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1. Introduction
Premenstrual syndrome (PMS) refers to unpleasant changes in psychological, physical, and behavioral health that occur in the last week of the menstrual cycle and resolves at the beginning of the new menstrual cycle [1]. This syndrome can be quantified by the sum of psychological symptoms (anxiety/tension, depression, confusion, anger/irritability, mood swings, vigor, fear of rejection, lethargy, and sleep disorders), as well as physical symptoms (tenderness of the breasts, bloating, appetite changes, weight gain, headache, aches, abdominal pain, swelling, fatigue, gastrointestinal symptoms, and skin problems) [2]. Although the complete etiology of PMS is unclear, it can be partly attributed to hormonal changes during the menstrual cycle and the subsequent effect on neurotransmitters such as gamma-aminobutyric acid (GABA) and serotonin [2, 3].
PMS affects 20% to 40% of women of childbearing age all over the world [2, 3]. Because PMS can disrupt both the professional and personal lives of women [4], safe and effective treatments are urgently needed. Some medications such as psychotropic medications (e.g., selective serotonin reuptake inhibitors), hormone treatments (estradiol and progesterone), or nonsteroidal anti-inflammatory drugs (NSAIDs) have been prescribed for treatment of PMS [3]. Due to the side effects and lack of therapeutic response in some patients, women have turned to other therapeutic approaches [5]. Complementary and alternative medicine (CAM) is widely used as a safe, lower cost, alternative solution for coping with common health concerns such as PMS [6, 7].
Aromatherapy is a component of CAM which involves the inhalation of plant extracts as essential oils [8]. Essential or volatile oils are said to stimulate olfactory receptor cells and consequently send messages to the limbic system, the emotional center of the brain [9]. Previous meta-analyses have documented the beneficial effects of aromatherapy for dysmenorrhea [10], depressive symptoms [11], and sleep improvement [12].
One previous review evaluated the effectiveness of aromatherapy in conjunction with Iranian herbal medicines on PMS and primary dysmenorrhea [13]. However, this review focused on Iranian countries and omitted many trials conducted elsewhere in the world. Furthermore, the review focused on primary dysmenorrhea rather than PMS and did not conduct quantitative meta-analysis on PMS specifically. The existing scientific literature includes multiple randomized clinical trials evaluating the effects of aromatherapy on PMS. Some of them identified beneficial effects of aromatherapy on PMS symptoms [14–16]. To our knowledge, there is no meta-analysis evaluating the entirety of the clinical literature on the effects of aromatherapy on PMS symptoms. The purpose of this study is to quantify and summarize the findings of RCTs regarding the effects of aromatherapy on premenstrual syndrome.
2. Method
2.1. Search Strategy
This study was designed according to Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) [17].
Databases such as PubMed/Medline, Cochrane Library, and Scopus were searched to recognize relevant published articles until October 2020. The advanced search was performed using a prepared syntax based on Medical Subject Headings (MeSH) and related keywords including (“Aroma” OR “Aromatherapy” OR “Aromatic therapy” OR “Essential oil” OR “Fragrance” OR “Fragrant oil” OR “Scent”) AND (“Premenstrual Syndrome” OR “Premenstrual Tension” OR “Premenstrual Dysphoria” OR “Premenstrual Dysphoric Disorder”). To identify all possible studies, the search was conducted without the use of filters. In addition, the reference lists from eligible papers and pertaining review articles were manually inspected to ensure no other articles were missed.
2.2. Eligibility Criteria
Based on the predefined eligibility criteria, two independent investigators (SE and MQ) reviewed the title and abstract of every article for possible inclusion in this study. The inclusion criteria were (1) randomized clinical trials (RCTs) with either parallel or crossover design; (2) studies conducted on females with premenstrual syndrome; (3) studies assessing the effect of aromatherapy on premenstrual symptoms; and (4) studies reporting mean and standard deviation (SD) of symptoms of PMS. Studies which used other methods in addition to aromatherapy were omitted unless the control group also received the additional treatment. This was done to ensure that the aromatherapy treatment was the only difference between the groups.
