Category Archives: Anti-tumoral

Akt, Anti-cancer, anti-inflammatory, anti-oxidant, anti-proliferative, Anti-tumoral, Anti-tumoral., apoptosis, Apoptotic, Breast cancer, Breast cancer cell lines, c-Fos, c-Myc, Caco-2, Chapter 7 Isolates and Cancer Research, chemo-preventive, Chemo-preventive effects, Colon Cancer or Colorectal cancer, ERK, growth-inhibitory, HCT-116,SW-480, Hs578T, IL-8, MDA-MB-231, metastasis, Pancreatic cancer, PancTu-I, Panc1, Panc89 and BxPC3, Rectal cancer, S, TNF

EGCG, ECG, CG, EC

April 19, 2014 brian

Cancer: Breast, pancreatic, lung, colorectal

Action: Chemo-preventive effects, metastasis

(-)-Epigallocatechin gallate (EGCG) is isolated from Camellia sinensis [(L.) Kuntze].

Epidemiological evidence suggests tea (Camellia sinensis L.) has chemo-preventive effects against various tumors. (-)-Epigallocatechin gallate (EGCG), a catechin polyphenol compound, represents the main ingredient of green tea extract and is chemo-preventive and an anti-oxidant. EGCG shows growth inhibition of various cancer cell lines, such as lung, mammary, and stomach.

Breast Cancer, Colorectal Cancer

Although EGCG has been shown to be growth-inhibitory in a number of tumor cell lines, it is not clear whether the effect is cancer-specific. The effect of EGCG on the growth of SV40 virally transformed WI38 human fibroblasts (WI38VA) was compared with that of normal WI38 cells. The IC50 value of EGCG was estimated to be 120 and 10 microM for WI38 and WI38VA cells, respectively. Similar differential growth inhibition was also observed between a human colorectal cancer cell line (Caco-2), a breast cancer cell line (Hs578T) and their respective normal counterparts.

EGCG at a concentration range of 40-200 microM induced a significant amount of apoptosis in WI38VA cultures, but not in WI38 cultures, as determined by terminal deoxynucleotidyl transferase assay. It is possible that differential modulation of certain genes, such as c-fos and c-myc, may cause differential effects of EGCG on the growth and death of cancer cells (Chen et al., 1998).

Breast Cancer

Green tea contains many polyphenols, including epigallocatechin-3 gallate (EGCG), which possess anti-oxidant qualities. Reduction of chemically-induced mammary gland carcinogenesis by green tea in a carcinogen-induced rat model has been suggested previously, but the results reported were not statistically significant. Green tea significantly increased mean latency to the first tumor, and reduced tumor burden and number of invasive tumors per tumor-bearing animal; however, it did not affect tumor number in female rats.

Furthermore, we show that proliferation and/or viability of cultured Hs578T and MDA-MB-231 estrogen receptor-negative breast cancer cell lines was reduced by EGCG treatment. Similar negative effects on proliferation were observed with the DMBA-transformed D3-1 cell line. Growth inhibition of Hs578T cells correlated with induction of p27Kip1 cyclin-dependent kinase inhibitor (CKI) expression.

Thus, green tea had significant chemo-preventive effects on carcinogen-induced mammary tumorigenesis in female S-D rats. In culture, inhibition of human breast cancer cell proliferation by EGCG was mediated in part via induction of the p27Kip1 (Kavanagh et al., 2001).

Pancreatic Cancer

The in vitro anti-tumoral properties of EGCG were investigated in human PDAC (pancreatic ductal adenocarcinoma) cells PancTu-I, Panc1, Panc89 and BxPC3 in comparison with the effects of two minor components of green tea catechins, catechin gallate (CG) and epicatechin gallate (ECG). It was found that all three catechins inhibited proliferation of PDAC cells in a dose- and time-dependent manner.

Interestingly, CG and ECG exerted much stronger anti-proliferative effects than EGCG. Importantly, catechins, in particular ECG, inhibited TNFα-induced activation of NF-κB and consequently secretion of pro-inflammatory and invasion promoting proteins like IL-8 and uPA.

Overall, these data show that green tea catechins ECG and CG exhibit potent and much stronger anti-proliferative and anti-inflammatory activities on PDAC cells than the most studied catechin EGCG (KŸrbitz et al., 2011).

Okabe et al. (1997) assessed the ability of EGCG to inhibit HGF signaling in the immortalized, nontumorigenic breast cell line, MCF10A, and the invasive breast carcinoma cell line, MDA-MB-231. The ability of alternative green tea catechins to inhibit HGF-induced signaling and motility was investigated. (-)-Epicatechin-3-gallate (ECG) functioned similarly to EGCG by completely blocking HGF-induced signaling as low as 0.6 muM and motility at 5 muM in MCF10A cells; whereas, (-)-epicatechin (EC) was unable to inhibit HGF-induced events at any concentration tested. (-)-Epigallocatechin (EGC), however, completely repressed HGF-induced AKT and ERK phosphorylation at concentrations of 10 and 20 muM, but was incapable of blocking Met activation. Despite these observations, EGC did inhibit HGF-induced motility in MCF10A cells at 10 muM.

Metastsis Inhibition

These observations suggest that the R1 galloyl and the R2 hydroxyl groups are important in mediating the green tea catechins' inhibitory effect towards HGF/Met signaling. These combined in vitro studies reveal the possible benefits of green tea polyphenols as cancer therapeutic agents to inhibit Met signaling and potentially block invasive cancer growth (Bigelow et al., 2006).

