1. Introduction
Hemorrhoids are characterized by enlargement, bleeding, and protrusion of clusters of veins in the anus located under the membrane that lines the lowest part of the rectum and anus. It is estimated that hemorrhoids affect 5% of the general population, with 50% of people over the age of 50 having experienced symptoms of hemorrhoidal disease (HD). Pathologic symptoms of HD include fissures, fistulae, abscesses, or irritation and itching [
1,
2,
3]. Hemorrhoids can be either internal or external. The former occur inside the rectum and are usually not painful because this area lacks sensitive nerve endings. External hemorrhoids occur outside of the anal verge and are usually painful, accompanied by pruritus, itching, swelling, and burning sensations [
1,
2].
Possible HD causes include genetics, constipation or diarrhea, complications from chronic constipation, pregnancy, and obesity. These conditions lead to pressure elevation within the submucosal arteriovenous plexus and eventually result in swelling of the clusters of veins, laxity of the supporting connective tissue, and protrusion into and through the anal canal [
3,
4].
The natural history of most cases of hemorrhoid disease is self-limited. For symptomatic HD that presents to the clinic or emergency room, treatments range from nonoperative medical interventions and office-based procedures to surgery. One general guiding principle is that the least invasive approaches should be considered first, except in cases of acute thrombosis. Specific choices of treatments depend on patients’ ages, severity of symptoms, and comorbidities [
3,
4,
5,
6].
Lifestyle and dietary modification are the mainstays of conservative medical treatment of HD. Specifically, lifestyle modifications should include increasing oral fluid intake, reducing fat consumption, avoiding straining, and regular exercise. Diet recommendations should include increasing fiber intake, which decreases the shearing action of passing hard stool. In a meta-analysis of seven randomized trials comparing fiber to non-fiber controls, fiber supplementation (7–20 g/d) reduced the risk of persisting symptoms and bleeding by 50%. However, fiber intake did not improve symptoms of prolapse, pain, and itching.
For internal hemorrhoids, rubber band ligation, sclerotherapy, and infrared coagulation are the most common procedures but there is no consensus on optimal treatment. Overall, the goals of each procedure are to decrease vascularity, reduce redundant tissue, and increase hemorrhoidal rectal wall fixation to minimize prolapse.
Continued symptoms despite conservative or minimally invasive measures usually require surgical intervention. In addition, surgery is the initial treatment of choice in patients with symptomatic grade-IV hemorrhoids or those who have strangulated internal hemorrhoids. It may also be required for symptomatic grade-III hemorrhoids and in patients who present with thrombosed hemorrhoids.
The vast number of treatment options means that there is no gold standard. There is no single best treatment for hemorrhoids and various options are available depending upon symptoms and grading. Any treatment has to be safe, especially while treating non-life threatening conditions such as hemorrhoids [
3,
4].
Due to various side effects, drug interactions, and the high costs of synthetic drugs, interest in herbal medicines is increasing day by day. Among the population, the variety of plants used against hemorrhoids is quite high. For example, 241 medicinal plants are used to treat hemorrhoids in various regions of Turkey [
5,
6,
7,
8,
9,
10,
11].
Nigella sativa (NS),
Conyza bonariensis (CB), and
Alchemilla vulgaris (
AV) are highly recommended for treating HD in the traditional Greco-Arab herbal medicine. They are reported to improve the symptoms of hemorrhoids such as pain, bleeding, itching, rectal prolapse, number of hemorrhoidal cushions, and recurrence of/increase in the rate of wound healing. Their mechanisms of action include anti-inflammatory, anti-nociceptive, venotonic, and venoprotective activities [
1,
2,
3,
4,
5].
The seeds of NS have been used in different traditional medicines around the world for centuries to treat various human diseases. So far, numerous studies have demonstrated that the seeds of
NS and its main active constituent (thymoquinone, a strong anti-oxidant and anti-inflammatory agent) to be therapeutically effective against various chronic diseases, such as neurological and mental illness, cardiovascular disorders, cancer, diabetes, inflammatory conditions, and infertility as well as various infectious diseases caused by bacterial, fungal, parasitic, and viral infections [
6,
12].