2.3. Data Extraction
Data extraction was conducted by two separate authors who thoroughly searched each eligible article to extract the following data: author’s name, publication year, country, essential oil selection, control group intervention, duration of intervention, duration of the treatment session, the total number of sessions, participants mean age or age range, sample size, study design, outcome assessment tool, and PMS symptom values (mean and standard deviation) before and after the intervention.
2.4. Risk of Bias Assessment
The risk of bias for each study was assessed by two independent examiners using the Cochrane Collaboration tool [18]. This scale evaluates six items: random sequence generation, allocation concealment, blinding (patients, personnel, and outcome assessors), incomplete outcome data, selective reporting, and other sources of bias. Studies were ranked as low risk, ambiguous risk, or high risk of bias based on each item.
2.5. Statistical Method
Data were reported as weighted mean differences (WMDs) with 95% confidence intervals (CIs). The random effects model was used to assess the weighted mean difference between values of PMS symptoms. For studies which did not provide mean change with standard deviations, we calculated these data using the following formula: mean change = final values − baseline values; SD = square root ((SD baseline)2 + (SD final)2 – (2R × SD baseline × SD final)) [19]. A correlation coefficient equal to 0.9 was used for the R value in the abovementioned formula [19, 20]. To convert standard deviations (SDs) to standard errors (SEs), we used the following formula: SD = SEM × sqrt (n), where n is the number of participants.
Heterogeneity was evaluated using the I2 index, and I2 values >50% were considered to be evidence of heterogeneity. Subgroup analyses were conducted based on predefined factors, including sample size, duration of intervention, outcome assessment tool, and study design. Sensitivity analyses were performed to examine the influence of each study on the overall effect size. Potential publication bias was identified by Egger’s test and a visual inspection of funnel plots. In the presence of publication bias, Duval and Tweedie’s trim and fill method was used to control the analysis for its effects [21]. All statistical analyses were conducted via STATA (Version 12.0, Stata Corp, College Station, TX). Statistical significance was defined as a
3. Result
A total of 253 articles were identified via online databases, and no additional articles were found through the additional manual search. A total of 234 articles remained after the elimination of duplicates. The abstracts of these 234 papers were screened, and the full text of 22 studies was evaluated. Of those 22 studies, 14 articles were omitted for the following reasons: 12 studies reported irrelevant outcomes, and 2 studies were review articles. This left a total of 8 studies in this analysis. The flow diagram of the study selection process is shown in Figure 1. Table 1 presents details of eligible studies. These studies represented a total of 295 participants and were published between 2016 and 2020. Six of the studies had parallel design, and the other 2 studies had a crossover design. Studies were conducted in Iran [15, 16, 22, 23], Japan [24, 25], India [26], and Turkey [14]. All of the studies were published in the English language.
[figure omitted; refer to PDF]
Table 1
Characteristics of randomized trials on the effects of aromatherapy on the premenstrual syndrome symptoms included in the meta-analysis.