Colorectal Cancer

Panaxadiol (PD) is a purified sapogenin of ginseng saponins, which exhibits anti-cancer activity. Epigallocatechin gallate (EGCG), a major catechin in green tea, is a strong botanical anti-oxidant. Effects of selected compounds on HCT-116 and SW-480 human colorectal cancer cells were evaluated by a modified trichrome stain cell proliferation analysis. Cell-cycle distribution and apoptotic effects were analyzed by flow cytometry after staining with PI/RNase or annexin V/PI. Cell growth was suppressed after treatment with PD (10 and 20 µm) for 48 h. When PD (10 and 20 µm) was combined with EGCG (10, 20, and 30 µm), significantly enhanced anti-proliferative effects were observed in both cell lines.

Combining 20 µm of PD with 20 and 30 µm of EGCG significantly decreased S-phase fractions of cells. In the apoptotic assay, the combination of PD and EGCG significantly increased the percentage of apoptotic cells compared with PD alone (p < 0.01).

Data from this study suggested that apoptosis might play an important role in the EGCG-enhanced anti-proliferative effects of PD on human colorectal cancer cells (Du et al., 2013).

Action: Anti-inflammatory, antioxidant

Green tea catechins, especially epigallocatechin-3-gallate (EGCG), have been associated with cancer prevention and treatment. This has resulted in an increased number of studies evaluating the effects derived from the use of this compound in combination with chemo/radiotherapy. Most of the studies on this subject up to date are preclinical. Relevance of the findings, impact factor, and date of publication were critical parameters for the studies to be included in the review.

Additive and synergistic effects of EGCG when combined with conventional cancer therapies have been proposed, and its anti-inflammatory and antioxidant activities have been related to amelioration of cancer therapy side effects. However, antagonistic interactions with certain anticancer drugs might limit its clinical use.

The use of EGCG could enhance the effect of conventional cancer therapies through additive or synergistic effects as well as through amelioration of deleterious side effects. Further research, especially at the clinical level, is needed to ascertain the potential role of EGCG as adjuvant in cancer therapy.

Cancer: Pancreatic ductal adenocarcinoma

Action: Anti-proliferative and anti-inflammatory

In the present study, Kürbitz et al., (2011) investigated the in vitro anti-tumoral properties of EGCG on human PDAC (pancreatic ductal adenocarcinoma) cells PancTu-I, Panc1, Panc89 and BxPC3 in comparison with the effects of two minor components of green tea catechins catechin gallate (CG) and epicatechin gallate (ECG). We found that all three catechins inhibited proliferation of PDAC cells in a dose- and time-dependent manner. Interestingly, CG and ECG exerted much stronger anti-proliferative effects than EGCG. Western blot analyses performed with PancTu-I cells revealed catechin-mediated modulation of cell cycle regulatory proteins (cyclins, cyclin-dependent kinases [CDK], CDK inhibitors). Again, these effects were clearly more pronounced in CG or ECG than in EGCG treated cells. Importantly, catechins, in particular ECG, inhibited TNFα-induced activation of NF-κB and consequently secretion of pro-inflammatory and invasion promoting proteins like IL-8 and uPA. Overall, our data show that green tea catechins ECG and CG exhibit potent and much stronger anti-proliferative and anti-inflammatory activities on PDAC cells than the most studied catechin EGCG.

References

Bigelow RLH, & Cardelli JA. (2006). The green tea catechins, (-)-Epigallocatechin-3-gallate (EGCG) and (-)-Epicatechin-3-gallate (ECG), inhibit HGF/Met signaling in immortalized and tumorigenic breast epithelial cells. Oncogene, 25:1922–1930. doi:10.1038/sj.onc.1209227

Chen ZP, Schell JB, Ho CT, Chen KY. (1998). Green tea epigallocatechin gallate shows a pronounced growth-inhibitory effect on cancerous cells but not on their normal counterparts. Cancer Lett,129(2):173-9.

Du GJ, Wang CZ, Qi LW, et al. (2013). The synergistic apoptotic interaction of panaxadiol and epigallocatechin gallate in human colorectal cancer cells. Phytother Res, 27(2):272-7. doi: 10.1002/ptr.4707.

Kavanagh KT, Hafer LJ, Kim DW, et al. (2001). Green tea extracts decrease carcinogen-induced mammary tumor burden in rats and rate of breast cancer cell proliferation in culture. Journal of Cellular Biochemistry, 82(3):387-98. doi:10.1002/jcb.1164

KŸrbitz C, Heise D, Redmer T, et al. (2011). Epicatechin gallate and catechin gallate are superior to epigallocatechin gallate in growth suppression and anti-inflammatory activities in pancreatic tumor cells. Cancer Science, 102(4):728-734. doi: 10.1111/j.1349-7006.2011.01870.x

Okabe S, Suganuma M, Hayashi M, et al. (1997). Mechanisms of Growth Inhibition of Human Lung Cancer Cell Line, PC-9, by Tea Polyphenols. Cancer Science, 88(7):639–643. doi: 10.1111/j.1349-7006.1997.tb00431.x

Lecumberri E, Dupertuis YM, Miralbell R, Pichard C. (2013) Green tea polyphenol epigallocatechin-3-gallate (EGCG) as adjuvant in cancer therapy. Clinical Nutrition. Volume 32, Issue 6, December 2013, Pages 894–903.

Kürbitz C, Heise D, Redmer T, Goumas F, et al. Cancer Science. Online publication Jan 2011. DOI: 10.1111/j.1349-7006.2011.01870.x

Anti-tumoral, Chapter 8 Injectables and Cancer Research, Chemotherapy, chemotherapy support, CYP1A2, inhibits chemotherapy-induced cardiotoxicity, inhibits CYP activity, Nausea and Vomiting

Shenmai

April 12, 2014 brian

Cancers: Lung, stomach

Action: Anti-tumoral., chemotherapy support, inhibits CYP activity, inhibits chemotherapy-induced cardiotoxicity

Shenmai injection (SMI) is a mixture of Radix Ginseng and Radix Ophiopogonis, comprised of total ginsenoside (TG), ophiopogon total saponins (OTS), ophiopogon total flavone (OTF), ginsenoside Rd, ophiopogonin D and ophiopogonone A.

