstrated that nearly 90% of the population can walk to a community pharmacy within 20 minutes, which increased to 100% in highly deprived areas [13].
A systematic review, conducted in 2016, showed the effectiveness of community pharmacist-led intervention in smoking cessation and the feasibility of pharmacy-delivered weight management interventions in the general population [14]. However, the impact of interventions targeting preconception and pregnant women, delivered by community pharmacists, has not been evaluated. This systematic review aimed to assess the effectiveness of community pharmacist-led interventions to improve health outcomes in women in the preconception period and/or during pregnancy.

2. Materials and Methods

The systematic review was conducted in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) statement [15] (Supplementary Information S1). The review was registered in the PROSPERO database, registration number CRD42021232334.

2.1. Inclusion and Exclusion Criteria

The inclusion and exclusion criteria were guided by the PICOS (participants, intervention, comparisons, outcomes and study design) framework, outlined in Table 1. For inclusion, studies had to meet the following criteria: (1) randomised controlled trial (RCTs) or non-RCTs (nRCTs) comparing community pharmacist-delivered interventions to inactive or usual care controls; (2) interventions targeting pregnant women or those planning pregnancy; (3) studies reporting health outcomes including weight status, physical activity, nutrition, micronutrient supplementation, smoking and alcohol status. Studies meeting the following criteria were excluded: (1) observational or qualitative research; (2) abstracts; (3) women aged less than 18 years or older than 50 years; (4) interventions delivered by pharmacists within a hospital or online; (5) studies not published in English. Studies that included pharmacists based in community pharmacies or community health centres were included. Interventions that included the involvement of the wider pharmacy team and contributions from multidisciplinary professionals were also considered. There was no restriction on study duration.

2.2. Literature Search

The following databases were searched up to 16/02/2021: EMBASE, MEDLINE, PsycINFO, Cumulative Index to Nursing and Allied Health Literature (CINAHL), and the Cochrane Library. The search strategy for EMBASE and MEDLINE are outlined in Supplementary Information S2. This search was limited to human studies. No limits were placed on the country of study or study date.

2.3. Study Selection and Data Extraction

Following the removal of duplicates in EndNote X9, the results were exported into Rayyan, a systematic review software. Titles and abstracts were independently screened against the eligibility criteria by three reviewers (PS, OQ and AF). For studies that met the inclusion criteria, the full text articles were retrieved. Reference lists of articles were also searched to identify any eligible studies. The corresponding authors of 2 studies were contacted to confirm the role of the pharmacist [16,17]. Any disagreements between reviewers were resolved through a consensus opinion among the authors (PS, OQ and AF).
Data extraction was performed by one reviewer (PS) and independently cross checked by two reviewers (AF and OQ). The extracted data were entered into standardised tables designed for this review, with studies ordered alphabetically according to the surname of the first author.

2.4. Quality Assessment

Study quality was appraised using the Effective Public Health Practice Project Quality Assessment Tool for Quantitative Studies [18]. Studies were rated using six criteria: selection bias, study design, confounders, blinding, data collection methods and withdrawals/dropouts. Studies were allocated a strong, moderate, or weak overall rating accordingly. Intervention integrity and analysis was also assessed, although this did not contribute to the overall ratings. Quality assessment was performed by two reviewers (PS and OQ). Any disagreements were again resolved through a consensus opinion among the authors (PS, OQ and AF).

2.5. Analysis and Synthesis

A narrative synthesis was performed, which followed the Synthesis Without Meta-Analysis (SWiM) guidelines [19].

3. Results

The study selection process is outlined in Figure 1. The literature search identified 1478 articles, and an additional two articles were identified through searching of reference lists. Following screening of titles and abstracts, ten articles were eligible for full text screening, of which four were included [20,21,22,23] and six excluded [16,17,24,25,26,27]. Reasons for exclusion included incorrect intervention setting, inappropriate study design or a target population that did not include pregnant women or those planning pregnancy.