| Reference | Location | Publication year | Subjects and gender | Age, y1 | Design | Intervention type | Duration (mo) | Outcome assessment tool | Outcomes | Findings | Notes about subjects | |
| Intervention | Control | |||||||||||
| (1) Heydari et al. | Iran | 2016 | A : 33 | A : 22.48 ± 1.76 | Parallel | Citrus aurantium blossom essential oil (0.5%) (eye pad) | Odorless sweet almond oil | 2 (twice a day for 5 minutes for 5 days) | PSST | (i) Score of psychological symptoms | Total score of PMS and psychological symptoms decreased significantly after aromatherapy compared to the control group; however, aromatherapy had not significant effects on physical and social symptoms | 66 students with moderate PMS |
| (2) Heydari et al | Iran | 2016 | A : 33 | A:22.66 ± 3.41 | Parallel | Essential oils of Rosa damascena (4%) (eye pad) | Aromatherapy with 100% sweet almond oil | 2 (twice a day for 5 minutes for 5 days) | PSST | (i) Score of psychological symptoms | Total score of PMS, psychological, physical, and social symptoms decreased significantly after aromatherapy compared to the control group | 64 students with moderate PMS |
| (3) Heydari et al | Iran | 2016 | A : 33 | A:22.33 ± 2.38 | — | Citrus aurantium blossom essential oil (0.5%) (eye pad) | Sweet almond oil | 2 (twice a day for 5 minutes for 5 days) | PSST | (i) Anxiety/tension | Psychological symptoms were significant between the three groups except for the variables of anxiety, interest in work activities, and social activities and insomnia; the aromatherapy with Citrus aurantium compared to placebo significantly reduced the score of symptoms such as tearful/increased sensitivity to rejection, feeling overwhelmed, or out of control; aromatherapy with Rosa damascena compared to placebo significantly reduced the anger/irritability, tearful/increased sensitivity to rejection, depression, hopelessness, difficulty in the concentration, and hypersomnia | 66 students with moderate PMS |
| (4) Lotfipur-Rafsanjani et al. | Iran | 2018 | A : 37 | 18–29 yrs | Parallel | Geranium 2% in almond oil + massage (30 min/week) | Sweet almond oil + massage (30 min/week) | 2 (30 min/week) | PMS score | (i) Psychological symptoms | Aromatherapy massage decreased the PMS physical and mental symptoms significantly compared to the massage therapy | 75 students with PMS |
| (5) Matsumoto et al. | Japan | 2016 | A : 9 | 20.6 ± 0.2 | Crossover | Fragrance from yuzu, a Japanese citrus fruit (Citrus junos Sieb. ex Tanaka) (diffuser) | Lavender | 1 (35 min) | POMS | (i) Tension and anxiety | Tension-anxiety, anger-hostility, and fatigue improved in the aromatherapy group compared to the control group; however, other symptoms did not change significantly | 17 women with moderate PMS |
| (6) Matsumoto et al. | Japan | 2016 | A : 9 | 21.7 ± 0.8 | Crossover | Lavender (diffuser) | Water | 1 (35 min) | POMS | (i) Tension and anxiety | Depression-dejection and confusion declined significantly in the aromatherapy group; however, other symptoms did not change significantly | 17 women with moderate PMS |
| (7) Uzuncakmak et al. | Turkey | 2018 | A : 40 | — | Crossover | Lavender (steam inhalation) | — | 3 (5 sessions on average for each cycle) | ACOG | (i) Anxiety | Aromatherapy improved the PMS scale and subdimensions of anxiety, depressive affect, nervousness, pain, bloating, and depressive thought mean scores compared to the control group | 87 students with PMS |
| (8) Geethanjali et al | India | 2020 | A : 30 | 18–35 | Parallel | Clary sage (Salvia sclerae) (diffuser) | Water | 1 (20 min) | PSST | (i) High-frequency power | Aromatherapy increased high-frequency power significantly compared to the control group | 60 women with PMS |
1Values of overall ranges and mean ± SDs in each group. A, aromatherapy; ACOG, American College of Obstetricians and Gynecologists; C, control; CI, confidence interval; PMS, premenstrual syndrome; POMS, Profile of Mood State; PSST, premenstrual symptoms screening tool; WMD, weighted mean difference.
Study participants were women who had moderate to severe PMS. Four of the studies measured PMS symptoms with PSST questionnaires [15, 22, 23, 26], two used PMOS [24, 25], one used ACOG [14], and one used the PMS score [16] questionnaire. One of the studies used aromatherapy with massage while the other seven studies used aromatherapy as the exclusive intervention [16]. Aromatherapy treatment time varied from 5 to 35 minutes, and total sessions ranged from 1 to 5. All of the studies used single oil as the intervention. Lavender was used in two studies [14, 25], as was Citrus aurantium blossom [15, 23] and rose (n = 2) [22, 23]. Yuzu, a Japanese citrus fruit (Citrus junos Sieb. ex Tanaka) [24], geranium [16], and clary sage [26] were each used in one study. Three studies used a diffuser to administer the aromatherapy treatment [24–26], three studies used eye pad [15, 22, 23], one study used steam inhalation [14], and one study used massage [16] as the method of administration.