NSCLC

Forty-five NSCLC patients, with stages IIIb-IV, were randomly divided into two groups: the treatment group (treated with chemotherapy combined with Shenmai injection) and the control group (treated with chemotherapy only). There was no significant difference between the two groups in acute curative effects (P > 0.05). However, there were significant differences between them in Karnofsky score and weight (P < 0.05). The treatment group was significantly better than the control group in preventing leukopenia and decreased hemoglobin (P < 0.05). The incidence of thrombocytopenia, nausea and vomiting, hepatic, and renal dysfunction in the treatment group was lower than that in the control group.

Shenmai injection would not influence the efficacy of chemotherapy in advanced NSCLC patients. However, it could improve the quality of life, increase the body weight of patients, and alleviate adverse reactions of chemotherapy, such as myelosuppression, to improve chemotherapy tolerance (Cao, Li, & Tan, 2006).

Hepatic CYP Enzymes

These in vivo and in vitro results demonstrated that Shenmai had the potential to inhibit the activities of hepatic CYP3A1/2 and CYP2C6, but might not significantly affect CYP1A2 and CYP2E1-mediated metabolism in rats (Xia et al., 2010).

Gastric Cancer; Chemotherapy

Sixty-seven patients with gastric cancer in medium to advanced stage were randomly divided into two groups: 33 cases in the treatment group and 34 cases in the control group. The control group was treated with docetaxel, oxaliplatin and fluorouracil (DOF), while the treatment group was treated with DOF and Shenmai injection (40 mL / day). One treatment course included 21 days, and after 2 treatment courses the results were observed.

There was significant difference between the two groups (X2=4.327 6, P < 0.05). Additionally, there was statistically significant difference in the Karnofsky score (u=2.7033, P=0.008 4) and syndrome evaluation (u=2.375 9, P=0.018 0).

Shenmai injection, combined with chemotherapy, has better effect on gastric cancer in medium to advanced stage than single chemotherapy alone. It has a reliable effect on tumor mass but the benefits in regards to the rate of chemotherapy completion and Kanorfsky animation score is not definite (OR and 95% CI are over 1) (Hao, Liu, Wang, Li, & Li, 2013).

Cardiotoxicity

Six RCTs were included, totaling 615 patients (307 in the experimental group and 308 in the control group). Current evidence suggests that Shenmai injection is potentially effective in the prevention and treatment of cardiotoxicity in tumor patients induced by anthracyclines (Yang, Lu, Mou, & Xu, 2012).

NSCLC

All patients were treated with the Navelbine and Cisplatin (NP) chemotherapy, but to the treatment group the Chinese drugs Shengmai Injection by intravenous drip and Gujin Granule by oral intake were given additionally. The main observation indexes were response rate (RR), median survival time, 1-year survival rate and median time to progression (TTP); secondary observation indexes were side-effects and cycles of chemotherapy.

RR was 48.5% in the treatment group and 32.2% in the control group, and the median survival times were 13 months and 9 months, respectively. However, the differences between groups were insignificant in terms of 1-year survival rate [51.5% vs 46.4%, P=0.4042], median TTP (5.95 months vs 4.64 months, P=0.3242), grade III or IV bone marrow inhibition occurrence rate [33.3% (11/33) vs 39.3% (11/28), P=0.3500], and mean cycles of chemotherapy applied (2.94+/-0.94 cycles vs 2.75+/-0.75 cycles, P=0.4100).

Combined Chinese drugs and chemotherapy can enhance the short-termtherapeutic efficacy in the treatment of NSCLC and prolong patients” median survival time (Chen et al., 2009).

References

Cao, Y., Li, P., & Tan, K.J. (2006). Clinical observation on Shenmai injection in preventing and treating adverse reaction of chemotherapy on advanced non-small-cell lung cancer. Chinese Journal of Integrated Traditional and Western Medicine, 26(6), 550-552.

Chen YZ, Li ZD, Gao F, Zhang Y, Sun H, Li PP. (2009) Effects of combined Chinese drugs and chemotherapy in treating advanced non-small-cell lung cancer. Chin J Integr Med, 15(6):415-9.

Hao, S.L, Liu, L.K., Wang, X.X., Li, J., & Li, Y.F. (2013). Clinical research of Shenmai injection combined with chemotherapy on gastric cancer in medium-advanced stage, A Report of 33 Cases. Shaanxi Journal of Chinese Traditional Medicine, 29(2), 9-11.

Xia, C.H., Sun, J.G., Wang, G.J., Shang, L.L., Zhang, X.X., Zhang, R., Peng, Y., Wang, X.J., Hao, H.P., Xie, L., & Roberts, M.S. (2010). Herb-drug interactions: in vivo and in vitro effect of Shenmai injection, a herbal preparation, on the metabolic activities of hepatic cytochrome P450 3A1/2, 2C6, 1A2, and 2E1 in rats. Planta Medica, 76(3), 245-50. doi: 10.1055/s-0029-1186082.

Yang, M., Lu, J., Mou, J.J., & Xu, T. (2012). Systematic review of Shenmai injection for cardiotoxicity induced by anthracyclines. Chinese Journal of Pharmacovigilance, 9(11), 666-669.

angiogenesis, anti-apoptotic, Anti-cancer, anti-tumor, Anti-tumoral, apoptosis, Apoptotic, Bcl-2, Chapter 8 Injectables and Cancer Research, Chemotherapy, chemotherapy support, EGFR, epidermal growth factor receptor, Esophageal cancer, Fas/APO-1, FasL, IKK, IL-1, IL-2, immunomodular, Liver cancer, Lung cancer, Lymphoma, MDR, metastasis, Pro-apoptotic, radiation support, radiotherapy

Kanglaite injection (KLT)

April 12, 2014 brian

Cancer: Lung, stomach, liver, kidney, breast, nasopharynx, esophagus, pancreas, colon-rectum, ovarian, prostate, lymphoma, leukemia

Action: Anti-tumoral, immunomodular, chemotherapy support, radiation support

Ingredients: yi yi ren (Coix Lacryma-jobi seed oil, CLSO).