3.1. Study Characteristics

The characteristics of included studies are summarised in Table 2. These studies included a randomised pre–post control design [20], a quasi-experimental pretest–posttest control group design [23], a pilot study with randomly allocated intervention and reference pharmacies [21], and a pilot study without a control group [22]. The studies were conducted in Indonesia [20,23], the Netherlands [21] and Scotland [22], respectively. The study aims were to improve adherence to iron supplement tablets (ISTs) and improve haemoglobin (Hb) levels during pregnancy [20], improve the knowledge and use of ferrous fumarate during pregnancy [23], promote smoking cessation during pregnancy [22], and improve the knowledge and use of folic acid supplements before pregnancy [21]. The duration of the interventions varied from 30 days [20,23] to 6 months [21,22].

3.2. Study Population

One study recruited women before pregnancy [21], whilst three recruited pregnant women [20,22,23], with one study specifically including women in the first and second trimesters [23]. Women were recruited through community pharmacies and community health centres. One study additionally utilised General Practitioners (GPs), antenatal clinics and libraries to provide information on the study [22]. The sample size ranged from 26 [23] to 880 women [21]. The gestational age of participants was reported in one study; within the control group, 21.9% were in the first trimester, 25% were in the second trimester and 53.1% were in the third trimester. This compared to 20.8% in the first trimester, 38.5% in the second trimester and 40.6% in the third trimester in the intervention group [20].

3.3. Study Interventions

All the interventions were delivered by pharmacists with support from the wider pharmacy team (Table 3). Heryadi et al. provided a single session of pharmacist-led counselling to pregnant women attending a community health centre within which a pharmacy was based. The session used a media leaflet and focused on reducing maternal anaemia through counselling on the importance of adherence to ISTs which were routinely prescribed through a government program. Participants were also advised on the correct consumption patterns of ISTs, which included information on the impact of calcium supplements, food and beverages on iron absorption [20].
Kusumawardani et al. also provided a single session of pharmacist-led counselling to women in the first and second trimester attending a community health centre. The counselling followed the 5A method, which aims to improve adherence to medication. This involved assessing the participants’ habits and knowledge regarding their current medication, advising the individual on the advantages and disadvantages of behaviour change, agreeing on a plan, assisting the identification of personal barriers to medication adherence, and arranging an evaluation or follow up. This aimed to improve knowledge on—and adherence to—ferrous fumarate for the prevention or treatment of maternal iron deficiency. This was the only study that referred to a specific behaviour change strategy [23].
The ‘Give It Up For Baby’ (GIUFB) programme was the basis of an antenatal smoking cessation scheme. The scheme was offered in community pharmacies within three intervention areas (area 1, area 2 and area 3) across Tayside. It involved participants attending an initial meeting with pharmacists to set a quit date, complete an interview and provide nicotine replacement therapy (NRT) if appropriate. Women attended the pharmacies every week for advice, behavioural support and carbon monoxide (CO) breath tests. Financial rewards to use in supermarkets were provided after every negative CO breath test. Participants attended weekly sessions for 12 weeks and were offered the opportunity to extend the intervention for up to 3 months postpartum [22].
In preconception women, Meijer et al. provided participants with education on folic acid supplementation. The intervention involved adding a sticker to boxes of oral contraceptives prescribed in the intervention pharmacies within the study period. The sticker included the text ‘Are you planning to have a baby? Ask for more information about folic acid in your pharmacy’. This was supplemented with an educational leaflet handed out by pharmacists alongside the prescriptions. The education aimed to inform and motivate women to ensure they took folic acid supplements whilst planning a pregnancy. The pharmacy teams were encouraged by researchers to further develop the intervention, which included trialling the use of posters, window displays, explanatory letters, ‘theme weeks’ and the provision of additional spoken information by pharmacists [21].
The comparison groups varied between the studies. Heryadi et al. included a control group where participants did not receive pharmacist-led counselling on adherence to ISTs and the prevention of maternal anaemia [20]. Kusumawardani et al. provided the control group with medication information as part of the normal practice at the community health centre [23]. Reference pharmacies were used by Meijer et al. [21], within which stickers and leaflets on folic acid supplements were not provided. In the work of Radley et al., the influence of the financial incentive intervention on smoking cessation rates in pregnant women was compared between the three intervention areas [22]. Although the same intervention was provided, this demonstrated the effect of intervention in areas of differing social deprivation. This study also made comparisons with data on smoking cessation rates among all pregnant women in Scotland [28].