3.1. Assessment of the Risk of Bias
Five studies were categorized as high quality, and the remaining articles were classified as fair, based on six domains of the Cochrane Collaboration tool. Only three studies described the exact method used for randomization, and only two studies reported blinding. The details of quality assessment for articles included in the present systematic review are illustrated in Table 2.
Table 2
Cochrane risk of bias assessment for randomized controlled trials on the effect of sesame consumption on diabetic indices in adults.
| Reference | Random sequence generation | Allocation concealment | Blinding of participants, personnel, and outcome assessors | Incomplete outcome data | Selective outcome reporting | Other sources of bias |
| Heydari et al. | L | U | L | L | L | L |
| Heydari al. | L | L | L | L | L | L |
| Heydari et al. | L | U | U | L | L | L |
| Lotfipur-Rafsanjani et al. | L | U | H | L | L | L |
| Matsumoto et al. | L | U | U | L | L | L |
| Matsumoto et al. | L | U | U | L | L | L |
| Uzuncakmak et al. | L | L | H | L | L | L |
| Geethanjali et al. | L | L | H | U | L | L |
H, high risk of bias; L, low risk of bias; U, unclear risk of bias.
3.2. Meta-Analysis
3.2.1. The Effect of Aromatherapy on Psychological Symptoms of PMS
Seven of the studies examined the impact of aromatherapy on psychological symptoms of PMS [14–16, 22–25]. This meta-analysis found that aromatherapy treatment decreases psychological symptoms of PMS (WMD–3.51; 95% CI (−4.84, −2.18), I2 = 82.6%), anxiety of PMS (WMD–1.78; 95% CI (−3.17, −0.38), I2 = 94.2%), and depression of PMS (WMD–2.0; 95% CI (−3.65, −0.34), I2 = 93.7%) in the intervention group compared to the control group. However, aromatherapy did not produce a significant effect on confusion as a symptom of PMS (WMD–0.65; 95% CI (−1.33, 0.02), I2 = 66.5%) (Figure 2).
[figure omitted; refer to PDF]3.2.2. The Effect of Aromatherapy on Physical Symptoms of PMS
All eight studies investigated the impact of aromatherapy treatment on physical symptoms of PMS [14–16, 22–26]. This meta-analysis found that aromatherapy treatment significantly reduces physical symptoms of PMS (WMD–1.28; 95% CI (−2.75, 0.19), I2 = 94.6%) as well as fatigue from PMS (WMD–1.44; 95% CI (−2.44, −0.44), I2 = 89.7%) based on the random effects model (Figure 3).
[figure omitted; refer to PDF]3.2.3. The Effect of Aromatherapy on the Overall Score of PMS
Three of the studies examined the impact of aromatherapy on the overall score of PMS [14, 15, 22]. This meta-analysis found that aromatherapy also decreased the severity of PMS in the intervention group compared to the control group (WMD–13.83; 95% CI (−22.04, −5.63), I2 = 94.5%) (Figure 4).
[figure omitted; refer to PDF]3.2.4. Subgroup Analyses
Subgroup analyses were conducted based on predefined factors such as symptom, sample size, duration of treatment, study design, and outcome assessment tool. The duration of treatment and outcome assessment tools were identified as the sources of heterogeneity regarding the psychological symptoms of PMS. However, none of these factors were found to be sources of heterogeneity regarding the physical symptoms of PMS. Furthermore, aromatherapy had a more favorable effect on psychological symptoms of PMS and physical symptoms of PMS in studies with a crossover design, studies which used the ACOG questionnaire for PMS measurement, studies with higher duration, and studies with smaller sample sizes (
Table 3
Pooled estimates of the effects of aromatherapy on premenstrual syndrome symptoms within different subgroups.