CB was found to exert antioxidant, anti-inflammatory, antinociceptive, and antipyretic effects. In addition, the growth-inhibitory activity of this plant against a series of selected microbial strains has also been reported. This plant is widely used in various traditional medicines in the treatment of rheumatism, gout, cystitis, nephritis, dysmenorrhea, tooth pain, and headache; it was also reported to have antiulcerogenic and anticoagulant activity, as well as antioxidant effects [
6,
12].
Alchemilla plants (lady’s mantle) are used in traditional medicine for different indications, including minimizing the symptoms of sore throat, stopping bleeding, acting against gastrointestinal diseases and inflammatory processes, as well as for promoting wound healing due to its strong antimicrobial and anti-inflammatory effects [
13,
14,
15,
16,
17,
18].
The concept of mixing plants to make a more effective poison or medicine is an ancient and very popular tradition. In our research group, we have conducted in vitro, in vivo, and clinical trials on anti-diabetes, anti-overweight, anti-acne, and anti-hyperlipidemia medicinal plant mixtures [
6,
7,
15,
19,
20,
21]. Based on knowledge from traditional Greco-Arab herbal medicine, and the results obtained in our survey [
6,
14] and other ethnopharmacological potential studies, we selected the most promising three medicinal plants, namely
NS, CB, and
AV, for preparing a topical HPC cream consisting of water–ethanol extracts of these three plants. These plants have been used extensively in traditional Greco-Arab medicine in the treatment of hemorrhoids and other chronic diseases [
5,
6,
7,
8,
9,
10,
11]. The present in vitro animal study and RDBPC aim to determine the safety and efficacy of HPC.
2. Materials and Methods
2.1. Preparation of Plant Extracts
NS,
CB, and
AV were collected from the Galilee region during the spring and summer months. The botanical identities of the collected plant materials were confirmed by Prof. Hasan Azaizeh (Department of Environmental Sciences, Tel-Hai Academic College, Israel). The voucher specimens of
NS,
CB, and
AV were
NS 2014/03/006,
CB 2014/04/008, and
AV 2014/05/012. The water–ethanol extracts of the plant materials were produced as described [
15]. In brief, 100 g of
NS (seeds),
CB (branches and flowering parts), or
AV (leaves) were added to one liter of 50% ethanol in distilled water and boiled for 10 min. The extracts were filtered through filter paper and frozen at −70 °C until use. All the experimental work on plant material described in this study complies with the relevant institutional, national, and international guidelines and legislation.
2.2. Preparation of HPC Cream
The herbal “HPC” cream was prepared from specific quantities of extracts of
NS,
CB,
AV, glycerol, and basic creams, as described in
Table 1. All experimental protocols of this study were approved by the ethics committee of the Rambam Hospital in Haifa, and were carried out in accordance with relevant guidelines and regulations as well as with ARRIVE guidelines.
Pharmaceutical Manufacturing Process
Emulsifiers were melted with sunflower seed oil at a temperature of 70 ± 5 °C. Separately, the aqueous phase (water, HPC, preservatives) was heated to the same temperature of 70 ± 5 °C. Then, the oily phase was added to the aqueous phase. The mixture was emulsified using homogenizer at 5000 rpm for 20–30 min. The resulted homogenous and white colored cream. In addition, the consistency, appearance, and stability of the cream were examined and approved.
