Study: Dermatological effects of Nigella sativa (Black Seed)

0
3238
Study: Dermatological effects of Nigella sativa (Black Seed)

Abstract
Nigella sativa seed, commonly known as black seed, has been employed as a natural remedy for many ailments for centuries in many cultures. It contains many active components including thymoquinone, thymohydroquinone, dithymoquinone, thymol,carvacrol, nigellimine, nigellicine, nigellidine and alphahederin. It was reported to possess numerous pharmacological effects related to several organs of the body. In this article, the literature pertaining to dermatological effects of N. sativa is reviewed. To the best of our knowledge this is the first review on this subject and we expect it stimulates further studies on the dermatological effects and application of N. sativa.

 

1. Introduction

Nigella sativa (N. sativa) belongs to the botanical family of Ranunculaceae and commonly grows in the Eastern Europe, Middle East, and Western Asia. It is a small shrub with tapering green leaves and rosaceous white and purplish flowers. Its ripe fruit contains tiny seeds, dark black in color, known as “Habba Al-Sauda” or “Habba Al-Barakah” in Arabic and black seed in English. The seed and oil of N. sativa were frequently used in ancient remedies (Unani, Ayurveda, Chinese and Arabic) in Asian countries and in the middle east. Several uses of the N. sativa seed had been mentioned by Ibne-Sina (980–1037) in his famous book Al-Qanoon fi el-Tibb (El-Kadi and Kandil, 1986, Al-Jishi, 2000).

Numerous active components have been isolated from N. sativa seed and its oil includingthymoquinone, thymohydroquinone, dithymoquinone, thymol, carvacrol, nigellimine-N-oxide, nigellicine, nigellidine and alpha-hederin. The pharmacological properties of N. sativa and its ingredients had been investigated by in vitro and in vivo studies conducted on human and laboratory animals. These studies showed that N. sativa and its ingredients have a wide range of pharmacological effects; immune-stimulatory, antiinflammatory, hypoglycemic,antihypertensive, antiasthmatic, antimicrobial, antiparasitic, antioxidant and anticancer effects (reviewed in Randhawa and Alghamdi, 2002, Randhawa and Alghamdi, 2011, Ali and Blunden, 2003, Salem, 2005, Padhye et al., 2008, Randhawa, 2008). Acute and chronic toxicity studies on laboratory animals have reported that N. sativa seed, its oil and thymoquinone, the most abundant and widely studied active principle, are safe, particularly when given orally (Badary et al., 1998, Mansour et al., 2001, Al-Ali et al., 2008). The objective of this article is to review the reported dermatological effects of N. sativa. An online and PubMed search of published articles related to the dermatological effects of N. sativaseed, its oil and active ingredients was conducted. Only articles substantiated by appropriate scientific methodology were reviewed and included. The following are categories of the studies: antimicrobial, antiviral, antifungal, antiparasitic, wound healing, psoriasis, acne vulgaris, vitiligo, skin cancer, percutaneous absorption, cosmetic application and cutaneousside effects.

 

2. Antimicrobial effects

2.1. Antibacterial
Topozada et al. (1965) were first to report the antibacterial effect of the phenolic fraction ofN. sativa oil. El-Fatatry (1975) isolated thymohydroquinone from the volatile oil of N. sativa, which was found to have high activity against gram-positive microorganisms, includingStaphylococcus aureus. Diethyl-ether extract of N. sativa was reported to possess concentration dependent inhibitory effect on gram-positive bacteria (represented by S. aureus) and gram-negative bacteria (represented by Pseudomonas aeruginosa andEscherichia coli) (Hanafi and Hatem, 1991). It also showed synergistic effect withstreptomycin and gentamycin and additive effect with spectinomycin, erythromycin,tobramycin, doxycycline, chloramphenicol, nalidixic acid, ampicillin, lincomycin and co-trimoxazole and successfully eradicated a non-fatal subcutaneous staphylococcal infectioninduced experimentally in mice when injected at the site of infection (Hanafi and Hatem, 1991). N. sativa extract showed almost similar results to topical mupirocin in the treatment ofneonates with staphylococcal pustular skin infections with no side effects (Rafati et al., 2014). Microbial resistance to drugs is a common and important issue. Studies of the effects of N. sativa extracts in vitro against resistant microorganisms, including resistant S. aureusand P. aeruginosa, showed promising and good results against many multi-drug-resistant gram positive and gram negative bacteria (Morsi, 2000, Mashhadian and Rakhshandeh, 2005, Salman et al., 2005).

2.2. Antiviral
N. sativa was found to enhance helper T cell (T4) and suppressor T cell (T8) ratio and increased natural killer (NK) cell activity in healthy volunteers (El-Kadi and Kandil, 1986). Besides improvement in immunity, N. sativa extract had some inhibitory effect on the humanimmune deficiency virus protease but the active principle(s) responsible for this activity was not identified (Ma et al., 1994). Moreover, N. sativa oil when given intraperitoneally to mice infected with murine cytomegalovirus for 10 days, the virus was undetectable in the liver andspleen, while it was still detectable in the control mice. This action was considered to be related to increase in the number and function of M-phi and CD4 +ve T cells and increased production of INF-gamma (Salem and Hossain, 2000).

