ABSTRACT
Carthami flos, the dried floret of Carthamus tinctorius L., Asteraceae (safflower), has been widely used in traditional Chinese medicine to treat a broad range of ailments, such as coronary heart disease, angina pectoris, gynecologic disease, stroke, and hypertension. However, although several studies on Carthami flos have been done consecutively, the results are usually scattered across various documents. This review aims to provide up-to-date information on the traditional uses, pharmacology, clinical applications, and toxicology of Carthami flos in China and thereby to provide a basis for further investigation of its use to treat dissimilar diseases. Various ethnomedical uses of Carthami flos have been documented in many ancient Chinese books. Crude extracts and isolated compounds from Carthami flos show a broad range of pharmacological properties, such as protective effects on brain tissue, on osteoblasts, and in myocardial ischemia, as well as anti-inflammatory, antithrombotic, antitumor, and antidiabetic activities. To date, safflower and safflor yellow injections have been used to treat coronary heart disease, chronic pulmonary heart disease, cerebrovascular diseases, orthopedic diseases, and diabetes mellitus. Regarding the toxicology of Carthami flos, among the side effects that have been observed are allergic reaction, spermatogenetic failure, fatty liver, and nephrotoxicity.
Keywords:
Carthami flos
; Pharmacology; Clinical applications; Side effects
Introduction
Carthami flos, the dried floret of Carthamus tinctorius L., Asteraceae (safflower), has been commonly used in traditional Chinese medicine to treat a wide range of ailments, such as coronary heart disease, angina pectoris, gynecologic disease, stroke, and hypertension. In China, Carthami flos has been used as medication for more than 2100 years, since the species was introduced by Zhang Qian in the historic "Silk Road." Traditional Chinese medicine has accumulated ponderable information on the use of Carthami flos, which has been documented in ancient manuscripts and summarized in recently published books, such as Chinese Pharmacopoeias, "Newly Revised Canon of Materia Medica," and "Medical Treasures of the Golden Chamber." Modern pharmacological investigations have substantiated that Carthami flos extracts or isolated pure components have protective effects on brain tissue, myocardial tissue, and osteoblasts, as well as antithrombotic, anti-inflammatory, and antitumor effects, which, to some degree, are tightly linked to the accounts of blood circulation promotion, blood stasis removal, and pain relief recorded in ancient Chinese documents.
Thus far, many compounds have been isolated from Carthami flos, including quinochalones, flavonoids, alkaloids, polyacetylene, aromatic glucosides, organic acids, etc. (Guo and Zhang, 1998Guo, M.L., Zhang, Z.Y., 1998. Quantitative analysis of tocopherol content in safflower oil cultivated in different area. Acad. J. Second Mil. Med. Univ. 19, 59., 2000Guo, M.L., Zhang, Z.Y., 2000. Quality evaluation on Carthamus tinctorius cultivated in different sarea. Chin. J. Chin. Mater. Med. 25, 5-7.; Zhang et al., 2004Zhang, G., Guo, M.L., Li, Y., Zhang, H.M., Su, Z.W., 2004. Study on flavonoid content of different safflower species and its hereditary stability. Chin. Tradit. Herbal Drugs 35, 1411-1414., 2005Zhang, G., Guo, M.L., Li, Y., Zhang, H.M., 2005. Study on chemical constituents of Carthamus tinctorius. Acad. J. Second Mil. Med. Univ. 26, 220-221., 2006Zhang, G., Guo, M.L., Zhang, H.M., Su, Z.W., 2006. Study on HPLC fingerprint of different species of Carthamus tinctorius. Acad. J. Second Mil. Med. Univ. 27, 280-283., 2009aZhang, Z.Z., Guo, M.L., Zhang, J.D., 2009a. Identification of AFLP fragments linked to hydroxysafflor yellow A in Flos Carthamiand conversion to a SCAR marker for rapid selection. Mol. Breeding 23, 229-237.; Asgarpanah and Kazemivash, 2013Asgarpanah, J., Kazemivash, N., 2013. Phytochemistry, pharmacology and medicinal properties of Carthamus tinctorius L.. Chin. J. Integr. Med. 19, 153-159.; Zhou et al., 2014Zhou, X.D., Tang, L.Y., Xu, Y.L., Zhou, G.H., Wang, Z.J., 2014. Towards a better understanding of medicinal uses of Carthamus tinctorius L. in traditional Chinese medicine: a phytochemical and pharmacological review. J. Ethnopharmacol. 15, 27-42.). Effective compounds or active parts of Carthami flos have been screened for pharmacological activity in vivo and in vitro, suggesting good repercussions for human health maintenance and promotion. Some compounds have been applied to clinical treatment of coronary heart disease, chronic pulmonary heart disease, cerebrovascular diseases, orthopedic diseases, and diabetes mellitus. This paper introduces the ethnopharmacological application, pharmacological properties, modern clinical application, and side effects of Carthami flos in China and thereby provides support and evidence for further investigation of its use.
Ethnopharmacological use
In traditional Chinese medicine, the application of Carthami flos in clinical treatment can be traced back to as early as 2000 years ago. The book Medical Treasures of the Golden Chamber, written by Zhang Zhongjin, documented that, when given as a cold infusion, the decoction of Carthami flos and distillate spirit (1:10) had therapeutic effects on gynecological diseases, including induction of abortion early in pregnancy, expulsion of a retained afterbirth or stillbirth, and moderation of pain during menstrual periods. Given as a major medicament portion, Carthami flos has been used as a remedy for coronary heart disease, angina pectoris, hypertension, and gynecological diseases (Guo and Zhang, 1996Guo, M.L., Zhang, H.M., 1996. Herbalogical study of Carthamus tinctorius. Chin. Med. Mat. 19, 202-203., 1999Guo, M.L., Zhang, H.M., 1999. Comparison effect of Carthamus tinctorius cultivated in different area on activating blood circulation and dissipating blood stasis. Acad. J. Second Mil. Med. Univ. 20, 27-29.). The leaves are used as a diuretic, an appetizer, and a cure for urinary discharge. Also, powder made from leaves of safflower combining with Cortex Lycii Radicis could be used to clavus after adding sesame oil to be pasty. Due to the impact of specific geographic environments, customs, and cultures, the medicinal properties and clinical applications of Carthami flos differ across various ethnic regions of China. In Mongolian and Tibetan medicine, Carthami flos is used to treat liver metabolism disorders, such as hepatomegaly, hepatic injury, xantho eyes, and heat hepatic blood (Luo, 1988Luo, B.S., 1988. Meng Yao Xue. Ethical and Medicinal Press, Beijing, pp. 218-219.). In Dai and Yi medicine, the nature of Carthami flos is similar to that in Chinese medicine, but its clinical applications are mainly aimed at treating infertility, galacturia, soft tissue injuries, and fractures (Lin et al., 2003Lin, Y.F., Yi, Z., Zhao, Y.H., 2003. Zhong Guo Dai Yi Yao Cai Se Tu Pu. Yunnan Ethical and Medicinal Press, Kunming, pp. 253.; Guan, 1993Guan, X.Z., 1993. Yi Zu Yi Yao Xue. Yuannan Ethical and Medicinal Press, Kunming, pp. 711.). Modern medical investigations have shown the activities of Carthami flos in improving oxygen supply to the heart and brain, mitigating ischemic injury, and hepatoprotection, which, to some extent, provide scientific support for the traditional medicinal theory and application of Carthami flos (Chen et al., 2012Chen, M., Zhao, P.W., Sun, Y.L., Sun, L.P., 2012. Advances in pharmacological function of Carthamus tinctorius and its essential constitutes. Global Tradit. Chin. Med. 5, 556-560.).