3.4. Study Outcomes

The study outcomes are summarised in Table 4. In the report by Heryadi et al., the Hb concentration in the intervention group increased from 10.39 ± 1.24 g/dL before the intervention to 11.52 ± 0.92 g/dL post-intervention (p < 0.001). There was no significant change in the control group (p = 0.3). Between treatment groups, the Hb concentration increased in the intervention group by 8.6 times compared to the control group (odds ratio (OR) = 8.6, p < 0.05) after controlling for confounders. In the intervention group, 49% took 31–45 ISTs and 16.7% took 46–60 ISTs, compared to 2.1% and 1% in the control group, respectively. The calcium and IST consumption pattern improved from 0.39 ± 0.49 to 1.0 ± 0.0 in the intervention group (p < 0.001). Similarly, the food consumption patterns improved from 0.27 ± 0.45 to 0.03 ± 0.17 (p < 0.001). The calcium and food consumption patterns did not significantly change within the control group (p = 1) [20].
The study by Kusumawardani et al. found improvements in knowledge, perceptions, and adherence to ferrous fumarate tablets in the intervention group. Knowledge on anaemia and ferrous fumarate tablets did not differ between groups prior to intervention (p = 0.343) but was significantly different post intervention (p < 0.001, relative risk (RR) 4.54, 95% confidence interval (CI) 1.62–12.72). Similarly, adherence to ferrous fumarate tablets was not significantly different prior to intervention (p = 0.234), however became significant following intervention (p < 0.001, RR 10.29, CI 1.56–67.99). Positive and negative perceptions of taking ferrous fumarate were not significantly different between groups before intervention (p = 0.420). Following intervention, the perceptions were significantly different between groups (p < 0.001, RR 4.54, CI 1.62–12.72) [23].
The GIUFB programme reported quit rates of 54% at 4 weeks, 32% at 12 weeks and 17% at 3 months post-partum. Overall, 7.8% women stopped smoking in the intervention areas compared to the national average in Scotland of 3.9%. Comparisons were made between quit rates across the three areas providing the intervention, which were classified as having variable levels of social deprivation. The 47.5% 4-week quit rate in area 1 was significantly different to the 59.7% 4-week quit rate in area 2 (p = 0.03). The 21.5% quit rate at 3 months postpartum in area 2 was also different to the 10.1% quit rate in area 3 (p = 0.03) [22].
In preconception women, Meijer et al. reported that 62.5% and 20.8% of nulliparous intervention women were using or intending to use folic acid supplements, respectively, compared to 30.8% and 7.7% in the control group (p = 0.02). In multiparous women, 45% of the intervention group and 6.7% of the control group were aware of the correct time period to use folic acid supplements (p = 0.01) [21].

3.5. Study Quality

The studies received global ratings from ‘moderate’ [20,23] to ‘weak’ [21,22]. This was largely due to a lack of control for confounders and lack of information on randomisation. Furthermore, two studies had a pilot study design. Pilot studies are generally underpowered to detect statistically relevant results; however, they can be used to inform on larger studies [29]. The individual ratings for the quality assessment are shown in Supplementary Information S3.