2.3. Antifungal
Hanafi and Hatem (1991) were the first to demonstrate the inhibitory effect of the diethyl-ether extract of N. sativa extract against Candida albicans. The ether extract of N. sativawas reported to inhibit the growth of Candida yeasts in several organs in experimental animal infections (Khan et al., 2003). Thymoquinone was also shown to inhibit in vitroAspergillus niger and Fusarium solani and the activity was comparable to amphotericin-B(Al-Jabre et al., 2003, Alqorashi et al., 2007, Randhawa et al., 2005). It was reported to be more effective than amphotericin-B and griseofulvin against Scopulariopsis brevicaulisgrowth in vitro. There was 100% inhibition of the growth of S. brevicaulis with thymoquinone 1 mg/ml, while amphotericin-B 1 mg/ml inhibited only 70% growth. However, clotrimazolewas much more effective than the above mentioned drugs, with an MIC of 0.03 mg/ml (Aljabre, 2005).

The ether extract of N. sativa was found to inhibit dermatophytes isolated from sheep skin infection (Kader et al., 1995). Thymoquinone was shown to possess moderate activity against clinical isolates of the three main groups of dermatophytes: Trichophyton,Epidermophyton and Microsporum and the ether extract of N. sativa were also found to be effective but in relatively higher concentrations (Aljabre et al., 2005). The MIC of thymoquinone against various dermatophytes ranged from 0.125 to 0.25 mg/ml, while the ether extract inhibited 80–100% of the growth of most dermatophytes at 40 mg/ml. Proportionately, greater effect of thymoquinone than N. sativa extract points out to that, theantifungal activity of N. sativa is primarily due to thymoquinone (Aljabre et al., 2005). In another study also thymoquinone, thymohydroquinone and thymol demonstrated antifungal effect against many clinical isolates, including dermatophytes, molds and yeasts at a concentration of 1 mg/ml (Taha et al., 2010). Using broth microdilution assay, extract of N. sativa inhibited the growth of Madurella mycetomatis, an important causative fungus ofmycetoma, at a concentration as low as 1 μg/ml (Elfadil et al., 2015).

2.4. Antiparasitic
An ointment prepared from the alcoholic extract of N. sativa seeds was applied daily for 15 weeks to cutaneous leishmaniasis produced experimentally in mice by a subcutaneous inoculation of Leishmania major at the dorsal base of the tail. The morphology of the lesion and the body weight of mice were monitored daily. There was no significant difference between the average weight of mice receiving N. sativa extract ointment and controls but the lesion diameter and symptoms of inflammation were significantly lesser in the test group as compared to the controls (Bafghi et al., 2011).

N. sativa seed was tested against miracidia, cercariae and adult worms of Schistosoma mansoni and showed strong biocidal activity against all stages of the parasite, as well as an inhibitory effect on egg-laying of adult female worms, indicating an antischistosomal potential of the N. sativa (Mohamed et al., 2005). In S. mansoni experimentally infected mice, the antischistosomal activity of N. sativa oil was found to be comparable to praziquantel and when given in combination with praziquantel there was potentiation of its effect (Mahmoud et al., 2002).

 

3. Wound healing

N. sativa seed and its oil were found to promote wound healing in farm animals (Ahmed et al., 1995). Moreover, ether extract of N. sativa seed applied topically onto staphylococcal-infected skin in mice enhanced healing by reducing total and absolute differential WBC counts, local infection and inflammation, bacterial expansion and tissue impairment (Abu-Al-Basal, 2011). Using human gingival fibroblast as a monolayer, aqueous extract of N. sativaexhibited low free radical scavenging activity and induced gingival fibroblast proliferation with accelerated wound closure activity despite its non-significant effect on collagen synthesis(Ab Rahman et al., 2014). It also resulted in elevation of basic fibroblast growth factor andtransforming growth factor beta (Ab Rahman et al., 2014).

 

4. Anti-inflammatory

4.1. Psoriasis
The ethanolic extract of N. sativa seed was evaluated for antipsoriatic activity in vivo by using mouse tail model for psoriasis and in vitro by using sulforhodamine B assay employingHaCaT human keratinocyte cell lines (Dwarampudi et al., 2012).

Significant epidermal differentiation was produced by the ethanolic extract of N. sativa, 71.36 ± 2.64%. In the negative control the epidermal differentiation was 17.30 ± 4.09% and in the positive control (tazarotene 0.1%) was 90.03 ± 2.00%. The antiproliferant activity of the ethanolic extract of N. sativa was good, IC50 value of 239 μg/ml, as compared to that of the positive control, asiaticoside, which showed potent activity with IC50 value of 20.13 μg/ml.