2.3. Cell Culture
The fibroblast cell line 3T3 (CRL-1658) and the human monocyte cell line THP-1 (202-TIB) were obtained from the ATCC (American Type Culture Collection, Manassas, VA, USA) and maintained under standard cell culture conditions in high-glucose (4.5 g/L) Dulbecco’s modified Eagle’s medium (DMEM) and Roswell Park Memorial Institute Medium (RPMI 1640), respectively. Both media were supplemented with 10% fetal bovine serum (FBS), 1% nonessential amino acids, 1% glutamine, 100 U/mL penicillin, and 10 µg/mL streptomycin. THP-1 cells were grown at a density of 2 × 105 cells/mL. Their differentiation into macrophages was induced by adding Phorbol-12-Myristate-13 Acetate (PMA, purchased from Sigma-Aldrich, Burlington, MA, USA) (100 ng/mL) and vitamin D3 (0.1 μM) (purchased from Sigma-Aldrich, Burlington, MA, USA) to the culture medium for 24 h. Cells were then treated with various concentrations of the HPC (0, 180, and 360 μg of HPC/mL).
2.4. Cell Viability
Lactate dehydrogenase (LDH) leakage assay was carried out to evaluate non-toxic concentrations of the three medicinal plants. Cell viability of cultured 3T3 cells was evaluated using the CytoTox 96 (cytotoxicity assay kit, Promega, Israel), according to the manufacturer’s instructions. Briefly, 96-well plates were used to culture of 2 × 10
3 cells/well of fibroblast cell line 3T3 for 24 h at 37 °C. Culture media was then replaced by media containing without HPC (control) or with 180, 360 μg HPC/mL for 24 h. DMEM additionally supplemented with 0.01 vol% of a cytotoxic surfactant (Triton X-100, Sigma-Aldrich, USA) was used as a positive control. The concentrations of LDH in cell lysates or centrifuged culture media were evaluated as described [
15].
For the MTT assay: 20,000 cells/100 µL media from the 3T3 cells cell line were seeded in 96-microtiter plates. Twenty-four hours later, cells were treated with culture media was then replaced by media containing without HPC (control) or with 180 or 360 μg HPC/mL for 24 h. The MTT assay was then performed.
2.5. Nitrite Determination
Griess reagent assay was applied to measure the inhibitory effects of NO production on THP-derived macrophages, as described in [
22,
23].
2.6. Antimicrobial Activity with Standardized Disk Diffusion Assay
This standardized technique was carried out as described in [
21]. Briefly,
Escherichia coli (
E. coli) strains (ATCC-25922) were cultured in Reinforced Clostridium Medium (RCM) for 48 h and adjusted to yield approximately 1.0 × 10
6 CFU/mL. A 1.0 × 10
8 CFU inoculum was spread on blood agar (with sheep blood 5 to 7%, obtained from Promega) (BASB) medium plates. Whatman filter discs of 6 mm diameter were placed in autoclaved glass Petri dishes. The bacterial suspension (10
8 CFU/mL) was swabbed on the surface of 5–7% BASB-medium plates. The HPC discs (1, 2 and 5 mg/disc) were then distributed evenly on the surface of the seeded agar plate. The Ampicillin reference antibiotics discs (10 mg/disc) were placed onto the agar plate beside the extract discs. The BASB-plates were incubated upside down in Gaspak jars at 37 °C for 48 h. The inhibition zone around each disc was then measured using a transparent ruler. Three replicate plates were used for each test.
2.7. Vasoconstriction Effect of HPC on Intestinal Vein Rings
The study was conducted in the faculty of medicine, Technion, Haifa, Israel, under the supervision of Dr Omar Said. Blood vessels were harvested from Sprague–Dawley male rats as described [
24,
25]. Intestinal vein rings were obtained and each ring was suspended by a fine steel wire and connected to an isometric tension transducer (Myograph F60). The transducer was connected to a Narco Trace 40 polygraph (Narco-Bio-Systems Inc., Houston, TX, USA). The rings were maintained in 15 mL Krebs–Henseleit solution at 37 °C bubbled with 95% O
2 and 5% CO
2. A tension of 500 mg was maintained during an equilibrium period of 60 min during which the bathing medium was changed every 20 min. The rings were exposed to cumulative concentrations of phenylephrine with the presence and absence of 10 mg/mL of HPC.