Indications: primary NSCLC and primary liver cancer, which are not suitable for surgery, of qi and yin deficiency, lingering “Dampness due to Spleen deficiency types”. It has synergic effect when combined with radiotherapy or chemotherapy. It has certain anti-cachexia and analgesic effects for middle or late-stage tumor patients.

Dosage and usage:

Slow intravenous drip: 200 ml, once daily, 21 days as a course of treatment with 3-5 days interval.

When combined with radiotherapy or chemotherapy, the dosage can be reduced according to the practical conditions. (Drug Information Reference in Chinese, 2000. See end).

Invented by the famous pharmacological professor, Prof. Li Dapeng, Kanglaite Injection (KLT) has been listed by the Chinese government as a “State Basic Drug”, a “State Basic Medical Insurance Drug” and a “State Key New Drug”.

Based on pre-clinical studies at John Hopkins University, USA, tumor-inhibitive rate of KLT on transplanted breast carcinoma induced by cell strain MDA-MB-231 was over 50%. KLT could inhibit the expression of COX2 of the strain in vitro and act as an inhibitor of fatty acid synthase.

The broad ranged basic studies in China also revealed KLT different mechanisms such as inducing cancer cell apoptosis, inhibiting angiogenesis, reversing MDR and regulating gene expression of Fas/Apo-1 and Bcl-2.

Both Chinese and overseas clinical experiences have shown that KLT has proven effect in the treatment of cancers mainly at the sites of lung, breast, liver, nasopharynx, esophagus, stomach, pancreas, kidney, colon-rectum, ovary and prostate. This agent is also applied in the treatment of malignant lymphoma and acute leukemia. KLT has brought great benefits to over 500,000 cancer patients in more than 2,000 big or medium hospitals in China since 1997.

The year 1995 witnessed KLT patent certificates granted from China and the USA. In August 1997 the phase III clinical study was successfully completed and the injection was officially launched in China after final approval from the Ministry of Public Health.

Doctors in America carried out a phase 1 study of Kanglaite in 2003. They gave it to 16 people who had different types of cancer including lung, prostate and oesophageal cancers. The results showed people did not have many side-effects but the effect on their cancer varied. Some people showed no response, and their cancers continued to grow. But in others, the cancer stopped growing for a few months.

Standard treatment course for KLT is 200 ml (2 bottles) per day via intravenous drip x 42 days (84 bottles). There is a break for 4-5 days after 21 days. Clinical experiences in China and Russia suggest 2 treatment courses for those with late stage advanced and metastatic tumors for better therapeutic effect and evident prolongation of life (Conti, n.d.).

A consecutive cohort of 60 patients was divided into two groups, the experimental group receiving Kanglaite” Injection combined with chemotherapy and the control group receiving chemotherapy alone. After more than two courses of treatment, efficacy, quality of life and side-effects were evaluated. The response rate and KPS score of the experimental group were significantly improved as compared with those of the control group(P<0.05). In addition, gastrointestinal reactions and bone marrow suppression were significantly lower than in the control group(P<0.05). Kanglaite” Injection enhanced efficacy and reduced the side-effects of chemotherapy, improving quality of life of gastric cancer patients (Zhan et al., 2012).

Lung Cancer

C57BL/6 mice with Lewis lung carcinoma were divided into four groups: the control group (C), cisplatin group (1 mg/kg, DDP), low KLT group (6.25 ml/kg body weight [L]), and high KLT group (12.5 ml/kg body weight [H]). T cell proliferation was determined by the MTT assay. Nuclear factor-kappa B (NF-κB), inhibitor kappa B alpha

(IκBα), IκB kinase (IKK) and epidermal growth factor receptor (EGFR) levels were measured by western blotting. An enzyme-linked immunosorbent assay was used to analyze the expression of interleukin-2 (IL-2).

Intraperitoneal KLT significantly inhibited the growth of Lewis lung carcinoma, and the spleen index was significantly higher in the L and H groups than in the C group. KLT stimulated T cell proliferation in a dose-dependent manner. Treatment with KLT at either 6.25 or 12.5 ml/kg decreased the level of NF-κB in the nucleus in a dose-dependent manner, and KLT markedly decreased the expression of IκBα, IKK and EGFR in the cytoplasm of tumor cells and overall. IL-2 was significantly increased in the supernatant of splenocytes in the H group.

These results demonstrate that KLT has pronounced anti-tumor and immunostimulatory activities in C57BL/6 mice with Lewis lung carcinoma. These may affect the regulation of NF-κB/IκB expression, in addition to cytokines such as IL-2 and EGFR. Further work needs to investigate the relevant signaling pathway effects, but our findings suggest that KLT may be a promising anti-tumor drug for clinical use (Pan et al., 2012).

Skin Keratinocytes

Ultraviolet (UV) radiation plays an important role in the pathogenesis of skin photoaging. Depending on the wavelength of UV, the epidermis is affected primarily by UVB. One major characteristic of photoaging is the dehydration of the skin. Membrane-inserted water channels (aquaporins) are involved in this process. In this study we demonstrated that UVB radiation induced aquaporin-3 (AQP3) down-regulation in cultured human skin keratinocytes. Kanglaite is a mixture consisting of extractions of Coix Seed, which is an effective anti-neoplastic agent and can inhibit the activities of protein kinase C and NF-κB. We demonstrated that Kanglaite inhibited UVB-induced AQP3 down-regulation of cultured human skin keratinocytes. Our findings provide a potential new agent for anti-photoaging (Shan et al., 2012).