| Number of trials | WMD (95% CI) | I2 (%) | ||||||||
| Psychological symptoms | Physical symptoms | Psychological symptoms | Physical symptoms | Psychological symptoms | Physical symptoms | Psychological symptoms | Physical symptoms | Psychological symptoms | Physical symptoms | |
| Total | 17 | 8 | −1.79 (−2.54, −1.04) | −1.27 (−1.96, −0.58) | <0.001 | <0.001 | <0.001 | <0.001 | 96.2 | 92.9 |
| PMS symptoms | ||||||||||
| Score of psychological symptoms | 3 | — | −3.73 (−4.22, −3.25) | — | <0.001 | — | 0.003 | — | 82.6 | — |
| Anxiety | 5 | — | −0.51 (−0.77, −0.26) | — | <0.001 | — | <0.001 | — | 94.2 | — |
| Depression | 5 | — | −0.58 (−0.88, −0.28) | — | <0.001 | — | <0.001 | —- | 93.7 | — |
| Confusion | 4 | - | −0.50 (−0.78, −0.21) | — | 0.001 | — | 0.03 | — | 66.5 | — |
| Score of physical symptoms | — | 3 | — | −0.90 (−1.12, −0.69) | — | <0.001 | — | <0.001 | — | 96.4 |
| Fatigue | — | 5 | — | −0.82 (−1.08, −0.56) | — | <0.001 | — | <0.001 | — | 89.7 |
| Study design | ||||||||||
| Parallel | 9 | 6 | −0.73 (−0.88, −0.57) | −0.84 (−1.01, −0.67) | <0.001 | <0.001 | <0.001 | <0.001 | 95.6 | 94.3 |
| Crossover | 8 | 2 | −3.59 (−4.33, −2.84) | −1.62 (−2.45, −0.79) | <0.001 | <0.001 | <0.001 | 0.094 | 89.9 | 64.4 |
| Outcome assessment tool | ||||||||||
| PSST | 8 | 4 | −0.49 (−0.65, −0.32) | −0.95 (−1.18, −0.71) | <0.001 | <0.001 | <0.001 | <0.001 | 87.3 | 94.7 |
| POMS | 6 | 2 | −1.45 (−2.38, −0.52) | −1.62 (−2.45, −0.79) | <0.001 | 0.005 | 0.025 | 0.094 | 61.2 | 64.4 |
| ACOG | 2 | 1 | −7.32 (−8.55, −6.09) | −4.40 (−5.74, −3.05) | <0.001 | <0.001 | 0.28 | — | 14.2 | — |
| PMS score | 1 | 1 | −4.04 (−4.63, −3.44) | −0.60 (−0.84, −0.35) | <0.001 | <0.001 | — | — | — | — |
| Duration of treatment | ||||||||||
| <2 mo | 6 | 2 | −1.45 (−2.38, −0.52) | −1.62 (−2.45, −0.79) | 0.002 | 0.005 | 0.025 | 0.094 | 61.2 | 64.4 |
| =2 mo | 9 | 5 | −0.73 (−0.88, −0.57) | −0.78 (−0.95, −0.61) | <0.001 | <0.001 | <0.001 | <0.001 | 95.6 | 93.4 |
| >2 mo | 2 | 1 | −7.32 (−8.55, −6.09) | −4.40 (−5.74, −3.05) | <0.001 | <0.001 | 0.28 | — | 14.2 | — |
| Sample size | ||||||||||
| <20 | 6 | 2 | −1.45 (−2.38, −0.52) | −1.62 (−2.45, −0.79) | 0.002 | <0.001 | 0.025 | 0.098 | 61.2 | 64.4 |
| ≥20 | 11 | 6 | −0.83 (−0.99, −0.68) | −0.84 (−1.01, −0.67) | <0.001 | <0.001 | <0.001 | <0.001 | 96.6 | 95.3 |
ACOG, American College of Obstetricians and Gynecologists; CI, confidence interval; PMS, premenstrual syndrome; POMS, Profile of Mood State; PSST, premenstrual symptoms screening tool; WMD, weighted mean difference.