Pharmacological reports
Effect on brain injury
Hydroxysafflor yellow A (HSYA) (1), a major active chemical ingredient of Carthami flos, has been widely researched in China as a treatment for cerebrovascular diseases (Li et al., 2005Li, Y., Zhang, G., Guo, M.L., 2005. Assaying of HSYA in safflower and its injection. Acad. J. Second Mil. Med. Univ. 26, 587-588., 2010Li, Y.K., Wang, Z.J., Chang, H., Wang, Y., Guo, M.L., 2010. Expression of CT-wpr, screened by cDNA-AFLP approach, associated with hydroxysafflor yellow A in Carthamus tinctorius L. Biochem. Syst. Ecol. 38, 1148-1155.; Zhang et al., 2009aZhang, Z.Z., Guo, M.L., Zhang, J.D., 2009a. Identification of AFLP fragments linked to hydroxysafflor yellow A in Flos Carthamiand conversion to a SCAR marker for rapid selection. Mol. Breeding 23, 229-237.,bZhang, G., Guo, M.L., Li, R.P., Li, Y., Zhang, H.M., Su, Z.W., 2009b. A novel compound from Flos Carthami and its bioactivity. Chem. Nat. Compd. 45, 398-401.; Feng et al., 2010Feng, N., Li, Y.K., Tang, J., Zhou, L., Guo, H., Han, J., Wang, B.R., Guo, D.A., 2010. cDNA-AFLP analysis on transcripts associated with hydroxysafflor yellow A(HSYA) biosynthetic pathway in Carthamus tinctorius. Biochem. Syst. Ecol. 38, 971-980.; Tang et al., 2010Tien, Y.C., Lin, J.Y., Lai, C.H., Kuo, C.H., Lin, W.Y., Tsai, C.H., Tsai, F.J., Cheng, Y.C., Peng, W.H., Huang, C.Y., 2010. Carthamus tinctorius L. prevents LPS-induced TNFa signaling activation and cell apoptosis through JNK1/2-NFkB pathway inhibition in H9c2 cardiomyoblast cells. J. Ethnopharmacol. 130, 505-513.). Numerous studies have indicated a protective ability of HSYA (1) against brain impairment. An in vitro study corroborated that interference with HSYA (1) (0.072 mg/ml) contributed to nerve regeneration of an organotypic hippocampal slice from neonatal SD rats in normal or ischemic conditions (Qin et al., 2012aQin, Z., Wang, X.F., Ye, H., Zheng, X.B., 2012a. Effects of hydroxysafflor yellow A on nerve regeneration of the organotypic hippocampal slices from neonatal SD rats. Shi Zhen Guo Yi Guo Yao 23, 1856-1858.; Chart 1). HSYA (1) also relieved oxygen-glucose deprivation in neural stem cell injury and contributed to neurogenesis in vitro (Qin et al., 2012bQin, Z., Wang, X.F., Ye, H., Zheng, X.B., 2012b. Effects of hydroxysafflor yellow A on neurogenesis in a rat model of oxygen-glucose deprivation in hippocampal slice cultures. Int. J. Cerebrovasc. Dis. 20, 263-268.; Chart 1). Neuron damage induced by exposure to glutamate and sodium cyanide (NaCN) in cultured fetal cortical cells was significantly inhibited by HSYA (1) (Zhu et al., 2003Zhu, H., Wang, Z., Ma, C., Tian, J., Fu, F., Li, C., Guo, D., Roeder, E., Liu, K., 2003. Neuroprotective effects of hydroxysafflor yellow A: in vivo and in vitro studies. Planta Med. 69, 429-433.; Chart 1). In an in vivo study, the therapeutic effect of HSYA (1) on focal cerebral ischemia was investigated in a middle cerebral artery occlusion (MCAO) model. Beginning with a dose of 3 mg/kg, HSYA (1) suppressed thrombosis formation in MCAO rats, followed by inhibition of platelet aggregation and adjustment of PGI2/TXA2 (Zhu et al., 2003Zhu, H., Wang, Z., Ma, C., Tian, J., Fu, F., Li, C., Guo, D., Roeder, E., Liu, K., 2003. Neuroprotective effects of hydroxysafflor yellow A: in vivo and in vitro studies. Planta Med. 69, 429-433., 2005Zhu, H.B., Zhang, L., Wang, Z.H., Tian, J.W., Fu, F.H., Liu, K., Li, C.L., 2005. Therapeutic effects of hydroxysafflor yellow A on focal cerebral ischemic injury in rats and its primary mechanisms. J. Asian Nat. Prod. Res. 7, 607-613.; Chart 1). Spinal cord ischemia-reperfusion injury in rabbits was also found to improve when treated with HSYA (10 mg/kg) (Shan et al., 2010Shan, L.Q., Ma, S., Qiu, X.C., Zhou, Y., Zhang, Y., Zheng, L.H., Ren, P.C., Wang, Y.C., Fan, Q.Y., Ma, B.A., 2010. Hydroxysafflor yellow A protects spinal cords from ischemia/reperfusion injury in rabbits. BMC Neurosci. 11, 720-725.; Chart 1). An investigation of its effect on mitochondrial permeability transition pores (mtPTP) in rat brain indicated that HSYA (1) (10-80 µmol/l) inhibited Ca2+-induced swelling of mitochondria isolated from rat brains and generation of ROS. Taken together with the improved mitochondrial energy metabolism, the enhanced ATP levels, and the respiratory control ratio, it was extrapolated that HSYA (1) inhibited the opening of mtPTP by a free radical-scavenging action in the brain, which consequently may have resulted in the neuroprotective effect (Tian et al., 2008Tian, J.W., Li, G.S., Liu, Z.F., Fu, F.H., 2008. Hydroxysafflor yellow A inhibits rat brain mitochondrial permeability transition pores by a free radical scavenging action. Pharmacology 82, 121-126.). In a study by Pan et al. (2012)Pan, Y., Zheng, D.Y., Liu, S.M., Meng, Y., Xu, H.Y., Zhang, Q., Gong, J., Xia, Z.L., Chen, L.B., Li, H.Y., 2012. Hydroxysafflor yellow A attenuates lymphostatic encephalopathy-induced brain injury in rats. Phytother. Res. 26, 1500-1506., HSYA (1) (5 mg/kg, i.p.) was found to attenuate brain injury induced by lymphostatic encephalopathy, which showing alleviating neurologic deficits and cell apoptosis in the rostral ventrolateral medulla (RVLM), suppressing the impaired regulatory roles of the autonomic nervous system in cardiovascular, and preventing the decrease of endothelial nitric oxide synthase (eNOS) mRNA. Additionally, pretreatment with HSYA (1) improved spatial memory deficits and inhibited changes in the blood-brain barrier, the SOD activity, and the malondialdehyde content in brain injury induced by 12C6+ particle therapy (Gan et al., 2012Gan, L., Wang, Z.H., Ma, C.J., Li, G., 2012. Protective effects of hydroxysafflor yellow A on brain injury in mice irradiated by 300 MeV/u 12C6+ ions. Nucl. Sci. Technol. 35, 624-629.). A recent work implied that HSYA (1) has a protective effect against cerebral I/R injury, partly by reducing apoptosis through the PI3K/Akt/GSK3b signaling pathway (Chen et al., 2013aChen, Y.S., Lee, S.M., Lin, C.C., Liu, C.Y., Wu, M.C., Shi, W.L., 2013a. Kinetic study on the tyrosinase and melanin formation inhibitory activities of carthamus yellow isolated from Carthamus tinctorius L. J. Biosci. Bioeng. 115, 242-245.,bChen, L., Xiang, Y.X., Kong, L.J., Zhang, X.M., Sun, B.Z., Wei, X.B., Liu, H.Q., 2013b. Hydroxysafflor yellow A protects against cerebral ischemia-reperfusion injury by anti-apoptotic effect through PI3K/Akt/GSK3b pathway in rat. Neurochem. Res. 38, 2268-2275.; Chart 1) and decreasing nitrotyrosine formation (Sun et al., 2013Sun, L., Yang, L., Fu, Y., Han, J., Xu, Y.W., Liang, H., Cheng, Y., 2013. Capacity of HSYA to inhibit nitrotyrosine formation induced by focal ischemic brain injury. Nitric Oxide 35, 144-151.). Based on these studies, it was hypothesized that the underlying mechanisms of the protective effects of HSYA on brain injury involved a reduction of lipid peroxidation, the suppression of superoxide dismutase (SOD) and glutathione peroxidase (GSH-Px) activities, the upregulation of the expression of endothelial nitric oxide synthase (eNOS) protein, and a decrease in cell apoptosis and structural damage of nervous tissues. Recent reports have suggested that HSYA (1) protect cortical neurons from inhibiting the phosphorylation of PPARr and the expression of NR2B-containing NMDA receptors and regulating the Bcl-2 family (Yang et al., 2010Yang, Q., Yang, Z.F., Liu, S.B., Zhang, X.N., Hou, Y., Li, X.Q., Wu, Y.M., Wen, A.D., Zhao, M.G., 2010. Neuroprotective effects of hydroxysafflor yellow A against excitotoxic neuronal death partially through down-regulation of NR2B-containing NMDA receptors. Neurochem. Res. 35, 1353-1360.; Liu et al., 2012aLiu, X.M., Sun, L., Liang, H., Sun, G.R., Chen, Y., 2012a. The effects of hydroxysafflor yellow A on PPARr expression in glutamate-induced neuron damage. Zhong Guo Xian Dai Shen Jing Bing Za Zhi 12, 330-336.,bLiu, W.C., Lai, M.T., Chen, H.Y., Ho, C.Y., Man, K.M., Shen, J.L., Lee, Y.J., Tsai, F.J., Chen, Y.H., Chen, W.C., 2012b. Protective effect of Flos carthami extract against ethyleneglycol-induced urolithiasis in rats. Urol. Res. 40, 655-661.). However, whether neuronal NOS is involved in the protective effects of HSYA (1) remains to be determined in a future study. An in vitroinvestigation also confirmed that HSYA showed protective effects on neurotoxicity induced by β-amyloid in PC12 cells, as evidenced by reversed changes triggered by β-amyloid, such as a decrease in cell viability, glutathione level, mitochondrial membrane potential, and the ratio of Bcl-2/Bax protein expression, along with an increase in lactate dehydrogenase, DNA fragmentation, and the levels of malondialdehyde and intracellular reactive oxygen species. This finding suggested that HSYA (1) was a promising candidate drug for prevention and treatment of Alzheimer's disease (Kong et al., 2013aKong, S.Z., Shi, X.G., Feng, X.X., Li, W.J., Liu, W.H., Chen, Z.W., Xie, J.H., Lai, X.P., Zhang, S.X., Zhang, X.J., Su, Z.R., 2013a. Inhibitory effect of hydroxysafflor yellow A on mice skin photoaging induced by UV irradiation. Rejuv. Res. 16, 404-413.,bKong, S.Z., Xian, Y.F., Ip, S.P., Lai, X.P., Shi, X.G., Lin, Z.X., Su, Z.R., 2013b. Protective effects of hydroxysafflor yellow A on β-amyloid-induced neurotoxicity in PC12 cells. Neurochem. Res. 38, 951-960.).