4.2. Acne vulgaris
In a clinical study (Abdul-Ameer and Al-Harchan, 2010), N. sativa oil lotion 10% significantly reduced mean lesion count of papules and pustules after 2 months of therapy. In the test group, the response to treatment was graded as good in 58%, moderate in 35% and no response in 7%. The satisfaction of patients with treatment was found to be full in 67%, partial in 28%, and no satisfaction in 5%. While in the control group, the lesions showed no significant reduction after 2 months and the response to treatment was good in 8%, moderate in 34%, and no response in 58%. The satisfaction of patients with treatment in this group was full in 8%, partial in 24%, and no satisfaction in 68%. There were no side effectsin the group treated with N. sativa oil lotion 10%. The authors attributed the results to theantimicrobial, immunomodulatory and anti-inflammatory effects of N. sativa oil. The molecular mechanisms of anti-inflammatory and antioxidative activities of thymoquinone, the most abundant active principle of N. sativa had been studied. Pretreatment of female HR-1 hairless mouse skin with thymoquinone attenuated 12-O-tetradecanoylphorbol-13-acetate (TPA)-induced expression of cyclooxygenase-2 (COX-2). Thymoquinone diminished nuclear translocation and the DNA binding of nuclear factor-kappa-B (NF-κB) via the blockade ofphosphorylation and subsequent degradation of IκBα in TPA-treated mouse skin. Thymoquinone also attenuated the phosphorylation of Akt, c-Jun-N-terminal kinase and p38 mitogen-activated protein kinase, but not that of extracellular signal-regulated kinase-1/2. Moreover, topical application of thymoquinone induced the expression of hemeoxygenase-1, NAD(P)H-quinoneoxidoreductase-1, glutathione-S-transferase and glutamate cysteine ligasein mouse skin (Kundu et al., 2013).
Similar anti-inflammatory effect of N. sativa fixed oil and thymoquinone has also been reported earlier by Houghton et al. (1995). The effect was demonstrated via the dose-dependent decrease in the formation of thromboxane B2 and leukotriene B4 showing the inhibition of cyclooxygenase and 5-lipooxygenase pathways of arachidonate metabolism in rat peritoneal leukocytes.

 

5. Skin pigmentation

5.1. Vitiligo
Lyophilized seed extract of N. sativa and its active ingredient, thymoquinone, showed significant skin darkening on the isolated melanophores of the wall lizard (Ali and Meitei, 2011). The pigment cells when exposed to the extract or thymoquinone responded by distinct dispersion of melanin leading to skin darkening. The melanin dispersal effect was antagonized by anticholinergic drugs, atropine and hyoscine, and potentiated by ananticholinesterase agent, neostigmine. The authors suggested that cholinergic mechanisms of muscarinic nature are involved in the melanin dispersion (Ali and Meitei, 2011). In a randomized double blind clinical study, patients applied N. sativa oil to lesions of vitiligotwice daily for 6 months had a significant decrease in the vitiligo area scoring index with no significant side effects (Ghorbanibirgani et al., 2014).

 

6. Hypersensitivity reactions

Earlier, carbonyl fraction of N. sativa and its active components, thymoquinone and nigellone were shown to counter the manifestations of allergic reactions; inhibition of histamine release from mast cells (Chakravorty, 1993), protection from histamine-inducedbronchospasm in guinea pigs (El-Dakhakhany, 1982) and decreases in the lung eosinophilia, elevated Th2 cytokines and raised IgE and IgG1 antibodies in a mouse model of allergic asthma induced by ovalbumin (El Gazzar et al., 2006).

Recently, a clinical study was conducted to compare the efficacy of Nigella, Betamethasoneand Eucerin ointments applied topically twice daily for 4 weeks in new cases of hand eczema. Changes in the severity of eczema and life quality were assessed by hand eczema severity index (HECSI) and dermatology life quality index (DLQI), respectively. Nigella and Betamethasone showed rapid improvement in the hand eczema and the quality of life as compared to Eucerin. No significant difference was detected in the mean HECSI and DLQIscores of the N. sativa and Betamethasone groups, indicating to the possibility that, N. sativa had same efficacy as Betamethasone in the improvement of hand eczema and life quality (Yousefi et al., 2013).