2.8. Open-Label, Uncontrolled, Safety/Efficacy Study to Evaluate the Safety and Efficacy of HPC in the Treatment of Hemorrhoids
The protocol of the study was reviewed and approved by the ethics committee of the Rambam Hospital, Israel (ethics approval number/date: 0330-13-RMB/23072013). The study was conducted in accordance with the relevant guidelines and regulations of the ethics committee of the Rambam Hospital, Israel. Dr Iyad Khamaysi (Gastroenterologist, Rambam Hospital, Haifa, Israel) carried out this open-label clinical study in 2014 on 37 patients (17 females and 20 males, ages 19–59) in his clinic in the Galilee region. All the patients were evaluated clinically and endoscopically and were asked to apply HPC twice daily for one week. Five of the 37 patients who also suffered from mild anal fissure were excluded. Significant improvement in the clinical parameters [
26] grade of hemorrhoids (1–4), hemorrhage (0–3), pain (0–10), and itching (0–3) served for evaluation of the HPC efficacy. The hemorrhoid severity degree grade for all the 37 patients was as follows: 10 patients with degree grade 1, 18 with degree grade 2, and 9 with degree grade 3. The trial criteria were the same as described for RDBPC in
Section 2.9.
2.9. RDBPC to Determine the Anti-Hemorrhoidal Efficacy and Safety of HPC
The protocol of the study was reviewed and approved by the ethics committee of the Rambam Hospital, Israel (ethics approval number/date: 0330-13-RMB/23072013). The study was conducted in accordance with the relevant guidelines and regulations of the ethics committee of the Rambam Hospital, Israel. This RDBPC to determine the anti-hemorrhoidal efficacy and safety of HPC was carried out in 2015 by Dr Iyad Khamaysi (Department of Gastroenterology, Rambam Hospital, Haifa, Israel) on 77 hemorrhoids patients with median grade of hemorrhoids of 2.0. The patients were randomly divided into test group (
n = 54, aged 19–61 years, 27 females and 27 males) and placebo group (
n = 23, ages 19–56 years, 11 females and 12 males with a median grade of hemorrhoids 2.0) (
Figure 1). The patients were asked to apply 2–3 mL of HPC twice daily for 6 days. Each patient came for 5 visits and follow-up: at baseline, at days 2, 4, and 6, and at the observation endpoint after one month. Changes in the Hemorrhoids Disease Severity (HDS) (0–3), Hemorrhage Severity (HS) (0–3), pain (0–10), and itching (0–3) measures served for evaluation of the HPC cream efficacy. The baseline hemorrhoid severity degree of the test group
n = 54 was diagnosed as follows: 9 patients with degree 1, 19 with degree 2, 26 with degree 3. While the placebo group
n = 23 was diagnosed as follows: 6 patients with degree 1, 7 with degree 2, 10 with degree 3.
Eligibility: To be eligible for this study, qualified participants needed to be (1) either male or female and aged 18 years and up, (2) diagnosed as suffering from hemorrhoids and willing to give informed consent, and (3) willing to refrain from using any other hemorrhoids medications while participating in the trial.
Inclusion Criteria: (1) Providing a written informed consent and ability to fulfill the requirements of the willingness to participate in the study and agreement to all study procedures. (2) Diagnosed with symptomatic internal hemorrhoids, diagnosed by both clinical and endoscopic assessment (grades I–III). (3) Refraining from the use of any other hemorrhoid medications.
Exclusion Criteria: (1) History of inflammatory bowel disease. (2) History of irritable bowel syndrome with constipation or diarrhea. (3) Previous surgical or instrumental treatment of internal hemorrhoids. (4) Topical anesthetics within 14 days prior to day 1. (5) Any investigational agents within 28 days before day 1. (6) Diagnosis with hemorrhoid Disease Severity degree IV. (7) Use of anal, intra-anal, or intra-rectal steroids within 28 days before day 1.
Primary and secondary endpoints: (1) The predefined primary outcome measures were a reduction in hemorrhoid symptoms, namely hemorrhage, pain, and itching. (2) The predefined secondary outcome measures were the incidence of adverse events and compliance with the treatment.
