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. 2021 Dec 31;24(4):196–205. doi: 10.3831/KPI.2021.24.4.196

The Effect of Comfrey on Enoxaparin-Induced Bruise in Patients with Acute Coronary Syndrome: A Randomised Clinical Trial

Zahra Bagheri 1, Azim Azizi 2, Khodayar Oshvandi 1, Younes Mohammadi 3, Amir Larki-Harchegani 4,5,*
PMCID: PMC8716702  PMID: 35028171

Abstract

Objectives

Bruising is an important side effect of enoxaparin injection. Comfrey (Symphytum officinale) is used to treat different types of wounds, bone fractures, and bruising in traditional medicine in many countries for centuries. This study aimed to determine the effects of the Comfrey ointment on the bruise size and color following enoxaparin injection.

Methods

This double-blind randomized clinical trial was conducted on 80 patients with acute coronary syndrome (ACS). The participants were randomly divided into two groups of 40, namely Comfrey and Placebo. Changes in bruise size and color in both groups were assessed daily before and after the intervention.

Results

The Comfrey and Placebo groups were homogeneous in demographic and clinical variables. A downward trend was observed in the bruise size in both groups throughout the study. However, the bruise size was smaller in the Comfrey group than the Placebo group on day 2-5 of the intervention. Moreover, there was a significant difference in bruise color between the groups, with a shorter healing course in the Comfrey group.

Conclusion

The Comfrey ointment accelerated the healing process of enoxaparin injection-induced bruising in patients with ACS. It is recommended as a safe and simple approach for these patients.

Keywords: bruise, enoxaparin, comfrey, acute coronary syndrome, patient, ointment

INTRODUCTION

Acute Coronary Syndrome (ACS) is a general term for the signs and symptoms of myocardial ischemia [1]. Patients with ACS take many drugs, specifically enoxaparin, to control symptoms and complications [2]. Enoxaparin is a low molecular weight anticoagulant administered as a subcutaneous injection [3].

Despite many advantages, enoxaparin has side effects such as pain, anemia, hematoma, thrombocytopenia, and injection site bruising [4, 5]. Bruising is defined as skin color change in a surface area of equal or larger than 2 mm2 [6]. This side effect is the result of bleeding from damaged vessels into the subcutaneous tissue. The bruise maximizes over 48 hours and then slowly starts resolving after 60 to 72 hours. However, complete healing typically occurs between two to three weeks [7, 8].

One of the most important responsibilities of a nurse towards patients is to prevent injury and discomfort and maintain safety [9]. Nevertheless, despite following standard patient care protocols, there are different degrees of discomfort and bruising with injections [10]. Enoxaparin injection-induced bruising occurs in 53.6% of patients with ACS [11]. A bruise can also disrupt physical and psychological comfort, impair mental self-image, and reduce self-confidence [12].

Nurses must reduce the fear and concern of patients regarding nursing interventions and care delivery. As a result, nurses should look for new methods to reduce such issues through professional development and research [13]. A literature review showed that different methods can be used to reduce the bruise size at the injection site, such as using cold and warm compresses [10], changing the needle length and diameter [14], cooling the injection site [15], and changing the injection angle [16] and speed [13]. Almost all of these methods can prevent bruising. According to databases such as Google Scholar and PubMed, there are no studies examining bruise size reduction and bruise healing in patients with ACS.

Comfrey (Symphytum officinale) is a medicinal plant used in traditional medicine to cure bruises. As a member of the Boraginaceae family, Comfrey is native to Europe and tropical regions in Asia. It has anti-inflammatory and pain-relieving effects, stimulates granulation, accelerates fractures, tissue regeneration, wound healing, and bruise, and improves rheumatic disorders, muscular pain, and sport-induced sprain [17-23]. The beneficial effects of this plant on cellular metabolism and cell survival of human skin fibroblasts have been proven [21]. Researchers attributed the medicinal effects of Comfrey to three major compounds, namely phenolic acids (rosmarinic acid, caffeic acid, and salicylic acid), amine (allantoin), glycopeptides, and mucilage polysaccharides [24]. Allantoins stimulate cellular metabolism and growth in subcutaneous tissue as well as bone, tendon, and ligament. On the other hand, rosmarinic acid has antioxidant and anti-inflammatory effects and inhibits the synthesis of prostaglandins [25].