 

7. Skin cancers

The anticancer activity of N. sativa was revealed, for the first time, when an enhancement of the natural killer (NK) cell activity was observed in advanced cancer patients receiving multimodality immunotherapy program in which N. sativa seed was one of the components (El-Kadi and Kandil, 1986). Regarding dermatology, Salomi et al. (1991) were first to investigate the antineoplastic effect of N. sativa. They reported that the topical application ofN. sativa and Crocus sativus extracts inhibited two-stage initiation/promotion of [dimethylbenz [a] anthracene (DMBA)/croton oil] induced skin carcinogenesis in mice, delayed the onset of papilloma formation and reduced the number of papillomas per mouse. Later, the protective effect of bee honey and Nigella was studied on the oxidative stress andcarcinogenesis induced by methylnitrosourea (MNU) in Sprague Dawely rats. It was observed that MNU produced oxidative stresses ranging from severe inflammatory reactionin lung and skin to colon adenocarcinoma in four out of six animals. The serummalondialdehyde (MDA) and nitric oxide (NO) were also raised. Treatment with N. sativaseed given orally protected against MNU-induced oxidative stress and carcinogenesis by 80% (12/15), whereas honey and N. sativa seed together protected 100% (12/12); and serum MDA and NO also significantly decreased in both cases compared to active controls (Mabrouk et al., 2004).

In another study, antineoplastic activity of thymoquinone was investigated using mousekeratinocytes, papilloma (SP-1) and spindle-17 carcinoma cells. In SP-1 cells thymoquinone induced G0/G1 cell-cycle arrest, which correlated with sharp increases in the expression of the cyclin-dependent kinase inhibitor p16 and a decrease in cyclin D1 protein expression. While in spindle 17 cells, G2/M cell-cycle arrest was noticed, this was associated with an increase in the expression of the tumor suppressor protein p53 and a decrease in cyclin B1protein. At longer times of incubation, thymoquinone induced apoptosis in both cell lines by remarkably increasing the ratio of Bax/Bcl-2 protein expression and decreasing Bcl-xL protein. These findings support a potential role for thymoquinone as a chemopreventive agent, particularly at the early stages of skin tumorigenesis (Gali-Muhtasib et al., 2004). Antitumor activity of thymoquinone and thymohydroquinone was also demonstrated usingtumor cell lines (squamous cell carcinoma, SCC VII) and fibrosarcoma, FsaR) and murinetumor models of fibrosarcoma and squamous cell carcinoma (Ivankovic et al., 2006).

Thymoquinone and diosgenin, the active ingredients obtained from N. sativa and fenugreek (Trigonella foenumgraecum), respectively, were shown to exert potent bioactivity against squamous cell carcinoma in vitro. They inhibited cell proliferation and induced cytotoxicity in A431 and Hep2 cells. These agents induced apoptosis by increasing the sub-G1 population, LIVE/DEAD cytotoxicity, chromatin condensation, DNA laddering and TUNEL-positive cells. There was also an increase in Bax/Bcl-2 ratio, activation of cell proliferation of caspases and cleavage of poly ADP ribose polymerase in the treated cells. In combination, thymoquinone and diosgenin had synergistic effects, resulting in cell viability as low as 10%. In a mouse xeno-graft model, a combination of thymoquinone and diosgenin significantly reduced tumor volume, mass and increased apoptosis (Das et al., 2012).

Using an in vitro cell migration assay, Ahmad et al. (2013) found that, thymoquinone inhibited the migration of both human and mouse melanoma cells. The inhibition ofmetastasis by thymoquinone was also observed in vivo in B16F10 mouse melanoma model and was accompanied by a decrease in expression of NLRP3 (NACHT, LRR, and pyrindomain-containing protein 3) inflammasome which resulted in decreased proteolytic cleavage of caspase-1. Inactivation of caspase-1 by thymoquinone resulted in the inhibition of IL-1β and IL-18. Thymoquinone also inhibited NF-κB activity in mouse melanoma cellsand reactive oxygen species and the later in turn resulted in the partial inactivation of NLRP3 inflammasome. The authors suggested that, thymoquinone can be a potentialimmunotherapeutic agent not only as an adjuvant therapy for melanoma, but also, in the control and prevention of metastatic melanoma (Ahmad et al., 2013).

 

8. Percutaneous absorption

The effect of N. sativa oil on the percutaneous absorption of model lipophilic drug-carvedilol was investigated using excised rat abdominal skin (Amin et al., 2008). N. sativa oil in 5% v/v had high degree of enhancing permeation as indicated by transdermal flux, permeability coefficient and enhancement factor. Employing differential scanning calorimetry, Fourier transform infrared and histopathology, N. sativa oil in 5% v/v, was found to work by extracting lipids from stratum corneum and by loosening the hydrogen bonds betweenceramides with subsequent fluidization of the lipid bilayer. The increased permeability of the lipophilic drug-carvedilol was considered to be due to increased diffusivity through the stratum corneum under the influence of N. sativa oil. It was postulated that, the higher content of linoleic acid and other unsaturated fatty acids in N. sativa oil was responsible for the enhancement of in vitro percutaneous absorption of the drug (Amin et al., 2010).

 

9. Cosmetic application

Using pH meter, corneometer, tewameter, methyl nicotinate model of micro-inflammation in human skin, and tape stripping of the stratum corneum, the in vivo and ex vivo properties of emulsions with the seedcake extracts of N. sativa have been evaluated (Amin et al., 2010). Emulsions with Borago officinalis, and N. sativa seedcakes significantly reduced skin irritation and improved the skin hydration and epidermal barrier function as compared with placebo. The authors suggested the potential use of seedcakes in anti-aging, moisturizing, mitigating, and protective cosmetics due to their antioxidant and anti-inflammatory activities.