Hepatocellular Carcinoma

KLT produced an obvious time and dose-dependent inhibitory effect on HepG2 cells, and marked apoptosis was detected by FCM. The protein of Fas increased by 11.01%, 18.71%, 28.71% and 37.15%; the protein of FasL increased by 1.49%, 1.91%, 3.27% and 3.38% in comparison with the control (P<0.05). Real-time fluorescent quantitative RT-PCR showed that treating HepG2 cells with KLT caused the up-regulation of Fas and FasL mRNA. KLT inhibits HepG2 growth by inducing apoptosis, which may be mediated through activation of the Fas/FasL pathway (Lu et al., 2009).

Glomerular Nephritis

MTT, telomere repeat amplification protocol (TRAP), ELISA, PAGE and silver-stain were applied to detect the growth rate and telomerase activity of mesengial cell (MC) after stimulation of Kang Lai Te (KLT) and IL-1. The growth rate of MC was enhanced by IL-1 stimulation, which was accompanied with a reduction of the activity of telomerase. Adversely, the growth rate of MC was reduced by KLT, which was accompanied with an enhancement of activity of telomerase. Moreover, the growth rate of MC and the activity of telomerase were both inhibited by the combinative use of IL-1 and KLT without any influence from the sequence of their administration. KLT could inhibit proliferation and telomerase activity of MC with or without pre-stimulation with IL-1. KLT might be useful to prevent and treat glomerular nephritis related to MC proliferation (Hu et al., 2005).

Lung Metastasis

To screen the differential expression genes of Kanglaite in anti-tumor metastasis mRNA was extracted and purified from the lung of the mouse with LA795 lung metastasis, and hybridized respectively on 4 096-gene chip. cDNA microarray was scanned for the fluorescent signals and analyzing difference expression. Twenty-seven differential expressed genes were obtained.

Among these genes, 25 were up-regulated and 2 were down-regulated. Twelve of them were Mus musculus cDNA clone. Six genes related with genesis, development and metastasis of tumor. cDNA microarray for analysis of gene expression patterns is a powerful method to identify differential expressed genes. In this study, 6 genes are thought to be associated genes of Kanglaite in anti-tumor metastasis (Wu et al., 2003).

Lung Cancer; Chemo Side Effects

Sixteen reports were included in the meta-analysis. The quality of 16 studies was low. Pooling data of 5 studies indicated that the effect of Kanglaite+NP (Vinorelbine+Cisplatin) was better than NP with RR 1.46, 95% Confidence Interval 1.13 to 1.91. Pooling data of 3 studies of MVP (Mitomycin+Vindsine+ Cisplatin) plus Kanglaite indicated that the effect was better with RR 1.84, 95%CI 1.22 to 2.76. Pooling data of 2 studies showed that the effect of GP (Gemcitabine+Cisplatin) plus Kanglaite was better than GP with RR 1.63, 95%CI 1.09 to 2.43.

Fourteen studies revealed that Kanglaite may reduce the side-effects induced by regular treatment. Ten studies showed regular treatment plus Kanglaite can stabilize/improve quality of life (Zhu et al., 2009).

Apoptosis

Some studies show Kanglaite could inhibit some anti-apoptotic genes and activate some pro-apoptotic genes. Its injection solution is one of the new anti-cancer medicines that can significantly inhibit various kinds of tumor cells, so it has become the core of research into how to further explore KLT injection to promote tumor cell apoptosis by impacting on related genes (Lu et al., 2008).

References

Conti, M. (n.d.). Anti-cancer Chinese herbal kanglaite. Cancer Evolution. Retrieved from: http://www.cancerevolution.info/cancer-therapies/alternative-therapies/83-anticancer-chinese-herbal-kanglaite.html.

Hu, Y,H., Liang, W.K. Gong, Z.F. Xu,Q.L. Zou. (2005). The effect of kanglaite injection (KLT) on the proliferation and telomerase activity of rat mesangial cells. Zhongguo Zhong Yao Za Zhi, 30(6):450-453.

Lu, Y., Li, C.S., Dong, Q. (2008) Chinese herb related molecules of cancer-cell-apoptosis: a mini-review of progress between Kanglaite injection and related genes. J Exp Clin Cancer Res, 27:31. doi: 10.1186/1756-9966-27-31.

Lu, Y., L.Q. Wu, Q. Dong,C.S. Li. (2009). Experimental study on the effect of Kang-Lai-Te induced apoptosis of human hepatoma carcinoma cell HepG2. Hepatobiliary Pancreat Dis Int, 8(3):267-272.

Pan, P.,Y. Wu,Z.Y. Guo,R. et al. (2012). Anti-tumor activity and immunomodulatory effects of the intraperitoneal administration of Kanglaite in vivo in Lewis lung carcinoma. J Ethnopharmacol, 143(2):680-685.

Shan, S.J., Xiao T., Chen J., et al. (2012). Kanglaite attenuates UVB-induced down-regulation of aquaporin-3 in cultured human skin keratinocytes. Int J Mol Med, 29(4):625-629.

Wu, Y., Yang Y., Wu D. (2003). Study on the gene expression patterns of Kanglaite in anti-lung metastasis of LA795 mouse. Zhongguo Fei Ai Za Zhi, 6(6):473-476.

Zhan, Y.P., Huang X.E., Cao J. (2012). Clinical safety and efficacy of Kanglaite(R) (Coix Seed Oil) injection combined with chemotherapy in treating patients with gastric cancer. Asian Pac J Cancer Prev, 13(10):5319-5321.

Zhu, L.Z. Yang, S. Wang, Y. Tang. (2009). Kanglaite for Treating Advanced Non-small-cell Lung Cancer: A Systematic Review. Zhongguo Fei Ai Za Zhi, 12(3):208-215.