Given the inevitable side effects of drugs such as enoxaparin injection-induced bruises in some patients [10, 13], the anti-bruise and anti-inflammatory effects of Comfrey in traditional medicine [26], and the lack of a comprehensive scientific study into the effect of Comfrey on bruises, this study aimed to determine the effect of Comfrey on the size and color of enoxaparin injection-induced bruises in patients with ACS.

MATERIALS AND METHODS

1. Study design

This randomized clinical trial was conducted on two homogeneous groups in the CCU and Heart Department of Farshchian Heart Hospital of Hamadan from July 2020 to July 2021.

97 participants enrolled in the study. 13 patients were excluded from the study due to non-compliance with the inclusion criteria, and the remaining 84 participants were randomly assigned to the Comfrey or Placebo groups, in a parallel-group scheme (1:1 ratio) using a permuted block randomization with a block size of four. Two participants in each group refused to continue with the study. 40 patients in each group were present until the end of the study (Fig. 1).

Figure 1.

Figure 1

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Flow diagram of the patients in the Comfrey and Placebo groups throughout the different phases of the trial.

2. Participants and study setting

The research sample included eligible patients with ACS who received enoxaparin (1 mg/kg with a maximum dose of 90 mg twice a day). The inclusion criteria were bruising (at least 1 cm2) caused by enoxaparin injection, age group of 30-85 years, no food and drug allergy, no coagulation problem, consciousness, not taking warfarin, heparin, and anti-inflammatory drugs (Glucocorticosteroids and NSAIDs), the injection site on the abdomen, and bruising less than 12 hours old. The exclusion criteria were allergy to employed ointments, early discharge, the occurrence of acute coagulation disorders, repeated injection into the bruising area, enoxaparin withdrawal, and not taking the drug twice a day.

3. Ethics statements

All procedures in this study were done in agreement with the ethical standards of the institutional research committee and with the 1964 Helsinki declaration. The research was approved by the Ethics Committee of Hamadan University of Medical Sciences (IR.UMSHA.REC.1397.471). The study objectives were explained to the patients and all patients signed a written informed consent form to declare their agreement to participate in this study. This trial was registered in the Iranian Registry of Clinical Trials (http://www.irct.ir; IRCT2015062822956N1).

4. Sample size

Following a previously published trial (Jeffrey et al., 2015), the equation for calculating the sample size in randomized clinical trials was used in the present study, where type one error (α) was 0.05, type two errors (β) was 0.10 (power = 0.90), the difference in mean (d) of bruise size was 10 mm, and the standard deviation (SD) was 10.

Assuming the probable loss to follow-up of 20% in each group, a total of 40 participants was considered as the final sample size for each group [27].

5. Randomization and blinding

The eligible participants were assigned to the Comfrey and placebo groups using permuted block randomization technique with a block size of four and an equal allocation ratio. Microsoft Excel 2016 software (Microsoft Corp., Redmond, WA, USA) was used to create random sequences of block sizes. To blind the study, the Comfrey and placebo groups were denoted by letters A and B, respectively. The researcher, patients, and statisticians were blinded to the groups until the end of the data analysis stage.

6. Plant materials

The plant (Symphytum officinale) was purchased from the Avicenna Herb Garden in Hamadan in early summer 2018 and then approved by a botanical specialist in Hamadan University of Medical Sciences. The herbal specimen was deposited in the herbarium (voucher number PMP-1329).