Investigations on the protective effects of extracts or other compounds from Carthami flos on the nervous system have also been done. In an in vitro study, Zhao et al. (2009a)Zhao, G., Zheng, X.W., Gai, Y., Chu, W.J., Qin, G.W., Guo, L.H., 2009a. Safflower extracts functionally regulate monoamine transporters. J. Ethnopharmacol. 124, 116-124. found that all solvents extracted from Carthami flos, which contain extracts of chloroform, ethyl acetate, and n-butyl alcohol (1, 10, and 100 µg/ml, respectively), markedly enhanced both dopamine uptake by Chinese hamster ovary (CHO) cells stably expressing the dopamine transporter (DAT) and norepinephrine uptake by CHO cells expressing the norepinephrine transporter (NET), and simultaneously depressed serotonin uptake by CHO cells expressing the serotonin transporter (SERT), indicating that extracts from Carthami flos would improve neuropsychologic disorders through regulating the monoamine-transporter activity. Further, an in vitro investigation showed that N1,N5-(Z)-N10-(E)-tri-p-coumaroylspermidine (2) potently and selectively inhibited serotonin uptake in S6 cells or in synaptosomes with a reversible competitive property for 5HT uptake inhibition, mirroring its effect of improving neuropsychologic disorders through regulating serotoninergic transmission (Zhao et al., 2009bZhao, G., Gai, Y., Chu, W.J., Qin, G.W., Guo, L.H., 2009b. A novel compound N1,N5-(Z)-N10-(E)- tri-p-coumaroylspermidine isolated from Carthamus tinctorius L. and acting by serotonin transporter inhibition. Eur. Neuropsychopharm. 19, 749-758.; Chart 1). Carthamin (10 mg/kg) (3) significantly decreased the formation of malondialdehyde in mouse cerebrum and of thiobarbituric acid reactive substances and 8-hydroxy-2′-deoxyguanosine (8-OHdG) in the cerebral cortex of rats subjected to an injection of FeCl3 solution into the sensory motor cortex inhibited glutamate-induced (Hiramatsu et al., 2009Hiramatsu, M., Takahashi, T., Komatsu, M., Kido, T., Kasahara, Y., 2009. Antioxidant and neuroprotective activities of Mogami-benibana (Safflower, Carthamus tinctorius Linne). Neurochem. Res. 34, 795-805.; Chart 1). Nicotiflorin (kaempferol-3-O-rutinoside) (4), a natural flavonoid extracted from Carthami flos, showed neuroprotection in focal cerebral ischemia in vitro and in vivo, which might be attributed to the upregulation of endothelial nitric oxide synthase (eNOS) activity (Li et al., 2006aLi, R.P., Guo, M.L., Zhang, G., Xu, X.F., Li, Q., 2006a. Neuroprotection of nicotiflorin in permanent focal cerebral ischemia and in neuronal cultures. Biol. Pharm. Bull. 29, 1868-1872.,bLi, R.P., Guo, M.L., Zhang, G., Xu, X.F., Li, Q., 2006b. Nicotiflorin reduces cerebral ischemia damage and upregulates endothelial cultured rat cerebral blood vessel endothelial cells. J. Ethnopharmacol. 107, 143-150.; Chart 1). A study by Huang et al. (2007)Huang, J.L., Fu, S.T., Jiang, Y.Y., Cao, Y.B., Guo, M.L., Wang, Y., Xu, Z., 2007. Protective effects of nicotiflorin on reducing memory dysfunction, energy metabolism failure and oxidative stress in multi-infarct dementia model rats. Pharmacol. Biochem. Behav. 86, 741-748. showed that kaempferol-3-O-rutinoside (4) (30, 60, and 120 mg/kg) significantly attenuated the increase of lactic acid and malondialdehyde (MDA) contents and the decrease in LDH, Na+K+ATPase, Ca2+Mg2+ATPase, and superoxide dismutase (SOD) activity in multi-infarct dementia model rats, indicating its protective effects on reducing the memory dysfunction, energy metabolism failure, and oxidative stress that are involved in multi-infarct dementia. Additionally, postischemic treatment with kaempferol-3-O-glucoside (7.5 mg/kg) (5) showed a neuroprotective effect in focal cerebral ischemia-reperfusion rats. The mechanism of these kaempferol flavonoid effects was attributed to anti-neuroinflammatory activity by inhibiting the activation of STAT3 and NF-kB p65, including independent and dependent pathways of IkB degradation and the subsequent expression of pro-inflammatory mediators (Yu et al., 2013Yu, L., Chen, C., Wang, L.F., Kuang, X., Liu, K., Zhang, H., Du, J.R., 2013. Neuroprotective effect of kaempferol glycosides against brain injury and neuroinflammation by inhibiting the activation of NF-kB and STAT3 in transient focal stroke. PLOS ONE 8, e55839.). Nevertheless, more pharmacological evaluations in animal models relating to neurological disorders need to be considered in future studies to explain the underlying mechanisms of these compounds.
Effects on myocardial ischemia
Ethanolic extract of Carthami flos (62.5 µg/ml) has the ability to suppress JNK activity and inhibit LPS-induced TNFα activation and apoptosis in H9c2 cardiomyoblast cells (Tien et al., 2010Tien, Y.C., Lin, J.Y., Lai, C.H., Kuo, C.H., Lin, W.Y., Tsai, C.H., Tsai, F.J., Cheng, Y.C., Peng, W.H., Huang, C.Y., 2010. Carthamus tinctorius L. prevents LPS-induced TNFa signaling activation and cell apoptosis through JNK1/2-NFkB pathway inhibition in H9c2 cardiomyoblast cells. J. Ethnopharmacol. 130, 505-513.; Chart 1). In an in vivo study, the protective effects of a purified extract from Carthami flos (100, 200, 400, and 600 mg/kg body wt.) on myocardial ischemia was assessed in a model of myocardial ischemia injury induced by left anterior descending coronary artery (LAD) occlusion, which resulted in reduced infarct size and improved cardiac function (Han et al., 2009Han, S.Y., Li, H.X., Ma, X., Zhang, K., Ma, Z.Z., Tu, P.F., 2009. Protective effects of purified safflower extract on myocardial ischemia in vivo and in vitro. Phytomedicine 16, 694-702.). Further investigations have reported that this cardioprotective effect of Carthami flos extract (200 mg/kg) was not only supported by decreased levels of creatine kinase (CK) and LDH but, further, could be strengthened by adding Panax notoginseng (Burk) F.H. Chen (EPN) extract (50 mg/kg) (Han et al., 2013a>Han, Z.Q., Ba, T.D.L.G., Na, R.S., Eerdengbilige, E.D.B.L.G., 2013a. Research on influences of Mongolian medicine deduhonghua-7 powder on SOD, MDA and Na-K-ATPase activity in liver tissue of rat with chronic liver injury. Chin. Arch. Tradit. Chin. Med. 31, 1076-1078.,b>Han, S.Y., Li, H.X., Ma, X., Zhang, K., Ma, Z.Z., Tu, P.F., 2013b. Evaluation of the anti-myocardial ischemia effect of individual and combined extracts of Panax notoginseng and Carthamus tinctorius in rats. J. Ethnopharmacol. 145, 722-727.). HSYA (1) (4 or 8 mg/kg) also showed a cardioprotective effect, as evidenced by the reduced myocardial infarction size in rats with acute myocardial ischemia induced by LAD ligation (Wang et al., 2009aWang, T., Fu, F.H., Han, B., Li, G.S., Zhang, L.M., Liu, K., 2009a. Hydroxysafflor yellow A reduces myocardial infarction size after coronary artery ligation in rats. Pharm. Biol. 47, 458-462.,bWang, C.Y., Ma, H.M., Zhang, S.P., Wang, Y.F., Liu, J.T., Xiao, X.H., 2009b. Safflor yellow B suppresses pheochromocytoma cell (PC12) injury induced by oxidative stress via antioxidant system and Bcl-2/Bax pathway. N-Sarch. Pharmacol. 380, 135-142.). Whether the protective effect of HSYA (1) on myocardial ischemia injury could be enhanced by combination with EPN remains inconclusive (Fu et al., 2011Fu, J.H., Zhang, Q., Fan, C.Z., Liu, J.G., 2011. Protective effect of intravenous infusion injection of safflor yellow and hydroxyl safflor yellow A on acute myocardial ischemia injury in rats. Int. J. Tradit. Chin. Med. 33, 692-694.). Contrarily, extracellular Ca2+ influx through receptor-operated Ca2+channels and potential-dependent Ca2+channels could be blocked by crude drug of Carthami flos (Liu et al., 2005Liu, N., Yang, Y.Y., Mo, S.W., Liao, J.L., Jin, J.N., 2005. Calcium antagonistic effects of Chinese crude drugs: preliminary investigation and evaluation by 45Ca. Appl. Radiat. Isot. 63, 151-155.). A further finding showed that HSYA (1) markedly reduced Ca2+ influx on cardiac cells, as well as decreased the contractile force and heart rate in rats. Such an effect may implicate the activation of BKCa and KATP channels (Nie et al., 2012Nie, P.H., Zhang, L., Zhang, W.H., Rong, W.F., Zhi, J.M., 2012. The effects of hydroxysafflor yellow A on blood pressure and cardiac function. J. Ethnopharmacol. 139, 746-750.; Chart 1). Whether HSYA (1) could lower the peripheral resistance remains under study. Other compounds, such as N-(p-coumaroyl) serotonin (6) and N-feruroylserotonin (7), showed cardioprotective effects on isolated guinea pig Langendorff hearts subjected to normothermic global ischemia and subsequent reperfusion, speculated that this was in close association with the synthesis of high phosphorous energy, ATP, which was constituted an important part of the regulatory mechanisms involved in myocardial ischemic injury (Hotta et al., 2002Hotta, Y., Nagatsu, A., Liu, W., Muto, T., Narumiya, C., Lu, X.L., Yajima, M., Ishikawa, N., Miyazeki, K., Kawai, N., Mizukami, H., Sakakibara, J., 2002. Protective effects of antioxidative serotonin derivatives isolated from safflower against postischemic myocardial dysfunction. Mol. Cell. Biochem. 238, 151-162.). As evidenced by these findings, the mechanisms responsible for the cardioprotective effects may be partially achieved by scavenging of ROS, mediating the PI3K signaling pathway, and regulating superoxide dismutase activity and endothelial nitric oxide synthase activity.
