Pyrethrins In Soil and Water From Selected Pyrethrum Growing Areas In Nakuru County, Kenya

Introduction: Pyrethrum also known as Chrysanthemum is a plant from which compounds known as pyrethrins are derived. The pyrethrins have  been used for many years as insecticides. Incidentally due to their high instability they have slowly been replaced by synthetic pyrethroids.  Pyrethrins are generally regarded as safe compared to the pyrethroids. However, the amounts released into the environment have not been well documented especially in pyrethrum growing regions.Objective:  The aim of the study was to determine the concentration of pyrethrins that come from pyrethrum plants and released into the  environment through their use as insecticides, thus, into drinking water and soil, in pyrethrum growing regions in Kenya.Methodology: Quantification to amounts of pyrethrins from pyrethrum plants, in soil and water bodies in and around pyrethrum farms in Kiambogo and Naivasha (Nakuru County). The study was carried out using High Performance Liquid Chromatography (HPLC). Water samples (0.5L) were collected from the following water bodies: rivers, streams, dams, wells and boreholes near or within pyrethrum farms.Conclusion: It was established that, the quantity of pyrethrins present in water and soil samples werebelow detectable levels within the WHO recommended range. Hence safe for the environment,more so for the farmers and the people living around pyrethrum farms. Key words: Pyrethrum, pyrethrins, chromatography, water, soil

Development of a nutraceutical from natural products: A case study of a herbal-based low sodium table salt

Background: Cyperus papyrus reed ash has been used traditionally as a salt substitute in Western Kenya. Previous work carried out at Kenya Medical Research Institute indicated that potassium salt substitution derived from local papyrus reed has a favourable potassium/sodium ratio that is suitable for use to regulate high blood pressure. Objective: To develop and design a process flow for pilot scale production and to develop suitable analytical methods for quality assurance for a herbal based low sodium table salt. Methodology: The plant material was collected from two study sites in Rift Valley then cleaned, chopped, dried, ashed and extracted at laboratory and optimized industrial scale to yield laboratory and pilot scale samples. Elemental analysis was determined using Atomic Absorption and Flame emission spectroscopy. Results: The herbal salt yield for the laboratory scale processing was about 10% for both samples but 13% and 22%, respectively, using the optimized industrial procedure. Elemental analysis results indicate the presence of both essential and non-essential elements and heavy metal was within the World Health Organization acceptable limits. The potassium/sodium ratios obtained were between 3 and 11. Discussion: The herbal salt has the capacity to preserve meat and is a source of other essential trace elements such as chromium, Zinc and manganese. Key words: Nutraceuticals; process optimization; low sodium; herbal salt; elemental compositio

The immunomodulatory activities of licorice polysaccharides (Glycyrrhiza uralensis Fisch.) in CT 26 tumor-bearing mice

Abstract Background The increasing use of complementary and alternative medicine (CAM) has kindled the need for scientific evaluation of the mechanism of action of CAMs. Although, licorice, a common ingredient in many Traditional Chinese medicine (TCM) has attracted great attention for its antitumor and immunomodulatory activities, the mechanism of action of its polysaccharides is still unclear. Here we report the immunomodulatory activity of licorice polysaccharides in vivo. Methods The differential anticancer activities of licorice polysaccharides by tumorigenesis and immunomodulation was evaluated in vivo. Six weeks old, 120 CT-26 tumor bearing BALB/c mice, weighing 20 ± 2 g were used. They were randomly divided into six groups, three groups receiving high molecular weight (fraction A), low molecular weight (fraction B) polysaccharides and crude extract (fraction C); positive, negative and normal groups receiving cytoxin, saline and normal diet respectively. Weight of mice and tumors was determined and tumorigenicity assay calculated to determine the anticancer effects. Immunomodulatory potential was determined by immune organ indices, immune cell population and serum cytokine levels using immune organ weight and index, flow cytometry and cytokine/chemokine bead panel kit respectively. Results Licorice polysaccharides exhibited immunomodulatory activities in CT 26 tumor bearing BALB/c mice. The polysaccharides significantly suppressed tumor growth and increased immune organ index. Furthermore, the immunomodulatory effect was evident with activation of CD4+ and CD8+ immune cells population. The polysaccharides also affected the production of various cytokines, by increasing IL 2, IL 6, IL 7 levels and a decreasing TNFα levels. Conclusion In summary, licorice polysaccharide especially of low molecular weight exhibit anticancer and immunomodulatory activities by suppressing tumor growth and improving general health of mice. They also augment the thymus/spleen index and population of T lymphocytes. Furthermore, the polysaccharides enhance the levels of serum antitumor cytokines, IL 2, IL 6 and IL 7 while decreasing pro-tumor cytokine TNFα

Antimicrobial activity and probable mechanisms of action of medicinal plants of Kenya: Withania somnifera, Warbugia ugandensis, Prunus africana and Plectrunthus barbatus.