7. Preparation of Comfrey hydro-alcoholic extract

A total of 200 g of the dried plant was first ground and then suspended in ethanol 70% and subjected to continuous ultrasonic vibrations (USV) for three days. The suspension was stirred gently several times during this period. The obtained extract was then filtered using the Whatman® filter paper No. 30 and condensed using a rotary evaporator. The solution was then placed in a 30-40℃ oven to obtain the dry extract [28]. After weighing, the percent of extraction from the plant sample was calculated as 18.5% (w/w).

8. Preparation of Comfrey ointment

The dried smoothed powder of Comfrey hydro-alcoholic extract was mixed with eucerin as the base of ointment to prepare the Comfrey ointment 10% (w/w). A homogenizer was used to achieve a uniform ointment with acceptable appearance characteristics [29].

9. Preparation of placebo ointment

The placebo ointment was also eucerin-based, to which appropriate neutral food dye was added to achieve the same color as the Comfrey ointment and then placed in similar tubes.

The Comfrey and placebo ointments were prepared by a pharmacist in the laboratory of biopharmaceutical products, school of pharmacy, Hamadan University of Medical Sciences, Hamadan, Iran.

10. Data collection instruments

Demographic and clinical information of all participants was recorded and assessed by designing a questionnaire. Moreover, the bruise size and color in both groups were determined before the intervention and the days 1 to 5 of the intervention. To reduce the error rate in reporting the results, all bruise size and color measurements were taken at a fixed time (9 am) during the research period. The bruise size was recorded by placing a transparent paper strip on the bruise and coloring the spot with a fine-tip permanent marker. The measurement was replicated three times. Then, the paper was scanned by a scanner and the accurate bruise size was obtained in mm2 in ImageJ software version 1.52n. The bruise color was determined using a bruising color chart, reflecting four key bruise color changes from the onset to healing, and the dominant color was recorded. To investigate the reliability of the observers, the size and color of the bruise complication in ten patients were measured separately by the main researcher (the assessor) and three trained nurses at the same time, and the intraclass correlation coefficient (ICC) of 0.93 and 0.90 were obtained, respectively, indicating very good reliability [17]. After the initial evaluation of the bruise size and color, the participants in Group A received Comfrey ointment on the enoxaparin injection-induced bruising site. The ointment was administered four times per day with 6-hour intervals for five consecutive days. The participants in Group B underwent the same procedure, except that they received the Placebo ointment instead of Comfrey ointment. The amount of ointment used varied from patient to patient, depending on the size of the bruised area. Approximately 0.3 g of ointment was applied per cm2 of the bruised area to create a proper coverage of the ointment.

11. Statistical analysis

Data were analyzed with ANOVA. Then, Tukey’s post hoc test, and paired/unpaired t-test and their nonparametric equations were used if needed. The nonparametric assessment of the bruise color of each patient at different times was done using the Mann-Whitney U test. The statistical analysis was done in SPSS20 at the significance level of p < 0.05. Data were presented in the form of means ± SEM for all 40 patients in each group.

RESULTS

There was no significant difference between the groups in demographic information (sex, marital status, job, education, monthly income, place of residence, health-care insurance, smoking, age, BMI, INR, PT, PTT, and serum platelet counts (Tables 1-3).

Table 1.

Distribution of participants’ qualitative demographic characteristics between the two study groups

Variables Sub groups Comfrey groupN = 40 Placebo groupN = 40 p value
Number Percent Number Percent
Gender Female 16 40 19 47.5 0.435
Male 24 60 21 52.5
Marital status Married 34 85 38 95 0.311
Single 2 5 0 0
Widow 4 10 2 5
Employment status Employee 4 10 7 17.5 0.054
Housewife 10 25 16 40
Retired 10 25 7 17.5
Unemployed 0 0 3 7.5
Freelance job 16 40 7 17.5
Education level Illiterate 20 50 15 37.5 0.611
Middle school 6 15 10 15
Diploma 9 22.5 9 22.5
University education 5 12.5 6 15
Monthly income Under 100 USD 20 50 14 35 0.09
100-500 USD 16 40 16 40
More than 500 USD 4 10 10 25
Living place City 26 65 28 70 0.633
Village 14 35 12 30
Health insurance Insured 38 95 36 90 0.675
Non-insured 2 5 4 10
Smoking status Smoker 23 57.5 16 40 0.174
Non-smoker 17 42.5 24 60
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Table 2.