Akt, angiogenesis, Anti-angiogenic, Anti-cancer, anti-inflammatory, Anti-metastatic, Anti-tumoral, Anti-tumoral., AP-1, Apoptotic, Breast cancer, c-Jun, Chapter 8 Injectables and Cancer Research, chemo-preventive, Chemoprevention, Colon Cancer or Colorectal cancer, COX-2, ERK1, inflammation, Melanoma, p38, PKC, Prostate cancer, Skin cancer

Carnosol

April 11, 2014 brian

Cancer: Breast, prostate, skin, colon, leukemia, stomach

Action: Anti-inflammatrory, anti-angiogenic

Carnosol is found in certain Mediterranean meats, fruits, vegetables, and olive oil. In particular, it is sourced from rosemary (Rosmarinus officinalis (L.)) and desert sage (Salvia pachyphylla (Epling ex Munz)).

Prostate Cancer, Breast Cancer, Skin Cancer, Colon Cancer, Leukemia

One agent, carnosol, has been evaluated for anti-cancer property in prostate, breast, skin, leukemia, and colon cancer with promising results. These studies have provided evidence that carnosol targets multiple deregulated pathways associated with inflammation and cancer that include nuclear factor kappa B (NFκB), apoptotic related proteins, phosphatidylinositol-3-kinase (PI3 K)/Akt, androgen and estrogen receptors, as well as molecular targets. In addition, carnosol appears to be well tolerated in that it has a selective toxicity towards cancer cells versus non-tumorigenic cells and is well tolerated when administered to animals.

This mini-review reports on the pre-clinical studies that have been performed to date with carnosol describing mechanistic, efficacy, and safety/tolerability studies as a cancer chemoprevention and anti-cancer agent (Johnson, 2011).

Literature evidence from animal and cell culture studies demonstrates the anti-cancer potential of rosemary extract, carnosol, carnosic acid, ursolic acid, and rosmarinic acid to suppress the development of tumors in several organs including the colon, breast, liver, stomach, as well as melanoma and leukemia cells (Ngo et al., 2011).

Anti-inflammatory

Treatment with retinoic acid (RA) or carnosol, two structurally unrelated compounds with anti-cancer properties, inhibited phorbol ester (PMA)-mediated induction of activator protein-1 (AP-1) activity and cyclooxygenase-2 (COX-2) expression in human mammary epithelial cells. Treatment with carnosol but not RA blocked increased binding of AP-1 to the COX-2 promoter. Carnosol but not RA inhibited the activation of PKC, ERK1/2, p38, and c-Jun NH2-terminal kinase mitogen-activated protein kinase. Overexpressing c-Jun but not CBP/p300 reversed the suppressive effect of carnosol on PMA-mediated stimulation of COX-2 promoter activity.

Carnosol inhibited the induction of COX-2 by blocking PKC signaling and thereby the binding of AP-1 to the CRE of the COX-2 promoter. Taken together, these results show that small molecules can block the activation of COX-2 transcription by distinct mechanisms (Subbaramaiah, 2002).

Breast Cancer

Two rosemary components, carnosol and ursolic acid, appear to be partly responsible for the anti-tumorigenic activity of rosemary. Supplementation of diets for 2 weeks with rosemary extract (0.5% by wt) but not carnosol (1.0%) or ursolic acid (0.5%) resulted in a significant decrease in the in vivo formation of rat mammary DMBA-DNA adducts, compared to controls. When injected intraperitoneally (i.p.) for 5 days at 200 mg/kg body wt, rosemary and carnosol, but not ursolic acid, significantly inhibited mammary adduct formation by 44% and 40%, respectively, compared to controls. Injection of this dose of rosemary and carnosol was associated with a significant 74% and 65% decrease, respectively, in the number of DMBA-induced mammary adenocarcinomas per rat, compared to controls. Ursolic acid injection had no effect on mammary tumorigenesis.

Therefore, carnosol is one rosemary constituent that can prevent DMBA-induced DNA damage and tumor formation in the rat mammary gland, and, thus, has potential for use as a breast cancer chemopreventative agent (Singletary et al., 1996).

Anti-angiogenic

The anti-angiogenic activity of carnosol and carnosic acid could contribute to the chemo-preventive, anti-tumoral and anti-metastatic activities of rosemary extracts and suggests that there is potential in the treatment of other angiogenesis-related malignancies (L-pez-JimŽnez et al., 2013).

References:

Johnson JJ. (2011). Carnosol: A promising anti-cancer and anti-inflammatory agent. Cancer Letters, 305(1):1-7. doi:10.1016/j.canlet.2011.02.005.

L-pez-JimŽnez A, Garc'a-Caballero M, Medina Mç, Quesada AR. (2013). Anti-angiogenic properties of carnosol and carnosic acid, two major dietary compounds from rosemary. Eur J Nutr, 52(1):85-95. doi: 10.1007/s00394-011-0289-x.

Ngo SN, Williams DB, Head RJ. (2011). Rosemary and cancer prevention: preclinical perspectives. Crit Rev Food Sci Nutr, 51(10):946-54. doi: 10.1080/10408398.2010.490883.

Singletary K, MacDonald C & Wallig M. (1996). Inhibition by rosemary and carnosol of 7,12-dimethylbenz[a]anthracene (DMBA)-induced rat mammary tumorigenesis and in vivo DMBA-DNA adduct formation. Cancer Letters, 104(1):43-8. doi: 10.1016/0304-3835(96)04227-9

Subbaramaiah K, Cole PA, Dannenberg AJ. (2002). Retinoids and Carnosol Suppress Cyclooxygenase-2 Transcription by CREB-binding Protein/p300-dependent and -independent Mechanisms. Cancer Res, 62:2522

Anti-cancer, Anti-tumoral, Breast cancer, cell-cycle arrest, Chapter 8 Injectables and Cancer Research, Chemotherapy, chemotherapy support, Esophageal cancer, G0/G1, G1, Gastric cancer or Stomach cancer, Glioblastoma, KIP1, Liver cancer, Lung cancer, MAPK, Nasopharyngeal cancer, Nausea and Vomiting, p27, p38, radiotherapy, VEGF, VEGF

β-Elemene

April 11, 2014 brian

Cancer: Lung, malignant ascites, glioblastoma, gastric

Action: Anti-tumoral., chemotherapy support

Ingredients: Mixed liquid of β-, γ-, δ-elemene.