 

10. Cutaneous side effects

Contact dermatitis developed after the application of ointment made from the N. sativa seed oil but it could have been due to some impurity in the commercial black seed oil (Zedlitz et al., 2002). Bullous drug eruption with sub-epidermal detachment and necrosis of the epidermal surface has been reported in a 53-year-old woman after 2 weeks of applying N. sativa oil to her skin and ingesting it as well (Gelot et al., 2012).

 

11. Conclusion

The published original research articles on the effects of N. sativa and its ingredients strongly indicate its pharmacological potential in dermatology. Standard methods of drug development are needed to formulate topical therapy for use in dermatology.
Conflict of interest
None.

———————————————-

References

Ab Rahman et al., 2014
M.R. Ab Rahman, F. Abdul Razak, M. Mohd BakriEvaluation of wound closure activity of Nigella sativa, Melastoma malabathricum, Pluchea indica, and Piper sarmentosum extracts on scratched monolayer of human gingival fibroblasts
Evid. Based Complement. Altern. Med., 2014 (2014), p. 190342
Google Scholar
Abdul-Ameer and Al-Harchan, 2010
N. Abdul-Ameer, H. Al-HarchanTreatment of acne vulgaris with Nigella Sativa oil lotion
Iraq. Postgrad. Med. J., 2 (2010), pp. 140-143
View Record in ScopusGoogle Scholar
Abu-Al-Basal, 2011
M.A. Abu-Al-BasalInfluence of Nigella sativa fixed oil on some blood parameters and histopathology of skin in staphylococcal-infected BALB/c mice
Pak. J. Biol. Sci., 14 (23) (2011), pp. 1038-1046
View Record in ScopusGoogle Scholar
Ahmad et al., 2013
I. Ahmad, K.M. Muneer, I.A. Tamimi, M.E. Chang, M.O. Ata, N. YusufThymoquinone suppresses metastasis of melanoma cells by inhibition of NLRP3 inflammasome
Toxicol. Appl. Pharmacol., 270 (1) (2013), pp. 70-76
ArticleDownload PDFView Record in ScopusGoogle Scholar
Ahmed et al., 1995
I.H. Ahmed, M.A. Awad, M. El-Mahdy, H.M. Gohar, A.M. GhanemThe effect of some medicinal plant extracts on wound healing in farm animals
Assiut Vet. Med. J., 32 (64) (1995), pp. 236-244
View Record in ScopusGoogle Scholar
Al-Ali et al., 2008
A. Al-Ali, A. Alkhawajah, M.A. Randhawa, N.A. ShaikhOral and intraperitoneal LD50 of thymoquinone, an active principle of Nigella sativa, in mice and rats
J. Ayub Med. Coll. Abbottabad, 20 (2) (2008), pp. 25-27
View Record in ScopusGoogle Scholar
Ali and Blunden, 2003
B.H. Ali, G. BlundenPharmacological and toxicological properties of Nigella sativa
Phytother. Res., 17 (4) (2003), pp. 299-305
CrossRefView Record in ScopusGoogle Scholar
Ali and Meitei, 2011
S.A. Ali, K.V. MeiteiNigella sativa seed extract and its bioactive compound thymoquinone: the new melanogens causing hyperpigmentation in the wall lizard melanophores
J. Pharm. Pharmacol., 63 (5) (2011), pp. 741-746
CrossRefView Record in ScopusGoogle Scholar
Aljabre, 2005
S.H.M. AljabreIn vitro antifungal activity of thymoqyuinone against Scopulariopsis brevicaulis
Arab J. Pharm. Sci., 3 (2005), pp. 27-33
View Record in ScopusGoogle Scholar
Al-Jabre et al., 2003
S. Al-Jabre, O.M. Al-Akloby, A.R. Al-Quraishi, N. Akhtar, A. Al-Dossary, M.A. RandhawaThymoquinone, an active principle of Nigella sativa, inhibited Aspergillus niger
Pak. J. Med. Res., 42 (2003), pp. 102-104
Google Scholar
Aljabre et al., 2005
S.H.M. Aljabre, M.A. Randhawa, A. Akhtar, O.M. Alakloby, A.M. Alqurashi, A. AldossaryAntidermatophyte activity of ether extract of Nigella sativa and its active principle, thymoquinone
J. Ethnopharmacol., 101 (2005), pp. 116-119
ArticleDownload PDFView Record in ScopusGoogle Scholar
Al-Jishi, 2000
Al-Jishi, S.A.A., 2000. A Study of Nigella sativa on Blood Hemostatic Functions (M.Sc thesis). King Faisal University, Dammam, Saudi Arabia.
Google Scholar
Alqorashi et al., 2007