3.2.5. Sensitivity Analyses
By omitting each study and reanalyzing the data, we found that none of the studies affect the significance of the summary effect size of aromatherapy on psychological symptoms of PMS (Supplementary Figure 1), physical symptoms of PMS (Supplementary Figure 2), or the overall score of PMS (Supplementary Figure 3).
3.3. Publication Bias
The funnel plot and Egger test (
4. Discussion
This meta-analysis investigated the effect of aromatherapy on premenstrual syndrome symptoms in women. This study provides evidence that inhaling essential oils can alleviate the symptoms of PMS whether measured as psychological symptoms, physical symptoms, or total PMS symptom scores.
Psychological symptoms of PMS may occur following the decrease in quantity or function of serotonin, tryptophan, and estrogen level [27, 28]. A prospective, randomized controlled trial conducted on elderly persons with symptoms of depression showed an increase in 5-hydroxytryptamine (serotonin) concentrations in the aromatherapy group (lavender + sweet orange (Citrus sinensis) + bergamot (Citrus bergamia)) compared to the control group [29]. In a study conducted by Choi et al, daily inhalation of Citrus aurantium essential oil at concentrations of 0.5% for 5 days by postmenopausal women could increase the estrogen level slightly [30].
The present study found that aromatherapy could decrease the severity of psychological symptoms of PMS such as anxiety and depression, as well as fatigue as a physical symptom of PMS and the total score of PMS. Systematic review sand meta-analyses have found that aromatherapy can decrease depressive symptoms [11] and preoperative anxiety [31] in other demographic groups, which is consistent with our findings. In addition, one study found a favorable effect of aromatherapy with essential oils containing 0.5% neroli oil on ICU (intensive care unit) patients [30]. One clinical trial study showed that lavender aromatherapy could significantly decrease the mean scores of fatigue and anxiety of patients undergoing hemodialysis treatment [32]. However, one study with one session of aromatherapy with 5 min exposure did not find a significant effect on depressive symptoms on pregnant woman [33]. The insignificant result may be due to short intervention exposure time in the treatment groups.
4.1. Oil Selection
One important factor to consider when assessing the effectiveness of aromatherapy is that essential oils are plant extracts. Therefore, each batch differs with regard to the chemical volatile compounds contained within the oils used in these studies. The volatile compound of essential oils contains flavonoid and trepan chemicals such as limonene, gamma-terpinene, linalool, and linalyl acetate that have shown to act as anxiolytic antidepressants and contain sedative properties [34, 35]. Limonene, the main odorant of citrus fruits, plays a role in the stimulation of the sympathetic system and subjective alertness [36]. Linalool as a key volatile component of lavender has sedative properties through harnessing glutamate binding [37]. Gamma-Terpinene, another volatile compound found in yuzu, decreases stress by enhancing the dopamine release [38]. Another volatile component (β-caryophyllene) has been found to improve psychological symptoms such as depression and anxiety [39]. A major phytoncide, α-pinene, also has alleviating effects on autonomic stress response to novel environments [40]. Lehrner et al. showed after inhalation of fragrance from orange (Citrus sinensis), made up of limonene (88.1%), myrcene (3.77%), and α-pinene (1.19%), female patients had lower anxiety, higher peace, and a more positive mood in a waiting room of dental office [41].
One reason for the variation in previous clinical studies on aromatherapy might be the variation in distance between the aroma and the nostrils, which affects the overall dose of inhalation. Most studies in our analysis used a diffuser or eye pads, both of which are effective methods for producing favorable effects [42].