4. Discussion

This systematic review provides some evidence to suggest that community pharmacist-led interventions improved adherence to iron supplements, iron status and smoking cessation rates in pregnant women in addition to increasing awareness and use of folic acid supplements in women before pregnancy. However, the findings are limited by the small number and quality of the studies included.
Pharmacist-led educational counselling on the importance and use of iron supplements to reduce anaemia improved iron status in Indonesian pregnant women routinely prescribed iron supplements [20]. Similarly, pharmacist-led counselling improved knowledge on—and perceptions and use of—ferrous fumarate tablets [23]. Normal foetal growth and development is dependent upon maternal iron sufficiency during pregnancy and iron deficiency is common in pregnant women, with an estimated global prevalence of 38% [30]. Iron deficiency can lead to an increase in adverse maternal and infant outcomes [31,32]. Routine iron supplementation in pregnancy is not universal. In the UK, for example, it is recommended that women are tested for deficiency in early and late pregnancy [33]. Management of iron deficiency includes dietary advice and oral iron preparations [34]. Community-based pharmacists are ideally placed to provide advice to pregnant women on increasing dietary iron intake in addition to the optimisation of iron supplement use as part of an antenatal healthcare team.
In addition to iron supplements, Meijer et al. showed that community pharmacists improved knowledge about—and use of—folic acid supplements in women in the preconception period. In women who had a previous pregnancy, the only significant difference was increased knowledge of the correct time period to use supplements, which suggests that these women may already have had some understanding on the importance of folic acid supplements. There is a current shift in focus towards optimising health before pregnancy, with the preconception period being highlighted as critical for health across generations [3]. For example, folic acid supplementation in the preconception period can reduce neural tube defects by up to 70% [35]. We previously demonstrated poor folic acid usage in UK women planning pregnancy [11], which is consistent with other reports [36,37].
Public health strategies are urgently needed to increase the proportion of women taking folic acid in the preconception period. A systematic review in 2019 demonstrated uptake and acceptance of contraceptive interventions provided by community pharmacists and highlighted the opportunities to expand and integrate preconception care services including counselling on folic acid use [38]. Furthermore, a US study identified numerous opportunities in community pharmacy settings for pharmacists to provide preconception care services including screening for folic acid supplementation [26]. Together with the findings of this review, public health initiatives should consider community-based pharmacists to deliver interventions to improve folic acid knowledge and usage in preconception women.
The interventions targeting iron and folic acid supplementation were provided within one interaction with pharmacists [20,21,23]. Brief interventions are commonly used in healthcare settings, including within the ‘Making Every Contact Count’ approach, which promotes the delivery of health behaviour information within interactions with the health system [39]. The findings from this review suggest that brief interventions delivered by community-based pharmacists are feasible and lead to some improvements in health behaviours of women before and during pregnancy. However, only one study in this review referred to specific behaviour change strategies [23]. Incorporation of behaviour change strategies and training for pharmacists should be considered in future interventions.
The intervention by Radley et al. demonstrated that pharmacist-led education and support improved smoking cessation rates in pregnant women [22]. Maternal smoking is associated with preterm birth [40], stillbirth [41] and sudden infant death syndrome [42]. Cessation of smoking in early pregnancy was shown to prevent adverse outcomes [43]. In addition, smoking cessation intervention led by community pharmacists has been shown to be effective in the general population. This was demonstrated in a meta-analysis by Brown et al., which compared intervention to active comparators (OR 1.21, 95% CI 0.86–1.71) and usual care comparators (OR 2.56, 95% CI 1.45–4.53). Smoking cessation intervention was also found to be cost effective [14]. The findings of this review support the use of community pharmacist-led smoking cessation interventions. Radley et al. used financial incentives to improve smoking cessation rates in pregnant women, which was demonstrated to be effective by a similar scheme expanded to other areas within Scotland [16] and may be a promising strategy.
Community pharmacist-led interventions were previously shown to be effective in improving health behaviours in the general population [14] and in several countries, including in the UK, there are commissioned services that focus on weight management, alcohol reduction and smoking cessation [44]. Poor health behaviours and risk factors for adverse pregnancy outcomes in pregnant and preconception women [3] suggest that services are warranted in these populations. A recent UK pilot project trained pharmacists working in local communities to provide advice to women, before and during pregnancy, on a range of topics including immunisations, early GP and antenatal appointment booking, diet and micronutrient supplementation, smoking cessation and infant feeding. Although not included in the present review, women reported finding the service useful and increased pharmacist knowledge was reported [45]. This supports the findings of the current review as it highlights the potential role that pharmacists can play in improving population health. Despite this, there has been limited research into the effectiveness of community pharmacist-led interventions targeting preconception and pregnant women. Adequately powered, large scale and robust studies are required. As community pharmacists are well positioned to deliver public health initiatives, future research priorities should focus on expanding the role of community pharmacists to improve the physical and mental health of women before and during pregnancy. Importantly, none of the included studies considered the influence of intervention on pregnancy outcomes to determine the long-term effects of improvements in health behaviours.
The strengths of this review include an extensive search of the literature with a comprehensive search strategy. Five electronic databases and reference lists were searched to identify eligible studies. The screening, data extraction and quality assessment processes were all performed in duplicate by independent reviewers. Finally, this review followed the PRISMA guidelines to ensure systematic reporting [15].
There were several limitations. The interpretation of the findings is limited by the small number and quality of the included studies. The inclusion of studies reported in English may have excluded eligible studies and introduced publication bias. The included studies were only within high- and middle-income countries, and therefore, the findings may not be generalisable to other settings. It is also important to acknowledge the focus of this review on pharmacy-based care, despite antenatal care being provided by a multidisciplinary team. Evidence of interventions targeting preconception and pregnant women within different healthcare settings was not considered within this review.