Antithrombotic effect
The aqueous extracts of Carthami flos have been shown to be more efficient than clopidogrel against venous thrombosis and pulmonary embolism, with similar functions to carthamus yellow (Li and Wang, 2010Li, Y.H., Wang, N.S., 2010. Antithrombotic effects of Danggui, Honghua and potential drug interaction with clopidogrel. J. Ethnopharmacol. 128, 623-628.; Li et al., 2009Li, H.X., Han, S.Y., Wang, X.W., Ma, X., Zhang, K., Wang, L., Ma, Z.Z., Tu, P.F., 2009. Effect of the carthamins yellow from Carthamus tinctorius L. on hemorheological disorders of blood stasis in rats. Food Chem. Toxicol. 47, 1797-1802.; Chart 1). An HSYA (1) activity of enhancing the survival of vascular endothelial cells under hypoxia has also been found, which may be correlated with its effect on upregulation of the HIF-1a-VEGF pathway and regulation of Bcl-2/Bax (Ji et al., 2008Ji, D.B., Zhu, M.C., Zhu, B., Zhu, Y.Z., Li, C.L., Ye, J., Zhu, H.B., 2008. Hydroxysafflor yellow A enhances survival of vascular endothelial cells under hypoxia via upregulation of the HIF-1a-VEGF pathway and regulation of Bcl-2/Bax. J. Cardiovasc. Pharm. 52, 191-202.; Chart 1). A further investigation showed that HSYA (1) could protect human umbilical vein endothelial cells (HUVECs) from hypoxia-induced injury by inhibiting cell apoptosis and cell cycle arrest, partly indicating the molecular mechanism of HSYA (1) in the treatment of ischemic heart disease (Ji et al., 2009Ji, D.B., Zhang, L.Y., Li, C.L., Ye, J., Zhu, H.B., 2009. Effect of hydroxysafflor yellow A on human umbilical vein endothelial cells under hypoxia. Vasc. Pharmacol. 50, 137-145.; Chart 1). Contrarily, carthamin (3) (10 mg/l) could repair the blocked HUVEC migration and refinement of the f-actin structure caused by modeled microgravity (MMG), which would provide a new alternative for intervention in cardiovascular dysfunction apart from HSYA (1).
Anti-inflammatory effect
In a study by Wang et al. (2010)Wang, C.C., Choy, C.S., Liu, Y.H., Cheah, K.P., Li Jimmy, J.S., Wang, T.J., Yu, W.Y., Lin, C.W., Chenga, H.W., Hu, C.M., 2010. Protective effect of dried safflower petal aqueous extract and its main constituent, carthamus yellow, against lipopolysaccharide-induced inflammation in RAW264.7 macrophages. J. Sci. Food Agric. 91, 218-225., Carthami flos aqueous extract and carthamus yellow (CY) were examined regarding their effects on LPS-induced inflammatory response in a murine macrophage cell line RAW264.7 model. According to the results, aqueous extract from Carthami flos (1-1000 µg/ml) and CY (1-2000 µg/ml) suppressed the production of NO, PGE2, and IL-1β and decreased the iNOS and cyclooxygenase-2 (COX-2) protein expression levels in LPS-induced RAW264.7 macrophages. Based on the inhibition of cytosol IκB-α protein degradation and phospho-NF-κB protein expression, it was theorized that aqueous extract from Carthami flos and CY may inhibit LPS-stimulated expressions of the iNOS and COX-2 genes through the inactivation of NF-κB. As an effective part of the aqueous extract of Carthami flos, safflor yellow (SY) has shown an inhibitory effect on pulmonary fibrosis in vivo and in vitro, supported by suppressing the expression of a-smooth muscle actin (a-SMA) (Wang et al., 2011aWang, L., Jin, M., Zang, B.X., Wu, Y., 2011a. Inhibitory effect of safflor yellow on pulmonary fibrosis. Biol. Pharm. Bull. 34, 511-516.,bWang, X.H., Qin, Y.L., Yan, T., 2011b. Pharmacological research progress of Honghua injection. Acta Chin. Med. Pharmacol. 39, 109-110.; Chart 1). Regarding the anti-inflammatory action of methanol extracts of safflower (MEC), it has been reported that MEC triggered heme oxygenase-1 expression through Nrf2 (NF-E2-related factor) translocation and NF-kB activity inhibition. This potential molecular mechanism has provided other clues on the molecular mechanism underlying the anti-inflammatory action of aqueous extract from Carthami flosand CY (Jun et al., 2011Jun, M.S., Ha, Y.M., Kim, H.S., Jang, H.J., Kim, Y.M., Lee, Y.S., Kim, H.J., Seo, H.G., Lee, J.H., Lee, S.H., Chang, K.C., 2011. Anti-inflammatory action of methanol extract of Carthamus tinctorius involves in heme oxygenase-1 induction. J. Ethnopharmacol. 133, 524-530.; Chart 1). Contrarily, polysaccharides from Carthami flos were found to have immunomodulating activities that effectively activated the NF-kB signaling pathway through TLR4 and induced the production of various cytokines (IL-1, IL-6, IL-12, and IFN-γ) by peritoneal macrophages (Ando et al., 2002Ando, I., Tsukumo, Y., Wakabayashi, T., Akashi, S., Miyake, K., Kataoka, T., Nagai, K., 2002. Safflower polysaccharides activate the transcription factor NF-kB via Toll-like receptor 4 and induce cytokine production by macrophages. Int. Immunopharmacol. 2, 1155-1162.).
Recent investigations on HSYA (1) have focused on the treatment of acute lung injury (ALI). The effects of HSYA (1) on ALI have been evaluated in vitro (human alveolar epithelial A549 cells and umbilical vein endothelial cells (Eahy 926 cells)) and in vivo(LPS-induced and BLM-induced ALI mice), which all manifested that HSYA (1) ameliorated acute lung injury by suppressing both p38 MAPK (mitogen-activated protein kinase) phosphorylation and NF-κB activation, subsequently leading to a dramatic reduction in inflammatory cell infiltration and pro-inflammatory cytokine expression in lung tissue, as well as pulmonary edema and respiratory dysfunction (Sun et al., 2010Sun, C.Y., Pei, C.Q., Zang, B.X., Wang, L., Jin, M., 2010. The ability of HSYA to attenuate lipopolysaccharide-induced pulmonary inflammatory injury in mice. Phytother. Res. 24, 1788-1795.; Song et al., 2013Song, L.J., Zhu, Y., Jin, M., Zang, B.X., 2013. Hydroxysafflor yellow A inhibits lipopolysaccharide-induced inflammatory signal transduction in human alveolar epithelial A549 cells. Fitoterapia 84, 107-114.; Zhu et al., 2012Zhu, Y., Song, L.J., Zang, B.X., Bian, B.L., Jin, M., 2012. Study of hydroxysafflow yellow A to attenuate acute lung injury model of endothenal cell inflammatory factor expression induced by LPS. J. Cardiovasc. Pulmonary Dis. 31, 484-487.; Wu et al., 2012aWu, Z.Y., Jia, Y.L., Zhao, F.R., Li, P., Yi, Y.L., 2012a. Proliferation inhibition and induced differentiation effects of carthamin on Leukemic cells. An Hui Nong Ye Ke Xue 40, 5165-5166.,b>Wu, Y., Wang, L., Jin, M., Zang, B.X., 2012b. Hydroxysafflor yellow A alleviates early inflammatory response of bleomycin-induced mice lung injury. Biol. Pharm. Bull. 35, 515-522.; Chart 1). Due to the high water solubility of HSYA (1), these findings imply that HSYA (1) may target the cell membrane and then interfere with the interplay of receptors and their specific ligands (such as microbial ligands, pro-inflammatory cytokines, growth factors, etc.) to regulate downstream signal transduction pathways so as to exert its effects. However, the concrete mechanism by which HSYA alters intracellular signaling still warrants further studies.