Distribution of participants’ quantitative demographic variables between the two study groups

Variables Experimental group (N = 40) Placebo group (N = 40) p value
Mean ± SD Maximum Minimum Mean ± SD Maximum Minimum
Age (years) 64.13 ± 8.97 79 43 63.85 ± 10.49 80 41 0.900
Weight (kg) 72.79 ± 9.27 91 58 75.95 ± 9.09 90 53 0.131
Height (cm) 168.93 ± 9.95 189 144 168.53 ± 9.97 188 155 0.858
BMI (kg/m2) 25.58 ± 3.21 32.81 17.08 26.85 ± 3.5 35.70 20.96 0.097
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Table 3.

Distribution of participants’ clinical data between the Comfrey and placebo groups

Variables Experimental group (N = 40) Placebo group (N = 40) Means comparison
Mean ± SD Mean ± SD p value
PT before intervention 13.29 ± 0.82 13.22 ± 0.87 0.722
PT 1 day after intervention 13.83 ± 1.19 13.32 ± 0.76 0.080
PT 3 days after intervention 13.45 ± 0.89 13.30 ± 0.70 0.426
PT 5 days after intervention 13.56 ± 1.02 13.60 ± 0.65 0.936
PTT before intervention 28.28 ± 5.13 31.68 ± 9.14 0.141
PTT 1 day after intervention 31.20 ± 16.05 31.06 ± 6.30 0.543
PTT 3 days after intervention 31.15 ± 9.04 32.82 ± 15.12 0.661
PTT 5 days after intervention 31.13 ± 4.97 34.20 ± 7.66 0.416
INR before intervention 1.09 ± 0.10 1.09 ± 0.13 0.503
INR 1 day after intervention 1.14 ± 0.18 1.10 ± 0.10 0.256
INR 3 days after intervention 1.13 ± 0.13 1.09 ± 0.10 0.480
INR 5 days after intervention 1.14 ± 0.15 1.15 ± 0.10 0.934
Platelet before intervention 199423 ± 46309 201750 ± 40703 0.813
Platelet 1 day after intervention 200684 ± 25177 194632 ± 29984 0.640
Platelet 3 days after intervention 204568 ± 35715 196050 ± 32233 0.342
Platelet 5 days after intervention 180666 ± 39525 194200 ± 21182 0.511
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Fig. 2 shows no significant difference between the groups in the mean bruise size before the intervention (p = 0.494). On the first day after the intervention, the mean bruise size in the Comfrey group was lower than in the Placebo group. However, based on the independent t-test, there was no significant difference between the groups in the mean bruise size (p = 0.274). A significant difference was observed between the groups in the mean bruise size in the second to fifth days of the intervention (Fig. 2) (p > 0.05) with lower mean bruise size in the Comfrey group. Friedman’s test showed a significant difference between the groups in the mean bruise size at the observation times (p < 0.001). According to Fig. 2, there is a downward trend in the bruise size at the observation point in both groups, specifically in the Comfrey group.

Figure 2.

Figure 2

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Comparison of bruising size-reduction trend in Comfrey and Placebo groups. There was no significant difference between the Comfrey group and the placebo group in the mean size of bruising before the intervention (p = 0.494). Data are presented as mean ± SEM.

In Table 4 the non-parametric Friedman’s test was used to investigate the intervention effect on the bruise size and perform intra-group comparisons before and five days after the intervention. There was a significant difference within both groups in terms of bruise color at all six observation points (p < 0.001). The bruise color distribution was similar in both groups before the intervention. Comparison of bruise color in the first-to-fifth-day post-intervention showed a significant difference in the bruise color distribution in all five days of the intervention (p > 0.001). In that, the color of the bruised area indicated a faster healing course in the Comfrey group (Fig. 3).