One explanation for aromatherapy’s effects on PMS is the way in which these volatile compounds affect the limbic system. The volatile odorant molecules are inhaled through the roof of the nose where cilia enable them to reach the receptor cells in the nose. When these volatile odorant molecules reach these cells, the olfactory bulb and olfactory tract transmit an electrochemical impulse to the primary olfactory areas in the brain that are contained in the hypothalamus, hippocampus, and the limbic system. These systems are responsible for controlling autonomic homeostasis, managing conscious thought processes, and creating emotional feelings, respectively [37].
4.2. Limitations
The small number of studies that examined symptoms of PMS is a primary limitation of this study. Publication bias in the studies that examined the impact of aromatherapy on PMS scores produces another limitation although publication bias should be interpreted with caution given the small sample size. Furthermore, the heterogeneity among studies is high. The high amount of heterogeneity among studies may be due to the differences in duration of the treatment session, the total number of sessions, frequency of the treatment, forms of essential oils, different volatile compounds, and outcome assessment tool. In addition, three out of the 8 studies included in the systematic review were only found to be of fair quality.
5. Conclusion
The meta-analysis provides evidence that aromatherapy reduces overall symptom scores and both physical and psychological symptoms of PMS. To reproduce these results, a pretest is recommended before using aromatherapy, ensuring that participants have healthy olfactory function and do not experience negative responses to the oils selected. In addition, an increase in inhalation time and a higher number of sessions should be considered for future aromatherapy treatments.
Authors’ Contributions
Malihe Tabarrai and Somayeh Es-haghee conceptualized and designed the study. Somayeh Es-haghee, Fatemeh Shabani, and Marzieh Qaraaty drafted the manuscript and collected the data. Mohammad Ali Zareian analyzed the data. Malihe Tabarrai, Fatemeh Shabani, and Somayeh Es-haghee reviewed the protocol for important intellectual contents. Jessie Hawkins, as a native, did English language editing. All authors read and approved the final manuscript.
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Abstract
ObjectivesPremenstrual syndrome (PMS) is a common disturbance among women of childbearing age. Aromatherapy is a commonly used form of complementary and alternative medicine (CAM) to treat PMS. The purpose of this study is to quantify and summarize the effects of aromatherapy on premenstrual syndrome symptoms. Methods. PubMed, Scopus, and Cochrane Library databases were searched through relevant search terms until October 2020. The effect sizes were pooled as weighted mean difference (WMD) and 95% confidence interval (CI) using the random effect model. Egger tests and visual inspection of the funnel plot were performed to identify the existence of publication bias. The I-squared (I2) test was applied to measure heterogeneity. Results. Eight studies (n = 8) were included in this analysis. The quantitative synthesis of evidence found that aromatherapy decreases PMS scores (WMD –13.83; 95% CI (−22.04, −5.63), I2 = 94.5%), total psychological symptoms of PMS (WMD –3.51; 95% CI (−4.84, −2.18), I2 = 82.6%), anxiety of PMS (WMD–1.78; 95% CI (−3.17, −0.38), I2 = 94.2%), depression of PMS (WMD–2.0; 95% CI (−3.65, −0.34), I2 = 93.7%), and fatigue of PMS (WMD – 1.44; 95% CI (−2.44, −0.44), I2 = 89.7%) compared to the control group. Conclusion. Aromatherapy is an effective tool for the relief of PMS symptoms. Additional randomized controlled clinical trials with different durations and essential oils should be conducted to confirm our findings.
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Details
; Shabani, Fatemeh 2
; Hawkins, Jessie 3
; Mohammad Ali Zareian 4
; Nejatbakhsh, Fatemeh 1
; Qaraaty, Marzieh 4
; Tabarrai, Malihe 1
1 Department of Traditional Medicine, School of Persian Medicine, Tehran University of Medical Sciences (TUMS), Tehran, Iran
2 Department of Midwifery, School of Medicine, Arak University of Medical Sciences, Arak, Iran
3 Integrative Health, Franklin School of Integrative Health Sciences, Franklin, TN, USA
4 Research Development Unit (CRDU), Sayad Shirazi Hospital Golestan University of Medical Sciences, Gorgan, Iran