2.10. Statistical Analysis
Error limits cited and error bars plotted represent simple standard deviations of the mean. Usually, numerical results are given only to an accuracy sufficient to specify the least significant digit. When comparing different samples, results were considered to be statistically different when p < 0.05 (Student’s t test for unpaired samples).
3. Results and Discussion
There is a plethora of medicinal plants and their therapeutic uses are mentioned in traditional Greco-Arab herbal medicine scripts written by famous medieval scholars such as Avicenna, Rhazes, and Ibn al-Bitar [
6]. Many of these medicinal herbs are currently used in the treatment and prevention of all types of human diseases within the Mediterranean regions [
27]. For example, 241 herbs are used in the treatment of various types of HD in various regions of Turkey [
5]. Although most of these medicinal plants have a long history of traditional use, they lack sufficient evidence-based scientific data that are needed for approval as a new drug at the current time. Most of the published data dealing with anti-hemorrhoidal properties are based on in vitro or animal studies and, thus, there are many gaps in their efficacy and safety profiles. Therefore, it is essential to complete preclinical safety and efficacy evaluations of these medicinal plants and then go through clinical trials to prove their efficacy. There is a plethora of studies that suggest that the use of herbal mixtures is more effective in the treatment of HD compared to single plant treatment [
2,
5,
6]. This is most probably due to possible synergistic effects, though these remain to be elucidated.
NS,
CB, and
AV are highly recommended for treating HD in the traditional Greco-Arab herbal medicine [
6,
27]. However, few studies, if any, have evaluated their synergistic anti-hemorrhoidal effects. The results of the present study demonstrated that the mixture of the three plants used as a topical cream was effective for the management of HD. The improvement was probably due to the antimicrobial, anti-inflammatory, antioxidant, and healing properties of the mixture.
3.1. Cytotoxicity Measurements
Cytotoxic effects of HPC were evaluated in the first phase of this study in cells from the mouse fibroblast cell line 3T3.
Figure 2 depicts the results of LDH release (A) and MTT assay (B) at 24, 48, and 72 h of incubation time with 0, 180, and 360 μg of HPC/mL. Compared to untreated control cells, no significant change in LDH-release was found whether as a function of increasing the HPC concentration or as a function of increasing the incubation period. Treatment with Triton X-100 as positive control increased the LDH release by 430 ± 27% compared to untreated cells (data not shown).
These results support the long history of safe use of the three herbs and published data regarding the biosafety of the individual plants. The LD50 values for
NS,
CB, and
AV are 19.8, 17.8 and 17.3 g/Kg weight, respectively [
15,
26].
3.2. Antibacterial Activities
Plants can be effective in the treatment of hemorrhoids through anti-bacterial, anti-inflammatory, anti-oxidant, and wound-healing activities [
1,
2,
3,
4,
5]. The plants with essential oils, flavonoids, alkaloids, and phenolic compounds are well known for their antibacterial effects including inhibitory action against acne-inducing bacteria [
5]. The antimicrobial activity of HPC against
E. coli was evaluated here using the disc diffusion method. Inhibition zone diameters were measured to evaluate the antimicrobial activities of HPC against
E. coli, compared with the reference antibiotic (Ampicillin). HPC showed a dose-dependent antibacterial activity against
E. coli, reaching 60% of the inhibition observed with the Ampicillin at 5 mg/disc (
Figure 3). There are many reports on the anti-bacterial action of the three plants of HPC [
2,
5,
11,
12,
13,
17,
28,
29,
30]. However, the observed relatively high antibacterial (compared to Ampicillin) effects in this study could be due to the synergistic effects of all three plant extracts.