Other compounds have anti-inflammatory effects as well. Compared with ginkgolide B (IC50 5.45 × 10-6 mol/l), saffloquinoside A (8) (10-5 mol/l) exhibited 54.3% inhibitory rate on the release of β-glucuronidase from rat polymorphonuclear neutrophils (PMN), which was induced by the platelet-activating factor (PAF), suggesting its anti-inflammatory activity (Jiang et al., 2010Jiang, J.S., He, J., Feng, Z.M., Zhang, P.C., 2010. Two new quinochalcones from the florets of Carthamus tinctorius. Org. Lett. 12, 1196-1199.).
Antitumor effect
Carthami flos has been applied in cancer adjuvant therapy in traditional medicine. Modern pharmacological experiments have confirmed the antitumor activity of Carthami flos in vitro and in vivo. Herbal extract of Carthami flos (40 mg/ml) has antiproliferative and proapoptotic effects on hepatic stellate cells, which may act by regulating the gene expression of Fas and Bcl2 pathways (Chor et al., 2005Chor, S.Y., Hui, A.Y., To, K.F., Chan, K.K., Go, Y.Y., Chan, H.L.Y., Leung, W.K., Sung, J.J.Y., 2005. Anti-proliferative and pro-apoptotic effects of herbal medicine on hepatic stellate cell. J. Ethnopharmacol. 100, 180-186.). Further in vitro experiments have shown that safflor yellow B (9) (1, 10, and 100 nmol/l) protected pheochromocytoma (PC12) cells from H2O2-induced injury and apoptosis through antioxidant and antiapoptotic mechanisms that are linked to suppressing caspase-3 activity and Bax expression and increasing Bcl-2 synthesis (Wang et al., 2009aWang, T., Fu, F.H., Han, B., Li, G.S., Zhang, L.M., Liu, K., 2009a. Hydroxysafflor yellow A reduces myocardial infarction size after coronary artery ligation in rats. Pharm. Biol. 47, 458-462.,bWang, C.Y., Ma, H.M., Zhang, S.P., Wang, Y.F., Liu, J.T., Xiao, X.H., 2009b. Safflor yellow B suppresses pheochromocytoma cell (PC12) injury induced by oxidative stress via antioxidant system and Bcl-2/Bax pathway. N-Sarch. Pharmacol. 380, 135-142.). Another in vitro study by Zhang et al. (2012aZhang, Y.B., Dong, H.Y., Zhao, X.M., Fan, L., Zou, Y., Zhang, C., Li, G., Liu, J.C., Niu, Y.C., 2012a. Hydroxysafflor yellow A attenuates carbon tetrachloride-induced hepatic fibrosis in rats by inhibiting Erk5 signaling. Am. J. Chin. Med. 40, 481-494.,b>Zhang, X.L., Cheng, X., Liu, Y., Shi, X.K., 2012b. Effects of safflower polysaccharide on gene transcription and protein express on of Bcl-2 and Bax in human hepatocarcinoma cell line SMMC-7721. Chin. J. Exp. Tradit. Med. Form. 18, 239-244.,c)Zhang, L., Yue, Y.H., Chen, Y.C., Yang, G.Z., Li, X.R., 2012c. Study on the type I allergic reaction of safflower injection. Chin. Hosp. Pharm. J. 32, 1319-1321.reported that polysaccharide S of Carthami flos (0, 0.02, 0.04, 0.08, 0.16, 0.32, 0.64, and 1.28 g/l) could restrain the proliferation of SMMC-7721 and enhance the apoptosis of SMMC-7721 in a dose- and time-dependent manner, as shown by the increased Bax expression and the decreased Bcl-2 expression and mitochondrial membrane potential. However, HSYA (1) (0.028 g/l) inhibited the growth of a transplanted BGC-823 tumor through inhibition of tumor vascularization (Xi et al., 2012Xi, S.Y., Zhang, Q., Liu, C.Y., Xie, H., Yue, L.F., Gao, X.M., 2012. Effects of hydroxy safflower yellow-A on tumor capillary angiogenesis in transplanted human gastric adenocarcinoma BGC-823 tumors in nude mice. J. Tradit. Chin. Med. 32, 243-248.). Carthamin (3) dose-dependently (10-5, 10-4, and 10-3 mol/l) induced the K562 leukemic cells to the haemoglobin end cells, the mechanism behind which remains unknown (Wu et al., 2012aWu, Z.Y., Jia, Y.L., Zhao, F.R., Li, P., Yi, Y.L., 2012a. Proliferation inhibition and induced differentiation effects of carthamin on Leukemic cells. An Hui Nong Ye Ke Xue 40, 5165-5166.,b>Wu, Y., Wang, L., Jin, M., Zang, B.X., 2012b. Hydroxysafflor yellow A alleviates early inflammatory response of bleomycin-induced mice lung injury. Biol. Pharm. Bull. 35, 515-522.). In vivo, Chang et al. (2011)Chang, J.M., Hung, L.M., Chyan, Y.J., Cheng, C.M., Wu, R.Y., 2011. Carthamus tinctorius enhances the antitumor activity of dendritic cell vaccines via polarization toward Th1 cytokines and increase of cytotoxic T lymphocytes. Evid.-Based Compl. Altern. Med. 27, 48-58. showed in vivo the antitumor activities of Carthami flos-treated dendritic cell vaccine in JC (mouse mammary adenocarcinoma) tumor-bearing mice, relevant to the polarization toward Th1 cytokines and the increase in cytotoxic T lymphocytes. This finding further supports the report regarding the effectiveness of Carthami flos in breast cancer (Loo et al., 2004Loo, W.T.Y., Cheung, M.N.B., Chow, L.W.C., 2004. The inhibitory effect of a herbal formula comprising ginseng and Carthamus tinctorius on breast cancer. Life Sci. 76, 191-200.). As determined from these studies, the mechanism responsible for the antitumor activity of Carthami flos may occur partly by suppressing caspase-3 activity and Bax expression and by increasing Bcl-2 synthesis, as well as by inhibiting tumor vascularization. Inhibition of human tyrosinase activity increased with increasing concentrations of kinobeon A (10) with the use of l-tyrosine or l-3,4-dihydroxyphenylalanine (l-DOPA) as the substrate (Kanehira et al., 2003a>Kanehira, T., Takekoshi, S., Nagata, H., Osamura, R.Y., Homma, T., 2003a. Kinobeon A as a potent tyrosinase inhibitor from cell culture of safflower: in vitro comparisons of kinobeon A with other putative inhibitors. Planta Med. 69, 465-479.,b>Kanehira, T., Takekoshi, S., Nagata, H., Matsuzaki, K., Kambayashi, Y., Osamura, R.Y., Homma, T., 2003b. A novel and potent biological antioxidant, kinobeon A, from cell culture of safflower. Life Sci. 74, 87-97.). Recent work has uncovered that carthamus yellow reduced the activity of mushroom tyrosinase in a dose-dependent manner (IC50 1.01 ± 0.03 mg/ml) and showed a mode of competitive inhibition with a Ki of 0.607 mg/ml. Moreover, carthamus yellow clearly decreased the melanin production of B16F10 melanoma cells at concentrations of 4.0 mg/ml, indicating no cytotoxicity (Chen et al., 2013aChen, Y.S., Lee, S.M., Lin, C.C., Liu, C.Y., Wu, M.C., Shi, W.L., 2013a. Kinetic study on the tyrosinase and melanin formation inhibitory activities of carthamus yellow isolated from Carthamus tinctorius L. J. Biosci. Bioeng. 115, 242-245.,bChen, L., Xiang, Y.X., Kong, L.J., Zhang, X.M., Sun, B.Z., Wei, X.B., Liu, H.Q., 2013b. Hydroxysafflor yellow A protects against cerebral ischemia-reperfusion injury by anti-apoptotic effect through PI3K/Akt/GSK3b pathway in rat. Neurochem. Res. 38, 2268-2275.). As derived from these studies, Carthami flos has the potential to become a useful skin-whitening agent or a potent natural tyrosinase inhibitor in the future.
Effect on osteoblasts
In a study by Choi et al. (2010)Choi, E.M., Kim, G.H., Lee, Y.S., 2010. Carthamus tinctorius flower extract prevents H2O2-induced dysfunction and oxidative damage in osteoblastic MC3T3-E1 cells. Phytother. Res. 24, 1037-1041., extract of Carthami flos (2-10 µg/ml) was shown to inhibit osteoclastogenesis by modulating the receptor activator of nuclear factor-kB ligand (RANKL) signaling in MC3T3-E1 cells. Recently, evaluations of the effects of other compounds on bone have been carried out. Liu et al. (2011a>Liu, B.B., Luo, C., Ouyang, L.S., Mu, S.H., Zhu, Y.X., Li, K.Y., Zhan, M.L., Liu, Z.W., Jia, Y., Lei, W.L., 2011a. An experimental study on the effect of safflower yellow on tendon injury-repair in chickens. J. Surg. Res. 169, 175-184.,b)>Liu, X.H., Li, L.Q., Lu, W.H., Lai, C.L., 2011b. Effect of safflow yellow treatment on ET, MMP-9, hs-CRP and platelet aggregation rate of patients with coronary heart disease. Chin. J. Integr. Med. Cardio-/Cerebrovasc. Dis. 9, 1036-1037. found that SY (1.6 mg/ml) promoted the repair of injured tendon in Leghorn chicken, manifested by the enhanced expression of bFGF and collagen type I protein. Also, HSYA (1) downregulated the expression of TLR4 mRNA callus osteoblasts (Lu and Tu, 2012Lu, C.Y., Tu, Y.Y., 2012. Effect of hydrosafflor yellow A on the expression of TLR4 in callus osteoblasts, endothelial cells, macrophages. Chin. J. Inform. TCM 4, 90-91.). These results may have therapeutic implications in treating osteoporosis and other bone erosive diseases, such as rheumatoid arthritis or metastasis associated with bone loss.
