Effect of Spirulina on Lipid Profile, Glucose and Malondialdehyde Levels in Type 2 Diabetic Patients

Rostami, Hormat Alsadat Azmand; Marjani, Abdoljalal; Mojerloo, Mohammad; Rahimi, Behdad; Marjani, Majid

doi:10.1590/s2175-97902022e191140

Abstract

The study aimed to assess possible spirulina effects on lipid profile, glucose, and malondialdehyde levels in new cases of type 2 diabetes. The subjects consisted of 30 new cases of types 2 diabetes that divided into two groups; each consisted of 15 diabetic patients. Group I did not take any functional food or supplement and received no spirulina supplementation. Group II or experimental group also did not take any functional food or supplement but received spirulina supplementation. Analysis of data was done using SPSS 16.0. The Kolmogorov-Smirnov test, paired t-test, Wilcoxon test, and Spearman correlation analysis were used to analyze the data. After eight weeks of spirulina supplementation, significant differences were shown in the serum levels of total cholesterol, low-density lipoprotein (LDL)-cholesterol, triglyceride, and malondialdehyde. The serum fasting blood glucose, lipid profiles, and malondialdehyde levels at baseline were negatively and positively correlated with changes in these parameters. Spirulina supplementation may have a beneficial effect on lipid profile and malondialdehyde (MDA) levels through an interventional 8 weeks. This effect may protect subjects against free radicals and the development of some diseases such as atherosclerosis. The spirulina supplementation also showed a potential lipid-lowering effect on new case type 2 diabetic patients which may help the diabetics to have control on lipid levels. In addition, spirulina may be used as a functional food for the management of lipid profiles and MDA levels.