5. Conclusions

Community pharmacists are well positioned to deliver public health initiatives. As demonstrated by the findings of this review, community-based pharmacists can play an important role in improving the health of women before and during pregnancy, which may lead to long term benefits to health. This systematic review found preliminary evidence that community pharmacist-led interventions improved smoking cessation rates, iron status and adherence to iron supplements in pregnancy, in addition to improved use and knowledge of folic acid supplements in women before pregnancy. However, the evidence was of a weak to moderate quality. Despite this, the initial evidence and potential benefits provide rationale for further large-scale studies to assess the effectiveness of utilising community pharmacists to improve life course health.

Supplementary Materials

The following are available online at https://www.mdpi.com/article/10.3390/pharmacy9040171/s1, Supplementary Information S1: PRISMA checklist; Supplementary Information S2: Full search strategy for the MEDLINE and EMBASE databases; Supplementary Information S3: Quality assessment for studies included in the systematic review.

Author Contributions

Conceptualization, K.V.D., S.L.W., L.P., J.F., S.L., M.A., M.B., J.W., A.C.F. and O.F.Q.; methodology, A.C.F., P.A.S. and O.F.Q.; validation, K.V.D., S.L.W., L.P., J.F., S.L., M.A., M.B., J.W., A.C.F. and O.F.Q.; formal analysis, A.C.F., P.A.S. and O.F.Q.; investigation, A.C.F., P.A.S. and O.F.Q.; resources, A.C.F., P.A.S. and O.F.Q.; data curation, A.C.F., P.A.S. and O.F.Q.; writing—original draft preparation, A.C.F., P.A.S. and O.F.Q.; writing—review and editing, A.C.F. and O.F.Q.; visualization, A.C.F., P.A.S. and O.F.Q.; supervision, A.C.F. and O.F.Q.; project administration, A.C.F. and O.F.Q.; funding acquisition. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding. M.B. was partially funded by the National Institute for Health Research (NIHR) Applied Research Collaboration for Northwest London (ARC).NIHR contract number NIHR200180. Orcid 0000-0001-7442-0188. S.L.W. and L.P. were supported by the Tommy’s charity.

Conflicts of Interest

The authors declare no conflict of interest.