3.3. Effects of HPC on Nitric Oxide Production (NO)
It is well known that HD is characterized by severe vasodilatation at the anal region, which leads to inflammation of the surrounding tissues and to further secondary complications such as extravasation of fluid into interstitial spaces mainly due to increased vascular permeability and migration of inflammatory cells [
1]. These newly migrated inflammatory cells (monocytes, lymphocytes, neutrophils, and eosinophils) begin to release pro-inflammatory cytokines (TNF-α and IL-6) and free radicals (NO). These factors activate anus-resident cells (fibroblasts, endothelial cells, macrophages, and mast cells), leading to systemic inflammatory responses (fever and cachexia) [
15]. Evidence for the role of pro-inflammatory cytokines and NO in the pathogenesis of hemorrhoids suggests that anti-inflammatory agents may be of therapeutic use in the treatment of HD. A large number of medicinal plants and their derived phytochemicals were reported to exhibit significant anti-inflammatory effects in in vitro as well as animal models. The LPS-activated human monocytic cell line THP-1 was used here to measure the anti-inflammatory effects of HPC. LPS-activated THP-1 cells are known to secret various pro-inflammatory cytokines, such as TNF-α, IL-1β, or IL-6, as well as NO [
15,
31,
32,
33]. The secretion levels of NO by cultured THP-1 was measured in the culture supernatants using Gries reagent.
Figure 4 shows the dose-dependent inhibition of the LPS mediated production of NO. HPC inhibited the NO production by cultured THP-1 cells in a dose-dependent manner, reaching the control levels of untreated cells at a concentration of 100 μg/mL. There are many reports on the anti-inflammatory action of three plants of HPC, in particular
NS. Different immunomodulatory and immunotherapeutic properties of
NS have been published. These publications provide clear evidence that both crude extracts and active compounds, in particular thymoquinone, exhibit significant anti-oxidant effects by enhancing the oxidant scavenger system, which consequently leads to antitoxic effects. The
NS oil and thymoquinone have exhibited potent anti-inflammatory effects on several inflammation-based models including experimental encephalomyelitis, colitis, peritonitis, edema, and arthritis through suppression of the pro-inflammatory mediators prostaglandins and leukotrienes. The oil exhibited positive immunomodulatory effects, enhancing T cell and natural killer cell-mediated immune responses. In addition, the oil and its active ingredients show antimicrobial effects toward different bacteria [
7,
10,
11]. Alchemilla plants are used in traditional medicine for the treatment of different diseases, including reducing the symptoms of sore throat, stopping bleeding, acting against gastrointestinal diseases and inflammatory processes, as well as for promoting wound healing due to its strong antimicrobial and anti-inflammatory effects. Therefore, the anti-oxidant, anti-inflammatory, and antibacterial properties of the three plants of HPC as separate plants. In particular,
NS, alone and in combination (due to synergistic effects), seem to be the main mediators of the observed significant anti-hemorrhoid effects of HPC.
3.4. Vasoconstriction Effect of HPC on Intestinal Vein Rings
The main symptoms of HD include enlargement and distal displacement of the normal anal clusters of veins, abnormal dilatation and distortion of the vascular channel, together with destructive changes in the connective tissue within the anal cushion. It seems that vascular hyperplasia and abnormal regulation of the vascular tone hyperplasia play an important role in HD development, and could be a potential target for topical medicinal plant-based treatment. In most cases, hemorrhoids are treated conservatively, using many methods such as lifestyle modification, fiber supplement, suppository-delivered anti-inflammatory drugs, and administration of venotonic drugs [
1,
4,
5]. Greco-Arab medicinal plant-based treatments are becoming popular in recent years [
6,
27]. Although there are reports on the vasoconstriction action of several medicinal plants, no information in the literature is available concerning vasoconstriction effects of
NS,
CB, or
AV. Therefore, vasoconstriction was evaluated here to clarify if the anti-hemorrhoidal effects of these plants involves vasoconstriction mechanisms. The results shown in
Figure 5 indicate a significant vasoconstriction effect of HPC in combination with phenylephrine. HPC increased the tension by 40%. This effect can explain the ability of HPC to reduce vein swelling during inflammatory conditions.