Keywords:
Spirulina. Glucose. Lipids. Malondialdehyde. Diabetes Mellitus; Type 2

INTRODUCTION

Diabetes mellitus (DM) affects different organs in the human body. It is the third cause of death worldwide (Thornalley, 2002Thornalley PJ. Methods for studying the binding of advanced glycated proteins to receptors for advanced glycation endproducts (AGE receptors). Oxidant Antioxidant: Springer; 2002. p. 49-62.). DM can cause dysfunction in the metabolism of carbohydrates, fat, and proteins. Different epidemiological studies and reports by the World Health Organization have indicated the increasing prevalence of DM in the world (Akbarzadeh et al., 2007Akbarzadeh A, Norouzian D, Mehrabi M, Jamshidi S, Farhangi A, Verdi AA, et al. Induction of diabetes by streptozotocin in rats. India J Clin Biochem. 2007;22(2):60-4.). Different agents have been used to hinder the beginning of diabetes in pre-diabetic subjects or animals (Sprietsma, Schuitemaker, 1994Sprietsma JE, Schuitemaker GE. Diabetes can be prevented by reducing insulin production. Med Hypotheses. 1994;42(1):15-23.). Many studies have been conducted to find natural sources that can affect the carbohydrate level in diabetic patients (Wolf, 1987Wolf S. The potential role of oxidation and its complications: novel implications for theory and therapy. Diabetic complicat Sci Clin Aspect. 1987.). Spirulina is a cyanobacterium that grows in high temperatures and alkaline conditions. In 1967, the International Association of Applied Microbiology accepted spirulina as a source of excellent food for the future (Anitha, Chandralekha, 2010Anitha L, Chandralekha K. Effect of supplementation of Spirulina on blood glucose, glycosylated hemoglobin and lipid profile of male non-insulin dependent diabetics. Asia J Experiment Biologic Sci. 2010;1(1):36-46.). Spirulina contains high protein content (60-70%), carotenoids, vitamin E, phycocyanine, and chlorophyll (Layam, Reddy, 2006Layam A, Reddy CLK. Antidiabetic property of spirulina. Diabetologia croatica. 2006;35(2):29-33.). It has been reported as a new functional food that may help patients with chronic diseases such as diabetes. Some studies have shown an association between spirulina (as a functional food for humans) and cholesterol- regulatory properties, the host immune system modulation, and antioxidant effect (Hirata et al., 2000Hirata T, Tanaka M, Ooike M, Tsunomura T, Sakaguchi M. Antioxidant activities of phycocyanobilin prepared from Spirulina platensis. J Appli Phycol. 2000;12(3-5):435-9.; Qureshi, Kidd, Ali, 1996Qureshi M, Kidd M, Ali R. Spirulina platensis extract enhances chicken macrophage functions after in vitro exposure. J Nutr Immunol. 1996;3(4):35-45.). Moreover, toxicological studies have revealed the safety of spirulina (Salazar et al., 1996Salazar M, Chamorro GA, Salazar S, Steele CE. Effect of Spirulina maxima consumption on reproduction and peri- and postnatal development in rats. Food Chem Toxicol. 1996;34(4):353-9.). Many findings have performed to assess the effect of spirulina on human beings' health and different metabolic disorders (Kim, Kim, 2005Kim WY, Kim MH. The change of lipid metabolism and immune function caused by antioxidant material in the hypercholesterolemic elderly women in Korea. J Nutr Health. 2005;38(1):67-75.; Parikh, Mani, Iyer, 2001Parikh P, Mani U, Iyer U. Role of Spirulina in the Control of Glycemia and Lipidemia in Type 2 Diabetes Mellitus. J Med Food. 2001;4(4):193-9.; Rodriguez-Hernandez et al., 2001Rodriguez-Hernandez A, Ble-Castillo JL, Juarez-Oropeza MA, Diaz-Zagoya JC. Spirulina maxima prevents fatty liver formation in CD-1 male and female mice with experimental diabetes. Life Sci. 2001;69(9):1029-37.). Spirulina may decrease blood lipids in healthy (Park, Kim, 2003Park J, Kim W. The effect of Spirulina on lipid metabolism, antioxidant capacity and immune function in Korean elderly. Korea J Nutr . 2003;36:287-97.), heart disease (Ramamoorthy, Premakumari, 1996Ramamoorthy A, Premakumari S. Effect of supplementation of Spirulina on hypercholesterolemic patients. J Food Sci Technol 1996;33(2):124-8.), and diabetic individuals (Mani, Desai, Iyer, 2000Mani U, Desai S, Iyer U. Studies on the long-term effect of spirulina supplementation on serum lipid profile and glycated proteins in NIDDM patients. J Nutraceutic Function Med Food. 2000;2(3):25-32.). Spirulina also shows antioxidant properties that can inhibit lipid peroxidation (Benedetti et al., 2004Benedetti S, Benvenuti F, Pagliarani S, Francogli S, Scoglio S, Canestrari F. Antioxidant properties of a novel phycocyanin extract from the blue-green alga Aphanizomenon flos-aquae. Life Sci. 2004;75(19):2353-62.). Some studies have found that spirulina reduces plasma triglycerides, total-and LDL-cholesterol, and blood pressure in healthy elderly people (Park et al., 2008Park HJ, Lee YJ, Ryu HK, Kim MH, Chung HW, Kim WY. A randomized double-blind, placebo-controlled study to establish the effects of spirulina in elderly Koreans. Ann Nutr Metab. 2008;52(4):322-8.; Park, Kim, 2003Park J, Kim W. The effect of Spirulina on lipid metabolism, antioxidant capacity and immune function in Korean elderly. Korea J Nutr . 2003;36:287-97.). Spirulina shows many biological activities such as anemia prevention (Hemalatha et al., 2012Hemalatha K, Pugazhendy K, Jayachandran K, Jayanthi C, Meenambal M. Studies on the protective efficacy of Spirulina against lead acetate induced hepatotoxicity in Rattus norvegicus. Int J Chem Anal Sci. 2012;3:1509-12.), stopping of herpes simplex infection (Ferreira-Hermosillo et al., 2011Ferreira-Hermosillo A, Torres-Durán P, Shamosh-Halabe S, Juarez-Oropeza M. Biological effects of Spirulina and current research on its antioxidant activity. Toctli RICTB. 2011;2(1):1-13.), elevated production of antibodies (Premkumar et al., 2004Premkumar K, Abraham SK, Santhiya ST, Ramesh A. Protective effect of Spirulina fusiformis on chemical-induced genotoxicity in mice. Fitoterapia. 2004;75(1):24-31.), hypoglycemic (Abdel-Daim, Abuzead, Halawa, 2013Abdel-Daim MM, Abuzead SM, Halawa SM. Protective role of Spirulina platensis against acute deltamethrin-induced toxicity in rats. PLoS One. 2013;8(9):e72991.), hypolipemic (Jarouliya et al., 2012Jarouliya U, Zacharia JA, Kumar P, Bisen PS, Prasad GB. Alleviation of metabolic abnormalities induced by excessive fructose administration in Wistar rats by Spirulina maxima. Indian J Med Res. 2012;135:422-8.), antihypertensive characteristics (Ponce-Canchihuaman, et al., 2010Ponce-Canchihuaman JC, Perez-Mendez O, Hernandez-Munoz R, Torres-Duran PV, Juarez-Oropeza MA. Protective effects of Spirulina maxima on hyperlipidemia and oxidative-stress induced by lead acetate in the liver and kidney. Lipids Health Dis. 2010;9:35.), reduction of lipid profiles of the liver and lipid peroxidation products (El-Baky, El Baz, El Baroty, 2009El-Baky HHA, El Baz F, El-Baroty GS. Enhancement of antioxidant production in Spirulina platensis under oxidative stress. Acta Physiologiae Plantarum. 2009;31(3):623.). The aim of this study was to assess the possible spirulina effects on lipid profile, glucose, and malondialdehyde (MDA) concentrations in type 2 diabetic patients.