Withania somnifera, Warbugia ugandensis, Prunus africana and Plectrunthus barbatus are used traditionally in Kenya for treatment of microbial infections and cancer. Information on their use is available, but scientific data on their bioactivity, safety and mechanisms of action is still scanty. A study was conducted on the effect of organic extracts of these plants on both bacterial and fungal strains, and their mechanisms of action. Extracts were evaluated through the disc diffusion assay. Bacteria and yeast test strains were cultured on Mueller-Hinton agar and on Sabouraud dextrose agar for the filamentous fungi. A 0.5 McFarland standard suspension was prepared. Sterile paper discs 6 mm in diameter impregnated with 10 µl of the test extract (100 mg/ml) were aseptically placed onto the surface of the inoculated media. Chloramphenicol (30 µg) and fluconazole (25 µg) were used as standards. Discs impregnated with dissolution medium were used as controls. Activity of the extracts was expressed according to zone of inhibition diameter. MIC was determined at 0.78-100 mg/ml. Safety studies were carried using Cell Counting Kit 8 cell proliferation assay protocol. To evaluate extracts mechanisms of action, IEC-6 cells and RT-PCR technique was employed in vitro to evaluate Interleukin 7 cytokine. Investigated plants extracts have both bactericidal and fungicidal activity. W. ugandensis is cytotoxic at IC50<50 µg/ml with MIC values of less than 0.78 mg/ml. Prunus africana shuts down expression of IL 7 mRNA at 50 µg/ml. W. somnifera has the best antimicrobial (1.5625 mg/ml), immunopotentiation (2 times IL 7 mRNA expression) and safety level (IC50>200 µg/ml). Fractions from W. ugandensis and W. somnifera too demonstrated antimicrobial activity. Mechanisms of action can largely be attributed to cytotoxicity, Gene silencing and immunopotentiation. Use of medicinal plants in traditional medicine has been justified and possible mechanisms of action demonstrated. Studies to isolate and characterize the bioactive constituents continue

Antiproliferative Effects and Phytochemical Characterization of ((Forssk) Vahl) and (Eckyl and Zeyh) Extracts

Cancer mortality is a global concern. The current therapeutic approaches despite showing efficacy are characterized by several limitations. Search for alternatives has led to the use of herbal plants including C. edulis and P. capensis . However, there is limited research on antiproliferative effects of these medicinal plants. The study sought to evaluate antiproliferative effects of the plants against human breast and prostate cancers using cell viability, and gene expression assays to determine modulation of apoptotic genes. Further, Liquid Chromatography Mass Spectrophotometer (LC-MS) and Gas Chromatography Mass Spectrophotometer (GC-MS) analyses were performed to confirm phytocompounds in the extracts. The results indicated that ethylacetate extracts of C. edulis and P. capensis had the highest activity against cancer cells with IC 50 values of 2.12 ± 0.02, and 6.57 ± 0.03 μg/ml on HCC 1395 and 2.92 ± 0.17 and 5.00 ± 0.17 μg/ml on DU145, respectively. Moreover, the plants extracts exhibited relatively less cytotoxic activities against Vero cell lines (IC 50  > 20 μg/ml). The extracts also exhibit selectivity against the cancer cells (SI > 3). Further, mRNA expression of p53 in the treated HCC 1395 was increased by 7 and 3-fold, whereas by 3 and 2-fold in DU145 cells, upon treatment with ethylacetate extracts of C. edulis and P. capensis , respectively. Similarly, several-fold increases were observed in the number of transcripts of Bax in HCC 1395 and HOXB13 in DU145 cells. Phytochemical analyses detected presence of phytocompounds including flavonoids, phenolics, tocopherols and terpenoids which are associated with anticancer activity. Findings from this study provide a scientific validation for the folklore use of these plants in management of cancer

Bar chart depicting the relative IL 7 mRNA expression in IEC-6 cells subjected to the 4 medicinal plants.

<p>The assay was replicated 3 times. W. somnifera up-regulates IL-7 to approximately 2 times.</p

The MIC’s in mm of selected extracts against bacterial and fungal strains.

<p>WS (W. somnifera), WU (W. ugandensis), PA (P. africana), SA (Staphylococcus aureus), MRSA (Methicilin Resistance Staphylococcus aureus), MG (Microsporum gypseum), CA (Candida albicans), CN (Cryptococcus neoformans), TM (Trichophyton mentagrophytes), ND (Not done).</p

Zones of inhibition (mm) of selected plant extracts against bacterial and fungal strains.

<p>WS (W. somnifera), WU (W. ugandensis), PA (P. africana), SA (Staphylococcus aureus), MRSA (Methicilin Resistance Staphylococcus aureus), MG (Microsporum gypseum), CA (Candida albicans), CN (Cryptococcus neoformans), TM (Trichophyton mentagrophytes), NA (Not applicable), ND (Not done).</p

Antifungal activity of fractions 9, 10, 11 & 17 from dichloromethane extract of W. ugandensis against C. neoformans (A) and C. albicans (B).

<p>They display zones of inhibition (mm) of 12, 9, 8, 6 & 14, 8, 8, 6 respectively.</p

72 hr expression of GAPDH and IL 7 on treatment with different combinations of the 4 plant extracts.

<p>A & B represent GAPDH & IL 7 respectively. Combination ratios, WU/PA 1∶2, WU/PB 1∶4, WU/WS 1∶1, PA/PB 1∶2, PA/WS 2∶1, PB/WS 2∶1, PB/WS 4∶1, WU/WS/PB, 1∶1:4. P. africana was able to shut down the expression of IL 7 irrespective of the combination used.</p