Other effects
HSYA (1) has been found to alleviate carbon tetrachloride (CCl4)-induced liver fibrosis in rats, in part through inhibition of hepatic stellate cell (HSC) activation and MAP kinase extracellular regulated kinase 5 (Erk5) signaling (Zhang et al., 2011Zhang, Y.B., Guo, J., Dong, H.Y., Zhao, X.M., Fan, L., Zou, Y., Zhang, C., Li, G., Liu, J.C., Niu, Y.C., 2011. Hydroxysafflor yellow A protects against chronic carbon tetrachloride-induced liver fibrosis. Eur. J. Pharmcol. 660, 438-444.,2012aZhang, Y.B., Dong, H.Y., Zhao, X.M., Fan, L., Zou, Y., Zhang, C., Li, G., Liu, J.C., Niu, Y.C., 2012a. Hydroxysafflor yellow A attenuates carbon tetrachloride-induced hepatic fibrosis in rats by inhibiting Erk5 signaling. Am. J. Chin. Med. 40, 481-494.,b>Zhang, X.L., Cheng, X., Liu, Y., Shi, X.K., 2012b. Effects of safflower polysaccharide on gene transcription and protein express on of Bcl-2 and Bax in human hepatocarcinoma cell line SMMC-7721. Chin. J. Exp. Tradit. Med. Form. 18, 239-244.,cZhang, L., Yue, Y.H., Chen, Y.C., Yang, G.Z., Li, X.R., 2012c. Study on the type I allergic reaction of safflower injection. Chin. Hosp. Pharm. J. 32, 1319-1321.; Chart 1), suggesting that HSYA (1) can target fibrogenic pathways and therefore may be a potential therapy for hepatic fibrosis. A further work has reflected that the protective effect of HSYA (1) on hepatic fibrosis induced by oxidative stress requires the activation of PPARr (Wan et al., 2013Wan, L.W., Tan, L., Wang, Z.R., Liu, S.X., Wang, Y.L., Liang, S.Y., Zhong, J.B., Lin, H.S., 2013. Preventive and therapeutic effects of Danhong injection on lipopolysaccharide induced acute lung injury in mice. J. Ethnopharmacol. 149, 352-359.; Chart 1). Regarding other compounds, carthamus red has been reported to have a hepatoprotective effect in rats with CCl4-induced liver damage, which might be mediated by induction of antioxidant defense through increased activation of the Nrf2 pathway (Wu et al., 2013Wu, S.C., Yue, Y., Tian, H., Li, Z.K., Li, X.F., He, W., Ding, H., 2013. Carthamus red from Carthamus tinctorius L. exerts antioxidant and hepatoprotective effect against CCl4-induced liver damage in rats via the Nrf2 pathway. J. Ethnopharmacol. 148, 570-578.; Chart 1).
Compared with glibenclamide, hydroalcoholic extract of Carthami flos (200 mg/kg) has an antidiabetic activity in alloxan-induced diabetic rats, as shown by their decreased fasting blood sugar, triacylglyceride, cholesterol, LDL-C, and VLDL-C levels, as well increased insulin levels (Asgary et al., 2012Asgary, S., Rahimi, P., Mahzouni, P., Madani, H., 2012. Antidiabetic effect of hydroalcoholic extract of Carthamus tinctorius L. in alloxan-induced diabetic rats. J. Res. Med. Sci. 17, 386-392.). Diabetes is usually accompanied by increased production of free radicals or impaired antioxidant defenses (Cuerda et al., 2011Cuerda, C., Luengo, L.M., Valero, M.A., Vidal, A., Burgos, R., Calvo, F.L., Martínez, C., 2011. Antioxidants and diabetes mellitus: review of the evidence. Nutr. Hosp. 26, 68-78.; Kuroki et al., 2003Kuroki, T., Isshiki, K., King, G.L., 2003. Oxidative stress: the lead or supporting actor in the pathogenesis of diabetic complications. J. Am. Soc. Nephrol. 14, 216-220.; Maritim et al., 2003Maritim, A.C., Sanders, R.A., Watkins, J.B., 2003. Diabetes, oxidative stress, and antioxidants: a review. J. Biochem. Mol. Toxicol. 17, 24-38.). Previous studies have disclosed Carthami flos constituted a good source of antioxidant compounds with free radical-scavenging potential (Choi et al., 2010Choi, Y.J., Sim, W., Choi, H.K., Lee, S.H., Lee, B.H., 2013. α-Terpineol induces fatty liver in mice mediated by the AMP-activated kinase and sterol response element binding protein pathway. Food Chem. Toxicol. 55, 129-136.; Zhao et al., 2012Zhao, T., Zhao, B.C., Wu, H.Q., Zhao, M.Z., 2012. Research progress on the protection of vascular endothelial injury by Dan-Hong injection. Chin. Med. Herald. 9, 31-33.; Hiramatsu et al., 2009Hiramatsu, M., Takahashi, T., Komatsu, M., Kido, T., Kasahara, Y., 2009. Antioxidant and neuroprotective activities of Mogami-benibana (Safflower, Carthamus tinctorius Linne). Neurochem. Res. 34, 795-805.; Kanehira et al., 2003aKong, S.Z., Shi, X.G., Feng, X.X., Li, W.J., Liu, W.H., Chen, Z.W., Xie, J.H., Lai, X.P., Zhang, S.X., Zhang, X.J., Su, Z.R., 2013a. Inhibitory effect of hydroxysafflor yellow A on mice skin photoaging induced by UV irradiation. Rejuv. Res. 16, 404-413.,b>Kanehira, T., Takekoshi, S., Nagata, H., Matsuzaki, K., Kambayashi, Y., Osamura, R.Y., Homma, T., 2003b. A novel and potent biological antioxidant, kinobeon A, from cell culture of safflower. Life Sci. 74, 87-97.; Kambayashi et al., 2005Kambayashi, Y., Takekoshi, S., Nakano, M., Shibamori, M., Hitomi, Y., Ogino, K., 2005. Kinobeon A, purified from cultured safflower cells, is a novel and potent singlet oxygen quencher. Acta Biochim. Pol. 52, 903-907.), suggesting that it could be useful in the prevention of diseases in which free radicals are implicated. Considering their effects on these lipid components and their antioxidant activity, Carthami flos and its active compounds can be assumed to be potential hypolipidemic agents that could yield considerable advantages for both the diabetic condition and the associated atherosclerosis or hyperlipidemic conditions. Recently, an in vitro study further corroborated that HSYA (1) (10-100 µmol/l) ameliorated methylglyoxal-induced injury in cultured human brain microvascular endothelial cells, as shown by the decreased expression of caspase-3 and the accumulation of advanced glycation end products. These results are reminiscent of the potential of HSYA as a novel strategy for protecting against vascular complications associated with diabetes (Li et al., 2013Li, W.L., Liu, J., He, P., Ni, Z.Z., Hu, Y.M., Xu, H.M., Dai, H.B., 2013. Hydroxysafflor yellow A protects methylglyoxal-induced injury in the cultured human brain microvascular endothelial cells. Neurosci. Lett. 549, 146-150.).
Liu et al. (2012aLiu, X.M., Sun, L., Liang, H., Sun, G.R., Chen, Y., 2012a. The effects of hydroxysafflor yellow A on PPARr expression in glutamate-induced neuron damage. Zhong Guo Xian Dai Shen Jing Bing Za Zhi 12, 330-336.,b)Liu, W.C., Lai, M.T., Chen, H.Y., Ho, C.Y., Man, K.M., Shen, J.L., Lee, Y.J., Tsai, F.J., Chen, Y.H., Chen, W.C., 2012b. Protective effect of Flos carthami extract against ethyleneglycol-induced urolithiasis in rats. Urol. Res. 40, 655-661. reported that administration of Carthami flos to ethylene glycol (EG)-fed rats led to a significant reduction in CaOx crystal formation, indicating its antilithic effect. Meanwhile, safflower yellow (50 mg/l) can protect human renal tubular epithelial cell lines (HK-2 cells) from damage by inhibiting apoptosis induced by aristolochic acid, which may be affected by suppressing the activation of caspase-3. These findings suggest that safflower yellow may be beneficial to the treatment of aristolochic acid nephropathy.
An in vivo study by Lu et al. (2008)Lu, Y., Ma, H., Liu, D., 2008. Pharmacological investigations of the unique herbal formula Menoprogen in rats: estrogenic activity and mechanism. Gynecol. Endocrinol. 24, 161-170. showed that menoprogen, a herbal formula consisting of Lycii fructus, Rehmanniae radix, Mori fructus, and Carthami flos, significantly increased the levels of serum estradiol and progesterone but reduced the levels of follicle-stimulating and luteinizing hormones in rats.