Indications: Increases the therapeutic effect and lowers the toxic and side-effects of radiotherapy and chemotherapy when in combination with routine regiments of radiotherapy or chemotherapy for lung cancer, liver cancer, esophageal cancer, nasopharyngeal cancer, brain tumors, metastatic bone cancer and other malignancies. It can also be used for intervention, intracavitary chemotherapy and pleural effusion or ascites caused by cancer.

Dosage and usage:

Intravenous injection: 0.4-0.6 g, once daily, 2-3 weeks as a course of treatment.

Pleural injection: 300 ml + 10 ml of 2% procaine. The treatment can be repeated once after 5-7 days if the pleural effusion does not reduce.

Abdominal injection: 500 ml + 10 ml of 2% procaine, 1-2 times every week for 2 consecutive weeks.

Topical administration: 25-50 mg, once daily, 5-10 times as a course of treatment.

Arterial infusion: 300-400 mg once.

Elemene Injection is made from mixed liquid of β-, γ-, δ-elemene. It can increase the therapeutic effect and lower the toxicity and side-effects of radiotherapy and chemotherapy when combined with routine regiments of radiotherapy or chemotherapy for lung cancer, liver cancer, esophageal cancer, nasopharyngeal cancer, brain tumors, metastatic bone cancer and other malignancies. It can also be used for intervention, intraperitoneal chemotherapy, and pleural effusion or ascites caused by cancer (Drug Information Reference in Chinese: See end. 2000-12).

NSCLC; Chemotherapy

Randomized controlled trials (RCTs) of elemene injection combined with cisplatin chemotherapeuties in treating small cell lung cancer (NSCLC) were collected by Xu et al., (2013). Their meta-analysis results suggested that compared with cisplatin chemotherapy alone, the combination of elemene injection and cisplatin chemotherapeutics showed a higher clinical benefit rate (OR = 2. 03, 95% CI:1.43-2. 88, P <0. 000 1) and a better quality of life (OR = 3.23, 95% CI:2. 20-4. 74, P <0. 000 01). As well, the combination could also reduce leucopenia (OR =0. 50, 95% CI:0. 33-0. 76, P <0. 001), and thrombocytopenia (OR =0. 38, 95% CI:0. 16-0. 85, P <0. 02), increase CD4 (MD = 3.32, 95% C1:2. 94-3.70, P <0. 000 01), and CD4/CD8 (MD = 0. 36, 95% CI:0. 28-0. 44, P < 0. 000 01), and relieve gastrointestinal reactions such as nausea and vomiting (OR = 0. 37, 95% CI: 0. 19-0. 71, P = 0. 003).

The analysis indicates that elemene can enhance the chemotherapeutic effect on NSCLC, improve the quality of life, and reduce adverse effect of platinum-contained chemotherapeutics, thereby being worth promoting in clinic.

Lung Cancer

Randomized controlled clinical trials related to the use of β>-elemene injection, as an adjunctive treatment for lung cancer, were retrieved from the Chinese Biomedical (CBMweb), Chinese Medical Current Content (CMCC), China National Knowledge Infrastructure (CNKI), ChinaInfo, Cochrane Central Register of Controlled Trials; MEDLINE, EMBASE, OVID and TCMLARS databases.

A total of 21 source documents (1,467 patients) matched pre-specified criteria for determining the effectiveness and safety of β>-elemene injection as an adjunctive treatment for lung cancer. Five studies involving 285 NSCLC patients reported a higher 24-month survival rate (39.09%) with the adjunctive treatment than with chemotherapy alone (26.17%; RR, 1.51; 95% CI, 1.03 to 2.21). Four studies involving 445 patients reported that the increased probability for improved performance status for patients treated with elemene-based combinations was higher than that of patients treated with chemotherapy alone (RR, 1.82; 95% CI, 1.45 to 2.29).

The results from a subgroup analysis on 12 studies involving 974 NSCLC patients and 9 studies involving 593 patients with both SCLC and NSCLC showed that the tumor control rate for NSCLC improved more in the elemene-based combinations treatment group (78.70%) than in the chemotherapy alone control group (71.31%; RR, 1.06; 95% CI, 1.00 to 1.12). The tumor response rate for NSCLC also improved more among patients treated with elemene based combinations (50.71%) than among patients treated with chemotherapy alone (38.04%; RR, 1.34; 95% CI, 1.17 to 1.54). The effectiveness of chemotherapy for the treatment of lung cancer may improve when combined with β-elemene injection as an adjunctive treatment. The combined treatment can result in an improved quality of life and prolonged survival (Wang et al., 2012).

Malignant Ascites

The effective combination therapy for malignant ascites, the therapeutic value of the combination of Endostar, a modified recombinant human endostatin, and β-elemene, an active component of a traditional Chinese herb, in an H22 mouse malignant ascites model was investigated by Jiang et al. (2012). The results of this study revealed that the combination therapy had significant synergistic effects on the inhibition of ascites formation and a deceased number of tumor cells and protein levels in ascites compared with the results of treatment with a single agent. A decreased peritoneal microvascular permeability and reduction in VEGF, MMP-2 and hypoxia inducible factor 1α(HIF1α) was noted in the combination group, when compared with single agent treatment.