Table 4.

Comparison of bruise color before and after intervention between the groups

Groups Bruise color T1n (%) T2n (%) T3n (%) T4n (%) T5n (%) T6n (%) Friedman test statistic p value
Intervention group Pink and red 40 (100) 20 (50) 0 0 0 0 184.37 < 0.001
Blue and dark purple 0 20 (50) 37 (92.5) 17 (42.50) 4 (10) 0
Pale green 0 0 3 (7.5) 22 (55) 28 (70) 19 (47.5)
Yellow and brown 0 0 0 1 (2.5) 8 (2) 21 (52.5)
Placebo group Pink and red 40 (100) 40 (100) 34 (85) 19 (47.50) 8 (20) 2 (5) 140.65 < 0.001
Blue and dark purple 0 0 6 (15) 21 (52.5) 32 (80) 34 (85)
Pale green 0 0 0 0 0 4 (10)
Yellow and brown 0 0 0 0 0 0
Statistic - 26.57* 69.91** 51.25** 76.05** 80.78*zz*
p value - < 0.001 < 0.001 < 0.001 < 0.001 < 0.001
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T1, Before intervention; T2, First day after intervention; T3, Second day after intervention; T4, Third intervention day after intervention; T5, Fourth day after intervention; T6, Fifth day after intervention. *Chi-square test, **Fisher exact test.

Figure 3.

Figure 3

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Bruising healing in one patient in the intervention group for the first to fifth days after the intervention (left to right, respectively).

Table 5 shows the probability of bruise color change (Kaplan–Meier) in both groups after the intervention. According to the results, the probability of change in bruise color was 50% after the first day of the intervention, which reached 100% after the second day of intervention in the Comfrey group. This bruise color change was observed in all participants until the second day of intervention in this group. The bruise color change was not observed in any of the placebo control participants one day post-intervention. The probabilities of a change in the bruise color in the second, third, fourth, and fifth days after the intervention were 25%, 52%, 80%, and 95%, respectively.

Table 5.

Bruise color change probability (Kaplan–Meier estimator) after intervention in the Comfrey and placebo groups

Groups Time of event Number of events* Number of risks Number of censored cases Probability of not happening Probability of happening
Comfrey group T1 0 40 0 1 0
T2 20 40 0 0.50 0.50
T3 20 20 0 0 1
>T3 - - - - -
Placebo group T1 0 40 0 1 0
T2 0 40 0 1 0
T3 6 40 0 0.85 0.25
T4 15 34 0 0.48 0.52
T5 11 19 0 0.20 0.80
T6 6 8 2 0.05 0.95
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T1, Before intervention; T2, First day after intervention; T3, Second day after intervention; T4, Third intervention day after intervention; T5, Fourth day after intervention; T6, Fifth day after intervention. *Bruise color change.

DISCUSSION

There was a significant difference between the groups in the mean bruise size at the assessment times. In addition, a downward trend was observed in the bruise size at different time points in both groups. To establish whether there is a difference between the groups in the bruise size reduction, the Comfrey and Placebo groups were compared at different time points and the results showed that the groups were homogeneous in this regard before the intervention. Although the mean bruise size in the Comfrey group was smaller than the Placebo group on the first day after the intervention, this difference between the groups was not significant. However, the difference between the groups in the mean bruise size was significant at 2-5 days with a smaller mean bruise size in the Comfrey group. As a result, the use of Comfrey ointment can reduce the size of enoxaparin injection-induced bruises. This finding confirmed the research hypothesis that Comfrey ointment affects the size of enoxaparin injection-induced bruises.

Inconsistent with this study, Barna et al. [30] showed no significant difference in wound healing of the control group before and after the intervention. Moreover, Chaiet et al. [31] showed no significant difference in the bruise size in the placebo group, which can be due to the short duration of these two studies, specifically with respect to the wound type.