The 5a-reductase inhibitory and hair growth-promoting activities of Carthami flos ethanolic extract were tested in C57BL/6 mice, which resulted in a finasteride equivalent 5a-reductase inhibitory activity (FEA) value of 24.30 ± 1.64 mg per 1 g crude extract (Kumara et al., 2012Kumara, N., Rungseevijitprapab, W., Narkkhongc, N.A., Suttajitd, M., Chaiyasuta, C., 2012. 5a-reductase inhibition and hair growth promotion of some Thai plants traditionally used for hair treatment. J. Ethnopharmacol. 139, 765-771.). This finding may lead to new alternative medicines for hair loss prevention and treatment.
An in vitro study of the anti-gammaherpesvirus activity of n-hexane and EtOH fractions of Carthami flos extracts (iSLK-BAC16 and iSLK-puro cells) by Lee et al. (2013)Lee, H., Cho, H., Son, M., Sung, G.H., Lee, T., Lee, S.W., Jung, Y.W., Shin, Y.S., Kang, H., 2013. Dysregulation of KSHV replication by extracts from Carthamus tinctorius L. J. Microbiol. 51, 490-498. indicated that n-hexane and EtOH fractions of Carthami flos extracts critically influenced two stages of the Kaposi's sarcoma herpesvirus (KHSV) life cycle by abnormally inducing KSHV lytic reactivation and severely preventing KSHV virion release from the viral host cells. Simultaneously, the mechanism of dysregulation of KSHV replication by Carthami flos extracts may be mediated by dysregulating the cell cycle and producing strong cytotoxicity. Based on this finding, studies to gather more in vitro and in vivo evidence on the anti-gamma herpesvirus activities of Carthami flos extracts and the causes of cellular cytotoxicity are needed. In vivo, Carthami flos extract (200 and 400 mg/kg) showed similar reductions in the volume, free acidity, and total acidity of gastric secretion induced by carbachol, such as cimetidine and verapamil, indicating its antiulcerogenic effect (Mandade et al., 2012Mandade, R., Sreenivas, S.A., Wanare, R., 2012. Antiulcer screening of Carthamus tinctorius on volume and acidity of stimulated gastric secretion in rats. J. Pharmacol. Pharmacother. 3, 185-188.). As reported by Liu et al. (2005)Liu, N., Yang, Y.Y., Mo, S.W., Liao, J.L., Jin, J.N., 2005. Calcium antagonistic effects of Chinese crude drugs: preliminary investigation and evaluation by 45Ca. Appl. Radiat. Isot. 63, 151-155., Carthami flos has a natural calcium channel blocking activity, which may have contributed to its antiulcerogenic effect. Further studies to evaluate the exact mechanism of this effect are suggested. Recently, the photoprotective activity of topical HSYA (1) (100 and 200 µg per mouse) was investigated in a UV-induced photoaging mice model. The results showed clear recovery of UV-induced skin damage, which could possibly be attributed to the antioxidative property of HSYA (1) and activated by promoting endogenous collagen synthesis (Kong et al., 2013aKong, S.Z., Shi, X.G., Feng, X.X., Li, W.J., Liu, W.H., Chen, Z.W., Xie, J.H., Lai, X.P., Zhang, S.X., Zhang, X.J., Su, Z.R., 2013a. Inhibitory effect of hydroxysafflor yellow A on mice skin photoaging induced by UV irradiation. Rejuv. Res. 16, 404-413.,bKong, S.Z., Xian, Y.F., Ip, S.P., Lai, X.P., Shi, X.G., Lin, Z.X., Su, Z.R., 2013b. Protective effects of hydroxysafflor yellow A on β-amyloid-induced neurotoxicity in PC12 cells. Neurochem. Res. 38, 951-960.).
Clinical applications
Treatment of coronary heart disease
In a study by Huang (2013Huang, S.L., 2013. Effect analysis on safflower injection in the treatment of coronary heart disease. Lin Chuang Yi Xue Gong Cheng 20, 1517-1518.; Chart 2), patients with coronary heart disease (CHD) treated with safflower injection showed a decrease in hemodynamic parameters, containing the whole blood, high shear viscosity, shear whole blood viscosity, whole blood viscosity and plasma viscosity, which were lower than those of the control group treated with Salvia miltiorrhiza injection, suggesting the clinical efficacy of safflower injection in coronary heart disease. In another study, safflower injection was found to improve the clinical symptoms of angina pectoris and the electrocardiogram of CHD patients compared with groups treated only with conventional western medicine (Su and Chai, 2011Su, X.G., Chai, J.D., 2011. The clinical efficacy of safflower injection on the coronary heart disease. China Mod. Med. 18, 115-117.; Chart 2). The major active ingredient of Carthami flos, safflor yellow, has also been used to treat coronary heart disease. A study by Liu et al. (2011a>Liu, B.B., Luo, C., Ouyang, L.S., Mu, S.H., Zhu, Y.X., Li, K.Y., Zhan, M.L., Liu, Z.W., Jia, Y., Lei, W.L., 2011a. An experimental study on the effect of safflower yellow on tendon injury-repair in chickens. J. Surg. Res. 169, 175-184.,b)>Liu, X.H., Li, L.Q., Lu, W.H., Lai, C.L., 2011b. Effect of safflow yellow treatment on ET, MMP-9, hs-CRP and platelet aggregation rate of patients with coronary heart disease. Chin. J. Integr. Med. Cardio-/Cerebrovasc. Dis. 9, 1036-1037. found that safflor yellow could reduce the endothelin, matrix metalloproteinase-9, and high-sensitivity C-reactive protein of different patients with coronary artery disease (Chart 2). Other studies have shown that safflor yellow could decrease neuropeptide Y, which was important to improve the pathogenetic condition of patients (Liu et al., 2008Liu, A.G., Li, P., Wang, Q.Q., 2008. Effect of safflow yellow treatment on neuropeptide Y of patients with unstable angina. Shan Dong Yi Xue 48, 67.; Chart 2).
Treatment of chronic pulmonary heart disease
The use of safflower injection to treat heart failure in patients with chronic pulmonary heart disease (CPHD) resulted in improved heart function, as proved by the ameliorative blood gas parameters compared with the control group (p < 0.05) (Liao, 2012Liao, R.D., 2012. Application of safflower injection in the treatment of heart failure in patients with chronic pulmonary heart disease. Zhong Guo Wei Sheng Chang Ye 2, 29-30.; Chart 2). contrarily, recent studies on SY and SY injection have indicated their curative function in pulmonary heart disease. An investigation by Chen et al. (2014)Chen, Q., Liu, X.Q., Li, Q.F., Liu, L., Dou, D.C., Wang, S.H., 2014. Protective effect of safflower yellow on myocardium in patients with pulmonale plus heart failure. Xi Nan Guo Fang Yi Yao 24, 378-380. showed the efficacy of SY in improving ST segment depression (p < 0.01) and decreasing the levels of TnI, CK-MB, and CRP (p < 0.05), thereby protecting myocardial injury from CPHD (Chart 2). Meanwhile, the pulmonary function, as well as blood viscosity and rheology, of patients with CPHD was found to be ameliorated after treatment with SY injection (Ren and Mei, 2014Ren, L.X., Mei, S.Q., 2014. Clinical efficacy of safflower yellow injection in the treatment of AEC OPD patients complicated with chronic pulmonary heart disease. Lin Chuang Fei Ke Za Zhi 19, 1039-1040.; Chart 2).
Treatment of cerebrovascular diseases
Extracts and compounds from safflower have been applied with beneficial effects in the clinical treatment of cerebrovascular diseases. Systemic evaluations of the clinical effect and safety of safflower injection in the treatment of acute ischemic stroke have indicated that such injection is helpful in improving neurologic functional deficits and has a good safety profile, as shown by the meta-analysis results on total effective rates, the relative risk 99% credible region (99% CI), the number of treatments needed (99% CI), and the weight mean deviation (99% CI), which are 1.19 (1.10, 1.28), 7.14 (5.00, 12.5), and -0.62 (-1.10, -0.15), respectively (Ma et al., 2012Ma, L.H., Li, D.M., Li, K.J., 2012. Clinical effect study on ischemic stroke in acute period treated with red flower injection. J. Zhejiang Chin. Med. Univ. 36, 633-635.). The latent mechanism was partially involved in decreasing the serum ratio of IL-6/IL-10 and suppressing the lipid peroxidation by increasing the level of superoxide dismutase, choramphenicol acetyltransferase, and malondialdehyde, which were supported by clinical evidence from Luo et al. (2014Luo, C.Z., Gao, Z.Q., Jiang, J.Y., Yang, X.Y., Tang, J.P., Luo, Y., 2014. Effects of safflor injection on serum IL-6 and IL-10 level of young patients with mild acute cerebral infarction. J. Chongqing Med. Univ. 29, 463-465.; Chart 2). Also, injections of safflower yellow and HSYA have been reported to be more effective in clinical treatment of acute ischemic stroke compared with Ginkgo leaf extract and dipyridamole injection (Xiao and Hu, 2011Xiao, X., Hu, W.J., 2011. Clinical effect of HSYA injection on acute ischemic apoplexy. Med. J. West China 33, 932-936.; Xing et al., 2008Xing, Y.L., Tu, Q., Xiao, Q.F., Jiao, Y., 2008. Clinical effect of safflower yellow injection on ischemic apoplexy. Chin. Hosp. Pharm. J. 28, 1493-1495.; Chart 2).