These studies found that in the ascitic tumor cells, the protein levels of VEGF and MMP-2, as well as levels of VEGF mRNA, were significantly inhibited by the combination therapy. The potentiating effects of the combination of Endostar with β-elemene suggest that this novel therapy may yield an effective therapy for the treatment of malignant ascites.

Glioblastoma

Anti-proliferation of glioblastoma cells induced by beta-elemene was dependent on p38 MAPK activation. Treatment of glioblastoma cell lines with beta-elemene, led to phosphorylation of p38 MAPK, cell-cycle arrest in G0/G1 phase and inhibition of proliferation of these cells. Inhibition of p38 MAPK reversed beta-elemene-mediated anti-proliferation effect. Furthermore, the growth of glioblastoma cell-transplanted tumors in nude mice was inhibited by intraperitoneal injection of beta-elemene (Yao et al., 2008).

Breast Cancer; Chemotherapy

Beta-elemene had synergistic effect with Paclitaxel, and its possible mechanism might be correlated with down-regulating the cell-cycle protein cyclin-B1 expression and up-regulating the P27(kip1) expression. Beta-elemene (20 and 40 microg/mL respectively) and Paclitaxel (0.016 and 0.008 microg/mL respectively) synergistically inhibited cell proliferation of MB-468 breast cancer cells, with Q value > 1.15. Beta-elemene alone (52.59 microg/mL) apparently decreased the expression of cyclin-B1 protein. The expression of cyclin-B1 protein in the combined group was also lower than that in the PI group (1.698 microg/mL). The expression of P27(kip1) was up-regulated when compared with that in the betaI group or the PI group (Cai et al., 2013).

Gastric Cancer

TCM therapy applied in the 34 patients assigned in the TCM group (group I) included intravenous injection of Cinobufotalin, beta-elemene, or orally taking of anti-cancer Chinese herbs. The same TCM was also applied in the 36 patients of the combined treatment group (group II), but in combined use of FOLFOX chemotherapeutic protocol.

The median survival period in group II was 31 months, while it was 30 months in group I; the 1-, 2-, 3-year survival rates in group II were 88.89%, 84.38% and 59.26%, and those in the group I were 82.35%, 71.43% and 65.00%, respectively with insignificant difference between the two groups (chi2 = 0.298, P > 0.05); QOF in group I was significantly superior to that in group II (P < 0.05), and the adverse reaction occurrence was significantly less in group I than that in group II.

Chinese medicine treatment can improve the QOF and prolong the survival period of patients with progressive gastric cancer with few side-effects (Liu et al., 2008).

References

Jiang, Z.Y., Qin, S.K., Yin, X.J., Chen, Y.L., Zhu, L. (2012). Synergistic effects of Endostar combined with β-elemene on malignant ascites in a mouse model. Exp Ther Med, 4(2):277-284.

Liu X, Hua BJ. (2008). Effect of traditional Chinese medicine on quality of life and survival period in patients with progressive gastric cancer. Zhongguo Zhong Xi Yi Jie He Za Zhi, 28(2):105-7.

Wang, B., Peng, X.X., Sun, R., Li, J., Zhan, X.R., Wu, L.J., Wang, S.L., & Xie, T. (2012). Systematic review of β-elemene injection as adjunctive treatment for lung cancer. Chinese Journal of Integrative Medicine, 18(11), 8313-823.

Xu, X.W., Yuan, Z.Z., Hu, W.H., Wang, X.K. (2013). Meta-analysis on elemene injection combined with cisplatin chemotherapeutics in treatment of non-small-cell lung cancer. Zhongguo Zhong Yao Za Zhi, 38(9):1430-7.

Yao, Y.Q., Ding, X., Jia, Y.C, et al. (2008). Anti-tumor effect of beta-elemene in glioblastoma cells depends on p38 MAPK activation. Cancer Lett, 264(1):127-34. doi: 10.1016/j.canlet.2008.01.049.

Anti-tumoral, Chapter 7 Isolates and Cancer Research, Chemotherapy, chemotherapy support, Lung cancer

β-Elemene

April 11, 2014 brian

Cancer: Lung

Action: Anti-tumoral., chemotherapy support

Lung Cancer

Randomized controlled clinical trials related to the use of β-elemene injection, as an adjunctive treatment for lung cancer, were retrieved from the Chinese Biomedical (CBMweb), Chinese Medical Current Content (CMCC), China National Knowledge Infrastructure (CNKI), ChinaInfo, Cochrane Central Register of Controlled Trials; MEDLINE, EMBASE, OVID and TCMLARS databases.

A total of 21 source documents (1,467 patients) matched pre-specified criteria for determining the effectiveness and safety of β-elemene injection as an adjunctive treatment for lung cancer. Five studies involving 285 NSCLC patients reported a higher 24-month survival rate (39.09%) with the adjunctive treatment than with chemotherapy alone. Four studies involving 445 patients reported that the increased probability for improved performance status for patients treated with elemene-based combinations was higher than that of patients treated with chemotherapy alone. The results from a subgroup analysis on 12 studies involving 974 NSCLC patients and 9 studies involving 593 patients with both SCLC and NSCLC showed that the tumor control rate for NSCLC improved more in the elemene-based combinations treatment group than in the chemotherapy alone control group. The tumor response rate for NSCLC also improved more among patients treated with elemene based combinations (50.71%) than among patients treated with chemotherapy alone.

The effectiveness of chemotherapy for the treatment of lung cancer may improve when combined with β-elemene injection as an adjunctive treatment. The combined treatment can result in an improved quality of life and prolonged survival (Wang et al., 2012).

Reference

Wang B, Peng XX, Sun R, Li J, Zhan XR, Wu LJ, Wang SL, Xie T. (2012). Systematic review of β-elemene injection as adjunctive treatment for lung cancer. Chinese Journal of Integrative Medicine, 18(11), 8313-823.