A. Alqorashi, N. Akhtar, S. AljabreThe effect of thymoquinone and B on the growth of Aspergillus niger
Sci. J. King Faisal Univ., 8 (1) (2007), pp. 137-145
Google Scholar
Amin et al., 2008
S. Amin, K. Kohli, R.K. Khar, S.R. Mir, K.K. PillaiMechanism of in vitro percutaneous absorption enhancement of carvedilol by penetration enhancers
Pharm. Dev. Technol., 13 (6) (2008), pp. 533-539
CrossRefView Record in ScopusGoogle Scholar
Amin et al., 2010
S. Amin, S.R. Mir, K. Kohli, B. Ali, M. AliA study of the chemical composition of black cumin oil and its effect on penetration enhancement from transdermal formulations
Nat. Prod. Res., 24 (12) (2010), pp. 1151-1157
CrossRefView Record in ScopusGoogle Scholar
Amin et al., 2010
S. Amin, S.R. Mir, K. Kohli, B. Ali, M. AliA study of the chemical composition of black cumin oil and its effect on penetration enhancement from transdermal formulations
Nat. Prod. Res., 24 (12) (2010), pp. 1151-1157
CrossRefView Record in ScopusGoogle Scholar
Badary et al., 1998
O.A. Badary, O.A. Al-Shabana, M.N. Nagi, A.M. Al-Bekairi, M.M.A. ElmazarAcute and subchronic toxicity of thymoquinone in mice
Drug Dev. Res., 44 (1998), pp. 56-61
CrossRefView Record in ScopusGoogle Scholar
Bafghi et al., 2011
A.F. Bafghi, A.R. Vahidi, M.H. Anvari, K. Barzegar, M. GhafourzadehThe in vivo antileishmanial activity of alcoholic extract from Nigella sativa seeds
Afr. J. Microbiol. Res., 5 (12) (2011), pp. 1504-1510
Google Scholar
Chakravorty, 1993
N. ChakravortyInhibition of histamine release from mastcells by nigellone
Ann. Allergy, 70 (1993), pp. 237-242
Google Scholar
Das et al., 2012
S. Das, K.K. Dey, G. Dey, I. Pal, A. Majumder, S.M. Choudhury, S.C. Kundu, M.M. MailAntineoplastic and apoptotic potential of traditional medicines thymoquinone and diosgenin in squamous cell carcinoma
Plos One (2012), 10.1371/journal.pone.004664
Google Scholar
Dwarampudi et al., 2012
L.P. Dwarampudi, D. Palaniswamy, M. Nithyanantham, P.S. RaghuAntipsoriatic activity and cytotoxicity of ethanolic extract of Nigella sativa seeds
Pharmacogn. Mag., 8 (32) (2012), pp. 268-272
View Record in ScopusGoogle Scholar
El Gazzar et al., 2006
M.A. El Gazzar, R. El Mezayen, J.C. Marecki, M.R. Nicolls, A. Canastar, S.C. DreskinAnti-inflammatory effect of thymoquinone in a mouse model of allergic lung inflammation
Int. Immunopharmacol., 6 (2006), pp. 1135-1142
ArticleDownload PDFView Record in ScopusGoogle Scholar
El-Dakhakhany, 1982
El-Dakhakhany, M., 1982. Some pharmacological properties of some constituents ofNigella sativa L. seeds: the carbonyl fraction of essential oil. In: Proceeding of the 2nd International Conference on Islamic Medicine, Kuwait, 12th April, pp. 426–431.
Google Scholar
Elfadil et al., 2015
H. Elfadil, A. Fahal, W. Kloezen, E.M. Ahmed, W. van de SandeThe in vitro antifungal activity of sudanese medicinal plants against Madurella mycetomatis, the mycetoma major causative agent
PLoS Negl. Trop. Dis., 9 (3) (2015), p. e0003488, 10.1371/journal.pntd.0003488
CrossRefGoogle Scholar
El-Fatatry, 1975
H.M. El-FatatryIsolation and structure assignment of an anti-microbial principle from the volatile oil of Nigella sativa L. seeds
Pharmazie, 30 (2) (1975), pp. 109-111
Google Scholar
El-Kadi and Kandil, 1986
El-Kadi, A., Kandil, O., 1986. Effect of Nigella sativa (the black seed) on immunity. In: Proceedings of the Fourth International Conference on Islamic Medicine, 4 November, Kuwait, pp. 344–348.
Google Scholar
Gali-Muhtasib et al., 2004
H.U. Gali-Muhtasib, W.G. Abou Kheir, L.A. Kheir, N. Darwiche, P.A. CrooksMolecular pathway for thymoquinone-induced cell-cycle arrest and apoptosis in neoplastic keratinocytes
Anticancer Drugs, 15 (4) (2004), pp. 389-399
CrossRefView Record in ScopusGoogle Scholar
Gelot et al., 2012