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Pharmacy 09 00171 g001 550
Figure 1. Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) flow diagram.
Figure 1. Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) flow diagram.
Pharmacy 09 00171 g001
Table
Table 1. PICOS framework.
Table 1. PICOS framework.
P—PopulationWomen over the age of 18 planning pregnancy or pregnant women
I—InterventionInterventions including smoking cessation, weight management, micronutrient supplementation and alcohol reduction led by a community-based pharmacist
C—ComparisonNon-active or usual care controls
O—OutcomeOutcomes including nutritional intake, levels of physical activity, smoking and alcohol status, micronutrient supplementation and weight status
S—Study typeRCTs and nRCTs
Abbreviations: nRCT, non-randomised controlled trial; RCT, randomised controlled trial.
Table
Table 2. Study characteristics of included studies.
Table 2. Study characteristics of included studies.
ReferenceCountry of StudyAim of StudyStudy DesignSample SizeAge (Years)
Heryadi, Sauriasari and Andrajati, 2017 IndonesiaTo determine the effect of counselling by pharmacists on adherence to ISTs, IST consumption patterns and Hb levelsRandomised before–after controlled trial, single centre192
I: n = 96
C: n = 96		I: 75 (78.1%) aged 21–35
C: 80 (83.3%) aged 21–35
Kusumawardani et al., 2019Indonesia To determine the influence of a brief counseling intervention by pharmacists on knowledge, perceptions, and adherence of pregnant women taking ferrous fumarate Pretest–posttest control trial, single centre26
I: n = 13
C: n = 13		I: 4 (31%) < 20 years, 9 (69%) 20–40 years
C: 6 (46%) < 20 years, 7 (54%) 20–40 years
Meijer et al., 2005The NetherlandsTo assess the effect of information provided by community pharmacies on knowledge, attitudes and use of folic acid among women prescribed oral contraceptivesPilot study with randomly allocated intervention and reference pharmacies, multicentre880
I: n = 600
C: n = 280		I: mean age 33.2 years (SD 3.40)
C: mean age 32.6 years (SD 3.51)
Radley et al., 2013ScotlandTo evaluate the smoking cessation outcomes and factors associated with success in pregnant women enrolled in an incentivised scheme at community pharmacies Pilot study without a control group, multicentre383
Intervention A1: n = 160
Intervention A2: n = 144
Intervention A3: n = 89		A1: mean age 26.7 (SD 6.10)
A2: mean age 26.9 (SD 6.60)
A3: mean age 27.7 (SD 5.80)
Abbreviations: A1, area 1; A2, area 2; A3, area 3; C, control group; Hb, haemoglobin; I, intervention group; IST, iron supplement tablets; n, number of individuals; SD, standard deviation.
Table
Table 3. Pharmacy and intervention characteristics.
Table 3. Pharmacy and intervention characteristics.
ReferencePharmacy CharacteristicsIntervention Intervention Duration
Heryadi, Sauriasari and Andrajati, 2017Pharmacy care provided within a community health centre in the Pagedangan Sub-district, Tangerang DistrictI: single session of pharmacist counselling on anaemia and ISTs with a media leaflet
C: no counselling		30 days
Kusumawardani et al., 2019Pharmacy care provided within the Jetis Community Health Center of YogyakartaI: single session of pharmacist counselling using the 5A model on the importance of using ferrous fumarate for anaemia treatment and prevention
C: received medication information according to the practiced procedure at Jetis Community Health Center		30 days
Meijer et al., 2005Community pharmacies in a Dutch town, randomised into groups
I: 4 pharmacies
C: 3 reference pharmacies		I: sticker and leaflet containing information on folic acid supplied with oral contraception
C: no intervention provided		6 months
Radley et al., 2013Community pharmacies within three intervention areas (A1, A2, A3) across Tayside Initial meeting with pharmacist to set a quit date and provide NRT, 12 weekly visits to pharmacies for support, education and CO breath tests, financial rewards provided after every negative test, opportunity to continue to 12 weeks postpartum