3.5. Open Label, Uncontrolled, Safety/Efficacy Study to Evaluate the Safety and Efficacy of HPC in the Treatment of Hemorrhoids
After obtaining the above-discussed positive in vitro results, we tested the safety and efficacy of HPC in the treatment of HD in an open-label, non-randomized, uncontrolled clinical study. This clinical study was carried out on 37 patients (17 females and 20 males, ages 19–59). The patients were asked to apply HPC twice daily for one week. Improvements in the severity degree of hemorrhoids (1–4), hemorrhage (0–3), pain (0–10), and itching (0–3) served us for evaluation of the HPC efficacy. The hemorrhoid severity degree for all the 37 patients was diagnosed as follows: 10 patients with degree 1, 18 with degree 2, and 9 with degree 3.
Figure 6 shows the obtained results. Almost all patients experienced a pronounced improvement in all four parameters tested.
3.6. RDBPC to Determine the Anti-Hemorrhoidal Efficacy and Safety of HPC
Although most of the currently used medicinal plants as well as their crude extracts in the management of HD have a history of traditional use, they lack sufficient evidence for approval as a new anti-hemorrhoidal drug. Therefore, the first advice is to complete efficacy and safety tests of these plants and then go through clinical trials to prove their efficacy [
2,
5,
6]. Furthermore, polyherbal formulations of these herbs may be more useful by possible synergism that needs to be elucidated. Traditional Greco-Arab medicine as well as other and traditional medicines of different countries represent an invaluable source to discovery of effective drugs with lower prevalence of side effects compared to synthetic pharmaceuticals [
2,
6,
7]. The mechanisms of action of these plants include anti-inflammatory, anti-oxidant, anti-nociceptive, venotonic and venoprotective activities or even stool softening by absorption of water absorption. Different classes of phytochemicals, especially flavonoids, triterpenes, tannins, and terpenoids, may be responsible for the observed anti-hemorrhoidal activity of medicinal plants.
Topical treatments of hemorrhoids assist locally in calming inflammation and for stopping bleeding and swelling and are highly useful. The efficacy of a topical treatment with HPC, prepared from extracts from NS, CB, and AV, was evaluated in this study for the management of hemorrhoids. These plants have historical backgrounds in traditional medicine in topical treatment of hemorrhoids. In addition, their synergistic effects of HPC in improving the symptoms of hemorrhoids such as pain, bleeding, itching, hemorrhage severity, and quality of life were evaluated here.
Following up the results obtained by the open-label clinical study on 37 patients (17 females and 20 males, ages 19–59), we conducted a new wider RDBPC to determine the anti-hemorrhoidal efficacy and safety of HPC. The results showed that after 7 days of treatment with HPC, an improvement was observed in all patients during various time intervals in the treatment. There were improvements in the severity of the patients’ major symptoms—severity of hemorrhoids (Degree 1–3) and hemorrhage severity (1–3)—compared to the placebo group (
Figure 7). A significant effect of HPC was observed on Quality of life (QoL) of the patients (Degree 1–3), Pain (0–10 Scale), and Itching (0–3 Scale), compared to placebo (
Figure 8). No side any effects were reported by any of the patients.
Figure 9 shows the effect of HPC on hemorrhage severity, disease degrees 1–3, as compared to placebo. Improvement was especially evident for the symptom of hemorrhage and no noticeable side effects were observed. Compared to placebo, treatment with HPC reduced the hemorrhage severity index to 0–1 after 6 days. The mechanism may be related to the regulation of cytokines in the systemic and hemorrhoidal region, which increases the permeability of the blood vessels and improves the coagulation mechanism and lymphatic blood pressure [
30,
34]. As discussed above, there are many reports about the anti-inflammatory action of the three plants of HPC. Several immunomodulatory, anti-inflammatory, and immunotherapeutic effects of
NS and
AV have been published. These publications provide clear evidence that both crude extracts and its active compounds, in particular thymoquinone, exhibit significant anti-oxidant and anti-inflammatory effects through enhancing the oxidant scavenger system, decreasing the production levels of pro-inflammatory cytokines (e.g., IL-6 and TNF-α) and increasing the production of anti-inflammatory cytokines (e.g., IL-10). Furthermore,
NS-derived oil and thymoquinone have also shown potent anti-inflammatory effects in several inflammation-based models including experimental encephalomyelitis, colitis, peritonitis, oedama, and arthritis through suppression of the pro-inflammatory mediators prostaglandins and leukotrienes. Most importantly, both the oil and its active ingredients expressed antimicrobial properties toward different microbes [
7,
10,
11].