P. Gelot, C. Bara-Passot, E. Gimenez-Amanu, et al.Bullous drug eruption with Nigella sativa oil
Ann. Dermatol. Venereol., 139 (4) (2012), pp. 287-291
ArticleDownload PDFView Record in ScopusGoogle Scholar
Ghorbanibirgani et al., 2014
A. Ghorbanibirgani, A. Khalili, D. RokhafroozComparing Nigella sativa oil and fish oil in treatment of vitiligo
Iran. Red Crescent Med. J., 16 (6) (2014), p. e4515
Google Scholar
Hanafi and Hatem, 1991
M.S. Hanafi, M.E. HatemStudies on the anti-microbial activity of the Nigella sativa seed (Black Cumin)
J. Ethnopharmacol., 34 (2–3) (1991), pp. 275-278
Google Scholar
Houghton et al., 1995
P.J. Houghton, R. Zarka, B. de lasHeras, J.R. HoultFixed oil of Nigella sativa and derived thymoquinone inhibit eicosanoid generation in leukocytes and membrane lipid peroxidation
Planta Med., 61 (1) (1995), pp. 33-36
CrossRefView Record in ScopusGoogle Scholar
Ivankovic et al., 2006
S. Ivankovic, R. Stojkovic, M. Jukic, M. Milos, M. JurinThe antitumor activity of thymoquinone and thymohydroquinone in vitro and in vivo
Exp. Oncol., 28 (2006), pp. 220-224
View Record in ScopusGoogle Scholar
Kader et al., 1995
H.A.A. Kader, S.R. Seddek, A.A. El-ShanawanyIn vitro study of the effect of some medicinal plants on the growth of some dermatophytes
Assiut Vet. Med. J., 34 (6–7) (1995), pp. 36-42
View Record in ScopusGoogle Scholar
Khan et al., 2003
M.A. Khan, M.K. Ashfaq, H.S. Zuberi, A.H. ZuberiThe in vivo antifungal activity of the aqueous extract from Nigella sativa seed
Phytother. Res., 17 (2003), pp. 183-186
CrossRefView Record in ScopusGoogle Scholar
Kundu et al., 2013
J.K. Kundu, L. Liu, J.W. Shin, Y.J. SurhThymoquinone inhibits phorbol ester-induced activation of NF-κB and expression of COX-2, and induces expression of cytoprotective enzymes in mouse skin in vivo
Biochem. Biophys. Res. Commun., 438 (4) (2013), pp. 721-727
ArticleDownload PDFView Record in ScopusGoogle Scholar
Ma et al., 1994
C.M. Ma, H. Miyashiro, M. Hattori, K. ShimotohnoScreening of traditional medicines for their inhibitory effects on human immunodeficiency virus protease
J. Tradit. Med., 11 (4) (1994), pp. 416-417
View Record in ScopusGoogle Scholar
Mabrouk et al., 2004
G.M. Mabrouk, S.S. Moselhy, S.F. Zohny, E.M. Ali, T.E. Helal, A.A. Amin, A.A. KhalifaInhibition of methylnitrosourea (MNU) induced oxidative stress and carcinogenesis by orally administered bee honey and Nigella grains in Sprague Dawely rats
J. Exp. Clin. Cancer Res., 21 (3) (2004), pp. 341-346
Google Scholar
Mahmoud et al., 2002
M.R. Mahmoud, H.S. El-Abhar, S. SalehThe effect of Nigella sativa oil against the liver damage induced by Schistosoma mansoniinfection in mice
J. Ethnopharmacol., 79 (1) (2002), pp. 1-11
ArticleDownload PDFView Record in ScopusGoogle Scholar
Mansour et al., 2001
M.A. Mansour, O.T. Ginwai, T. El-Hadiya, A.S. ElKhatib, O.A. Al-Shabanah, H.A. Al-SawafEffects of volatile oil constituents of Nigella sativa on carbon tetrachloride-induced hepatotoxicity in mice: evidence for antioxidant effects of thymoquinone
Res. Commun. Mol. Pathol. Pharmacol., 110 (2001), pp. 239-251
View Record in ScopusGoogle Scholar
Mashhadian and Rakhshandeh, 2005
N.V. Mashhadian, H. RakhshandehAntibacterial and antifungal effects of Nigella sativa extracts against S. aureus, P. aeruginosa andC. albicans
Pak. J. Med. Sci., 21 (1) (2005), pp. 47-52
View Record in ScopusGoogle Scholar
Mohamed et al., 2005
A.M. Mohamed, N.M. Metwally, S.S. MahmoudNigella sativa seeds against Schistosoma mansoni different stages
Mem. Inst. Oswaldo Cruz, 100 (2) (2005), pp. 205-211
CrossRefView Record in ScopusGoogle Scholar
Morsi, 2000
N.M. MorsiAntimicrobial effect of crude extracts of Nigella sativa on multiple antibiotic resistant bacteria
Acta Microbiol. Pol., 49 (1) (2000), pp. 63-74
View Record in ScopusGoogle Scholar