Treatment of orthopedic diseases
Recently, clinical observations of safflower injection in orthopedic diseases have been gradually carried out, with good echo. Safflower injection for patients with acute gouty arthritis showed equal efficacy to treatment with colchicine, suggesting that safflower injection may be a new alternative treatment for acute gouty arthritis patients due to its low toxicity (Li et al., 2011Li, M.B., Yang, Q., Chen, X.Y., 2011. Clinical observation on gouty arthritis patients treated with safflower injection. China Med. Pharm. 1, 123-124.; Chart 2). A clinical report by Sui et al. (2011)Sui, J.S., Wang, L.M., Jiang, Z.C., Fei, J.L., 2011. Clinical curative effect of safflower injection after isolated limbs replantation. Xian Dai Sheng Wu Xue Jin Zhang 11, 4877-4879. pointed to the application of safflower injection in isolated limb replantation, which resulted in 95% survival of replanted fingers with no adverse effect, exceeding the 86% survival rate in the control group. An observation of its prevention of postoperative tendon adhesion in flexor tendon injury has also been conducted, which resulted in 60 patients being healed in stage I and showing an advantage over the dickon biological film group in terms of total active motion of the tendon after four weeks. No obvious discrepancy in power to grasp was observed, which was reminiscent of the apotropaic effect of safflower injection on postoperative tendon adhesion in flexor tendon injury (Choi et al., 2013Choi, Y.J., Sim, W., Choi, H.K., Lee, S.H., Lee, B.H., 2013. α-Terpineol induces fatty liver in mice mediated by the AMP-activated kinase and sterol response element binding protein pathway. Food Chem. Toxicol. 55, 129-136.).
Treatment of diabetes mellitus and its complications
In a clinical report by Wei (2011Wei, Y.J., 2011. Clinical curative analysis of safflower injection in treatment of diabetic nephropathy. China Med. Herald. 8, 218-219.; Chart 2), safflower injection was extrapolated to effectively postpone the development of renal failure caused by diabetic nephropathy on the basis of routine treatment. Similarly, the application of safflower yellow injection in diabetic nephropathy obtained beneficial results in palliating urine protein and lowering the serum creatinine level of patients (Yang et al., 2011Yang, B.Q., Yang, L.Z., Yang, X.F., Chen, B., 2011. Clinical observation on diabetic nephropathy patients treated with safflower yellow injection. Seek Med. Ask Med. 9, 147.; Chart 2; Qiu et al., 2013Qiu, T.L., Wang, X., Yuan, J., Wang, G., Wang, M., 2013. Observation on the clinical effect of safflower yellow injection in the adjuvant treatment of early diabetic nephropathy. Prog. Mod. Biomed. 13, 5975-5977.). Other complications of diabetes mellitus that could be treated with safflower yellow injection have been reported. Diabetic peripheral neuropathy, a frequent chronic complication of diabetes mellitus, could be ameliorated by safflower yellow injection, which may be implicated in amelioration of microcirculation in patients (Yang and Dai, 2010Yang, D.M., Dai, L.F., 2010. Clinical observation on 42 diabetic peripheral neuropathy patients treated with safflower yellow injection. Yun Nan Zhong Yi Zhong Yao 31, 16-17.; Chart 2). In a recent clinical observation, safflower yellow injection was found to decrease the incidence of delayed graft function and thereby improve recovery of graft function after renal transplantation (Pang et al., 2014Pang, X.L., Feng, G.W., Shang, W.J., Liu, L., Li, J.F., Feng, Y.H., Xie, H.C., 2014. Clinical observation of safflor yellow for improving renal function in early stage of renal transplantation. J. Chin. Pract. Diag. Ther. 28, 298-300.; Chart 2).
Side effects
An in vivo study of the acute toxicity of carthamus red showed no toxicity and mortality for doses of up to 2000 mg/kg (Wu et al., 2013Wu, S.C., Yue, Y., Tian, H., Li, Z.K., Li, X.F., He, W., Ding, H., 2013. Carthamus red from Carthamus tinctorius L. exerts antioxidant and hepatoprotective effect against CCl4-induced liver damage in rats via the Nrf2 pathway. J. Ethnopharmacol. 148, 570-578.). However, some side effects have been reported in animal and human models. After being given orally (by gavage method) to mice at a dose of 200 mg/kg for 35 consecutive days, Carthami flos extract engendered the formation of multinucleated giant cells in the germinal epithelium and resulted in a marked decrease in epithelial vacuolization, germ sloughing and detachment, seminiferous tubule diameter, seminiferous epithelium height, and maturation arrest, suggesting its ability to change the testis histologic structure and cause spermatogenetic failure (Mirhoseini et al., 2012Mirhoseini, M., Mohamadpour, M., Khorsandi, L., 2012. Toxic effects of Carthamus tinctorius L. (Safflower) extract on mouse spermatogenesis. J. Assist. Reprod. Gen. 29, 457-461.; Bahmanpour et al., 2012Bahmanpour, S., Vojdani, Z., Panjehshahin, M.R., Hoballah, H., Kassas, H., 2012. Effects of Carthamus tinctorius on semen quality and gonadal hormone levels in partially sterile male rats. Kor. J. Urol. 53, 705-710.). Therefore, precautions should be taken when using Carthami flos extract on men who are infertile or have reproductive disorders. Tests of active systemic anaphylaxis and passive cutaneous anaphylaxis by Carthami flos injection have shown positive reactions in guinea pigs and SD rats, respectively, indicating its sensitization to allergic reaction (Zhang et al., 2012aZhang, Y.B., Dong, H.Y., Zhao, X.M., Fan, L., Zou, Y., Zhang, C., Li, G., Liu, J.C., Niu, Y.C., 2012a. Hydroxysafflor yellow A attenuates carbon tetrachloride-induced hepatic fibrosis in rats by inhibiting Erk5 signaling. Am. J. Chin. Med. 40, 481-494.,b>Zhang, X.L., Cheng, X., Liu, Y., Shi, X.K., 2012b. Effects of safflower polysaccharide on gene transcription and protein express on of Bcl-2 and Bax in human hepatocarcinoma cell line SMMC-7721. Chin. J. Exp. Tradit. Med. Form. 18, 239-244.,c)Zhang, L., Yue, Y.H., Chen, Y.C., Yang, G.Z., Li, X.R., 2012c. Study on the type I allergic reaction of safflower injection. Chin. Hosp. Pharm. J. 32, 1319-1321.. An essential requirement for future studies is the exploration of the recessive sensibilizing substance in Carthami flos injection. With the increasing clinical application of Carthami flos, side effects have been gradually reported, such as inducing angle-closure glaucoma, throat inflammation and rhinorrhagia (Deng, 2012Deng, Y.Z., 2012. The adverse reaction of safflower injection in the clinical application. Strait. Pharm. J. 24, 228-230.). Additionally, daily intraperitoneal injection of HSYA at a dosage of 180 mg/kg for ninety days resulted in slight nephrotoxicity in SD rats (Liu et al., 2004Liu, Z.F., Li, C.M., Li, M., Li, D.L., Liu, K., 2004. The subchronic toxicity of hydroxysafflor yellow A of 90 days repeatedly intraperitoneal injections in rats. Toxicology 203, 139-143.), whereas α-terpineol induced fatty liver (Choi et al., 2013Choi, Y.J., Sim, W., Choi, H.K., Lee, S.H., Lee, B.H., 2013. α-Terpineol induces fatty liver in mice mediated by the AMP-activated kinase and sterol response element binding protein pathway. Food Chem. Toxicol. 55, 129-136.). A clinical observation also reported Carthami flos as a new cause of occupational asthma, as shown by bronchial challenges or brochial provocation tests (Compes et al., 2006Compes, E., Bartolomé, B., Fernández-Nieto, M., Sastre, J., Cuesta, J., 2006. Occupational asthma from dried flowers of Carthamus tinctorious (safflower) and Achillea millefolium(yarrow). Allergy 61, 1239-1240.). As mentioned previously, further evaluations of the systemic toxicity and safety of Carthami flos are needed.
Conclusion
The available pharmacological studies on crude extracts or identified compounds of Carthami flos provide pragmatic support for some traditional therapeutic claims. However, there are a number of issues that need to be addressed. First, the extensive pharmacological investigations on quinochalcone glycosides have predominantly focused on HSYA. Its advantages in brain tissue, myocardial tissue, diabetes mellitus, and hypertension have been reported, and different preparations have been applied in clinical practice in China. However, the underlying molecular mechanisms of action of HSYA have not been sufficiently clarified. Consequently, more rigorous experiments on in vitro and in vivosystems, as well as in human models, are required. Moreover, how to exploit other quinochalcone glycosides remains a subject of continuing study. Second, more systemic evaluations of Carthami flos in clinical applications, including treatment of coronary heart disease, chronic pulmonary heart disease, cerebrovascular diseases, orthopedic diseases, and diabetes mellitus, need to be carried out. Third, in spite of the distinguished activities of Carthami flos in some diseases, the side effects of its use should not be ignored, such as spermatogenetic failure, allergic reaction, and nephrotoxicity. Thereby, systemic toxicity and safety evaluations regarding Carthami flos are necessary. In summary, the challenge for the future of Carthami flos lies in confirming the mechanism underlying its effects and in providing brawinest clinical support.
Acknowledgements
This work was supported by the following grants: National Natural Science Foundation of China (81173484, 81473300) and (2009ZX19105-01) for scholarship and financial support.
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Publication Dates
-
Publication in this collection
Oct 2015
History
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Received
01 May 2015 -
Accepted
03 June 2015