Comparisons made between intervention areas and national data on smoking cessation		6 months
Abbreviations: A1, area 1; A2, area 2; A3, area 3; C, control group; CO, carbon monoxide; I, intervention group; IST, iron supplement tablets; n, number of individuals; NRT, nicotine replacement therapy.
Table
Table 4. Study outcomes.
Table 4. Study outcomes.
ReferenceStudy Outcome MeauresStudy Outcomes
Heryadi, Sauriasari and Andrajati, 2017Hb level measured with Hbocue 301 Analyzer Hb
Adherence to ISTs, calcium
consumption patterns, food/beverage
consumption patterns measured with questionnaire		Within-group analysis:
I—Hb level increased from 10.39 ± 1.24 g/dL to 11.52 ± 0.92 g/dL, p < 0.001
C—no changes in Hb level, p = 0.3Between-group analysis:
I—Hb increased compared to C (OR = 8.6, p < 0.05) after controlling for confounders
Kusumawardani et al., 2019Knowledge, perceptions, and adherence to ferrous fumarate assessed with questionnairesNo difference in pre-test level of knowledge, perceptions, or
aderence between groups
Post-test knowledge:
I—0 (0.0%) low, 1 (7.7%) medium, 12 (92.3%) high
C—2 (15.4%) low, 11 (84.6%) medium, 0 (0.0%) high
p < 0.001
Post-test perceptions:
I—0 (0.0%) negative, 13 (100.0%) positive
C—12 (92.3%) negative, 1 (7.7%) positive
p < 0.001
Post-test adherence:
I—0 (0.0%) non-compliant, 2 (15.4%) less compliant, 11 (84.6%) compliant
C—5 (38.5%) non-compliant, 7 (53.8%) less compliant, 1 (7.7%) compliant
p < 0.001
RR values of the 3 parameters (4.55, 4.54, 10.29, respectively, with p < 0.05)
Meijer et al., 2005Knowledge of folic acid, identification of information sources, planned recommendation of folic acid supplements to otherwomen, current or planned use of folic acid supplementation assessed with questionnaireNulligravida women:
I—15 (62.5%) currently using and 5 (20.8%) intend to use folic acid supplements
C—4 (30.8%) currently using and 1 (7.7%) intend to use folic acid supplements
p = 0.02
Women with a previous pregnancy:
No change in current or intended use of folic acid supplements
p = 0.42.
I—9 (45.0%) knew the correct time period to take folic acid
C—1 (6.7%) knew the correct time period to take folic acid
p = 0.01
Radley et al., 2013Short and long term quit rates measured with CO breath testsEngagement with programme measured with attendanceQuit rates were 54% at 4 weeks, 32% at 12 weeks and 17%
at 3 months post partum
7.8% of women in the intervention areas compared to 3.9% of all pregnant smokers in Scotland quit at 4 weeks
By intervention areas:
A1—76 (47.5%) quit rate at 4 weeks
A2—86 (59.7%) quit rate at 4 weeks
p = 0.0330
A2—31 (21.5%) quit rate at 3 months postpartum
A3—9 (10.1%) quit rate at 3 months postpartum
p = 0.0248
Abbreviations: A1, area 1; A2, area 2; A3, area 3; CO, carbon monoxide; CI, confidence interval; C, control group; Hb, haemoglobin; I, intervention group; IST, iron supplement tablets; OR, odds ratio; RR, relative risk. Statistical significance if p < 0.05.
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Scott, P.A.; Quotah, O.F.; Dalrymple, K.V.; White, S.L.; Poston, L.; Farebrother, J.; Lakhani, S.; Alter, M.; Blair, M.; Weinman, J.; et al. Community Pharmacist-Led Interventions to Improve Preconception and Pregnancy Health: A Systematic Review. Pharmacy 2021, 9, 171. https://doi.org/10.3390/pharmacy9040171

AMA Style

Scott PA, Quotah OF, Dalrymple KV, White SL, Poston L, Farebrother J, Lakhani S, Alter M, Blair M, Weinman J, et al. Community Pharmacist-Led Interventions to Improve Preconception and Pregnancy Health: A Systematic Review. Pharmacy. 2021; 9(4):171. https://doi.org/10.3390/pharmacy9040171

Chicago/Turabian Style

Scott, Polly A., Ola F. Quotah, Kathryn V. Dalrymple, Sara L. White, Lucilla Poston, Jessica Farebrother, Shivali Lakhani, Marsha Alter, Mitch Blair, John Weinman, and et al. 2021. "Community Pharmacist-Led Interventions to Improve Preconception and Pregnancy Health: A Systematic Review" Pharmacy 9, no. 4: 171. https://doi.org/10.3390/pharmacy9040171

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