AV is used in traditional medicine for different indications, including minimizing the symptoms of sore throat, stopping bleeding, acting against gastrointestinal diseases and inflammatory processes, as well as for promoting wound healing due to its strong antimicrobial and anti-inflammatory effects. Therefore, synergistic anti-oxidant, anti-inflammatory, and antibacterial properties of the three plants of HPC seem to be the main mediators of the observed significant hemorrhage effects of HPC.
Figure 10 shows the effect of HPC on pain severity, degrees 1–3, as compared to placebo. Patients of all three levels of disease showed significant decreases in the severity of pain, reaching the highest effects (severity index of about 1 in the three severity degrees) on day 6 compared to placebo. Greco-Arab and Islamic herbal medicine use many medicinal plants in the management of pain. Among these plants,
AV and
NS seeds are the sources of phytochemicals that have been researched for their therapeutic potential [
35,
36,
37,
38,
39].
NS fixed oil, either topically or orally, is traditionally used for the management of pain in the back, joints, and musculoskeletal organs, as well as for rheumatoid arthritis. The observed anti-pain effects of HPC may be the results of a syncretic effect of all the plants of HPC.
Figure 11 shows the effect of HPC on pruritus ani (anal itching). Compared to placebo, HPC application brought about significant clinical responses almost immediately after the initiation of the treatment. Complete response up to resolution of the complaints was achieved towards the end of the treatment period. Importantly, this favorable clinical response was seen in all subjects regardless of their disease grade, although grade-1 disease was more rapidly responsive in comparison to grades 2 or 3. Subjects assigned for placebo did not report any improvement.
NS fixed oil topically or orally is used traditionally for management all types of itching [
36,
37,
38,
39,
40]. The observed anti-pain effects of HPC may be the result of
NS alone or the result of a syncretic effect of all the plants of HPC.
4. Conclusions
HD is one of the most common gastrointestinal diseases. There are several conventional therapeutic options sometimes associated with complications. Therefore, researchers are looking for traditional medicines as a potential resource for the introduction of new natural drugs. The present in vitro, animal study, and randomized, double-blind, placebo-controlled trial aim to determine the efficacy and safety of HPC. Our in vitro study showed that HPC has significant antimicrobial, anti-inflammatory, and vasoconstriction effects. Following the promising results regarding the cytotoxicity, anti-inflammatory, anti- E. coli, and vasoconstrictive effects of HPC on intestinal vein rings, as well as an open label clinical study on 37 patients, we conducted a double-blind, placebo-controlled trial to determine the anti-hemorrhoidal efficacy and safety of HPC. This clinical trial included 77 patients suffering from symptomatic hemorrhoids in different grades. The patients were asked to apply HPC/placebo twice daily for 6 days. Each patient came to five visits as well as a follow-up visit: at baseline, at days 2, 4, 6, and at the observation endpoint after one month. The obtained results show that patients treated with HPC had significant clinical improvement in all disease severity parameters compared to placebo.
A large number of over-the-counter remedies are available on the market because of the widespread attitude of patients to often choose to self-medicate with natural remedies instead of conventional medical treatments which are sometimes burdened by a problematic risk/benefit ratio that negatively affects their usefulness [
31,
32,
33]. Therefore, it is important to search for effective and safe herbal-based alternatives. Given the rapid and comprehensive efficacy of HPC on all the different symptoms of HD, it can find a place in the treatment of this disease.