Padhye et al., 2008
S. Padhye, S. Banerjee, A. Ahmad, R. Mohammad, F.H. SarkarFrom here to eternity – the secret of Pharaohs: therapeutic potential of black cumin seeds and beyond
Cancer Ther., 6 (2008), pp. 495-510
View Record in ScopusGoogle Scholar
Rafati et al., 2014
S. Rafati, M. Niakan, M. NaseriAnti-microbial effect of Nigella sativa seed extract against staphylococcal skin infection
Med. J. Islam. Repub. Iran., 8 (28) (2014), p. 42
Google Scholar
Randhawa, 2008
M.A. RandhawaAn update on antimicrobial effects of Nigella sativa and experience at King Faisal University, Dammam, Saudi Arabia
JSSDDS, 12 (1) (2008), pp. 36-43
Google Scholar
Randhawa and Alghamdi, 2002
M.A. Randhawa, M.S. AlghamdiA review of the pharmaco-therapeutic effects of Nigella sativa
Pak. J. Med. Res., 41 (2) (2002), pp. 77-83
View Record in ScopusGoogle Scholar
Randhawa and Alghamdi, 2011
M.A. Randhawa, M.S. AlghamdiAnticancer activity of Nigella sativa (Black Seed)—a review
Am. J. Chin. Med., 39 (6) (2011), pp. 1075-1091
CrossRefView Record in ScopusGoogle Scholar
Randhawa et al., 2005
M.A. Randhawa, O.M. Alaklobi, S.H.M. Aljabre, A.M. Alqorashi, N. AkhtarThymoquinone, an active principle of Nigella sativa, inhibited Fusarium solani
Pak. J. Med. Res., 44 (2005), pp. 1-3
View Record in ScopusGoogle Scholar
Salem, 2005
M.L. SalemImmunomodulatory and therapeutic properties of Nigella sativa L. seed
Int. Immunopharmacol., 5 (2005), pp. 1749-1770
ArticleDownload PDFView Record in ScopusGoogle Scholar
Salem and Hossain, 2000
M.L. Salem, M.S. HossainProtective effect of black seed oil from Nigella sativa against murine cytomegalovirus
Int. J. Immunopharmacol., 22 (9) (2000), pp. 729-740
ArticleDownload PDFView Record in ScopusGoogle Scholar
Salman et al., 2005
Salman, M.T., Khan, R.A., Shukla, I., 2005. Antimicrobial activity of Nigella sativa oil againstStaphylococcus aureus obtained from clinical specimens. In: 38th Annual Conference of Indian Pharmacological Society, Chennai, India, 28–30 Dec.
Google Scholar
Salomi et al., 1991
M.J. Salomi, S.C. Nair, K.R. PanikkarInhibitory effects of Nigella sativa and saffron (Crocus sativus) on chemical carcinogenesis in mice
Nutr. Cancer, 16 (1991), pp. 67-72
CrossRefView Record in ScopusGoogle Scholar
Taha et al., 2010
M. Taha, A. Azeiz, W. SaudiAntifungal effect of thymol, thymoquinone and thymohydroquinone against yeasts, dermatophytes and non-dermatophyte molds isolated from skin and nails fungal infections
Egypt. J. Biochem. Mol. Biol., 28 (2) (2010), pp. 109-126
View Record in ScopusGoogle Scholar
Topozada et al., 1965
H.H. Topozada, H. Masloum, M. El-DakhakhanyThe anti-bacterial properties of Nigella sativa seeds: active principle with some clinical application
J. Egypt. Med. Assoc., 48 (Suppl.) (1965), pp. 187-202
View Record in ScopusGoogle Scholar
Yousefi et al., 2013
M. Yousefi, B. Barikbin, M. Kamalinejad, E. Abolhasani, A. Ebadi, S. Younespour, M.Manouchehrian, S. HejaziComparison of therapeutic effect of topical Nigella with Betamethasone and Eucerin in hand eczema
J. Eur. Acad. Dermatol. Venereol., 27 (2013), pp. 1498-1504
CrossRefView Record in ScopusGoogle Scholar
Zedlitz et al., 2002
S. Zedlitz, R. Kaufmann, W.H. BoehnckeAllergic contact dermatitis from black cumin (Nigella sativa) oil-containing ointment
Contact Dermatitis, 46 (2002), p. 188
CrossRefView Record in ScopusGoogle Scholar

Author links open overlay panelSalih H.M.AljabreaOmar M.AlaklobyaMohammad A.Randhawab
a
Department of Dermatology, College of Medicine, King Fahd Hospital of the University, University of Dammam, Dammam, Saudi Arabia
b
Department of Pharmacology, College of Medicine, Northern Border University, P.O. Box 1321, Arar 91431, Saudi Arabia

LEAVE A REPLY

Please enter your comment!
Please enter your name here