Consistent with the current study, Frost et al. [25], Sowa et al. [21], Miškulin et al. [19], Gilca et al. [32], Alamgir [33], and Jarić et al. [34] highlighted the anti-bruising effects of Comfrey. However, these studies only addressed the properties of Comfrey or its effects on variables other than bruising and neglected its anti-bruising effects.

It seems that the anti-inflammatory effects of Comfrey play a role in its anti-bruising effects seen in the Comfrey group. Anders et al. [35] showed that cutaneous medications containing Comfrey root (5% and 10%) were as effective as or even more effective than diclofenac, in healing ultraviolet-induced erythema. Moreover, these anti-bruising effects can be due to the plant compounds including allantoin, ellagic acid, and rosmarinic acid [21, 25]. Smith et al. [26] and Staiger [36] highlighted the anti-inflammatory and stimulatory effects of Comfrey on granulation, tissue regeneration, and rapid healing.

Change in bruise color took place sooner in the Comfrey group than the control. Results showed that the bruise color change occurred one day after the intervention in the Comfrey group and 2-3 days after the intervention in the control. The difference in the onset of bruise color change between the groups was significant. As a result, the application of Comfrey ointment could facilitate the bruise color change following enoxaparin injection in the Comfrey group.

Bruising at the injection site is the undesirable result of enoxaparin subcutaneous injection, which can cause physical discomfort [27, 37]. According to the results, Comfrey ointment can be used to reduce these impacts. Consistent with our findings, different studies mentioned the effectiveness of Comfrey ointment in the rapid healing of trauma-induced bruises. However, these studies only provided a descriptive explanation of Comfrey properties and did not scientifically investigate the effect of Comfrey on bruising [38].

According to a study in the Medical University of Lublin, Poland, the Comfrey plant root can facilitate the growth and proliferation of skin fibroblasts [26]. This plant has been effective in improving cutaneous inflammation and skin redness caused by overexposure to ultraviolet (UV) rays, which confirms the findings of the current study [24, 39, 40].

CONCLUSIONS

The results showed that comfrey ointment accelerated the healing of enoxaparin injection-induced bruise (size and color) in patients with ACS. Therefore, Comfrey is recommended to be used as a safe, non-aggressive, and simple method to facilitate bruise improvement caused by enoxaparin injection.

ACKNOWLEDGEMENTS

The authors thank the patient for participating in this study and all clinical staff at Farshchian Heart Hospital (Department of Heart and CCU, Hamadan University of Medical Sciences) for their excellent technical assistance. Financial support for this study was provided by Vice-chancellor for Research and Technology, Hamadan University of Medical Sciences (Grant number: 9709275652).

Footnotes

LIMITATIONS

Due to early discharge, the effect of Comfrey on complete improvement of bruise, naturally lasting about two weeks, could not be investigated in this study. Therefore, we are not completely certain to what extent this medicinal plant can shorten the healing period. The results of this study only showed the effect of Comfrey ointment on bruise caused by abdominal injection of enoxaparin in patients with ACS. Moreover, the control group could enhance the validity of this study.

CONFLICT OF INTEREST

The authors declare that they have no financial or non-financial conflict of interest.

ETHICAL APPROVAL

All procedures performed in studies involving human participants were in accordance with the ethical standards of the institutional and/or national research committee and with the 1964 Helsinki declaration and its later amendments or comparable ethical standards. The study has been approved by the Ethical Committee of Hamadan University of Medical Sciences (approval number: IR.UMSHA.REC.1397.471).

RESEARCH REGISTRATION NUMBER

This study was registered in Iranian Registry of Clinical Trials (IRCT) with registration ID: IRCT2015062822956N1.

FUNDING

This research has been financially supported by vice-chancellor for research and technology, Hamadan University of Medical Sciences, Hamadan, Iran (Grant No.9709275652).

AUTHORS’ CONTRIBUTIONS

Dr. Amir Larki-Harchegani and Dr. Azim Azizi accept full responsibility for this performed study and two authors contributed equally.

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