MATERIAL AND METHODS

Subjects were chosen from patients with diabetes mellitus type 2 who referred to the health center in Behshar, Mazandaran Province, Iran. The subjects consisted of 30 new cases of types 2 diabetes (with fasting blood glucose ≥ 126 mg/dl). The subjects were divided into two groups; each consisted of 15 diabetic patients. Group, I did not take any functional food or supplement and received no spirulina supplementation. Group II or experimental group also did not take any oral hypoglycemic drugs, insulin or functional food and any other supplementation, but received spirulina supplementation (provided from Dana Med Pars Company, Tehran, Iran). The nutrition profile of spirulina powder is shown in Table I. Spirulina supplementation as pills were given for two months (4 grams/day) to the experimental group. The regular diets and physical activity of study subjects were maintained during the study. Diabetic patients were asked to maintain the usual diet and prevented to take any functional foods or dietary supplements. Follow up was continuously performed by phone calls twice a week. Exclusion criteria contain pregnant women, coronary artery diseases, peripheral vascular disease, cerebrovascular disease, liver disease, and impaired organ functions.

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TABLE I
Nutrition profile of spirulina powder

The 12-hr overnight fasting blood samples were collected for determination of fasting blood glucose, triglyceride, cholesterol, HDL-cholesterol, LDL-cholesterol, and MDA in the Metabolic Disorders Research Center, Golestan University of Medical Sciences. Blood samples were collected at the beginning and after eight weeks of the study groups. Serums were separated by centrifugation at 1000 g for 10 minutes. Before and after treatment with spirulina, the levels of biochemical parameters and MDA (nano mol/L) were determined by commercial kits and Kei Satoh (Satoh, 1978Satoh K. Serum lipid peroxide in cerebrovascular disorders determined by a new colorimetric method. Clin Chim Acta. 1978;90(1):37-43.) method using spectrophotometry (JENWAY6305), respectively. The serum insulin level was determined by the enzyme-linked immunosorbent assay. The study was approved by the Research Deputy of Golestan University of Medical Sciences Ethics Committee (IR.GOUMS.REC.1394.34). From all study subjects, a written agreement was obtained before blood collection and the start of the experiments. All subjects were weighed using digital scales. Study subjects were with a minimal cloth and without shoes. A tape meter was used to measure height when subjects were in stand ing position. Calculation of Body Mass Index (BMI) was done as weight (in kilograms) divided by height (in meters squared). Subjects were classified in to different categories of body mass index. Study subjects with BMI equal to 25.0-29.9 Kg/m² and BMI higher or equal to 30 Kg/m² were taken into account as overweight and obese subjects, respectively (WHO, 1998WHO: World Health Organization. Prevention and Management of the Global Epidemic of Obesity. Report of the WHO Consultation on Obesity. WHO: Geneva, 1998; (Technical Report Series, No. 894). 1998 ).

Data Analysis

Analysis of data was done using SPSS 16.0 (SPSS Inc., Chicago, IL, USA). Data were shown as mean with standard deviation. The Kolmogorov-Smirnov test was used to check the normal distribution of biochemical parameters. A comparison of mean differences of biochemical parameters was done by the paired t-test at the beginning and after eight weeks of intervention. MDA levels in both groups were compared and analyzed by the Wilcoxon test. Spearman correlation analysis was used to investigate the association between baseline blood profiles, fasting blood glucose and MDA levels, and changes in the biochemical parameters. Statistical significant was considered as P-value < 0.05.

RESULTS

The mean age of the spirulina treated type 2 diabetic patients and diabetic controls were 46.70±8.10 and 47.30±8.80, respectively. Body Mass Index of the spirulina treatment group and diabetic controls were 28.27±2.05 and 27.21±1.83, respectively. Baseline data of two groups' type 2 diabetic patients are shown in Table II. Significant differences are considered in the baseline data between the spirulina and control subjects in terms of fasting blood glucose, triglyceride, and MDA levels. No differences were found in other parameters (Table II). Table III shows the blood profile of the baseline and after eight weeks of intervention data between the spirulina treated group and control subject. Comparison between baselines and after eight weeks of intervention in spirulina treated diabetic patients were shown significant decreases in the total cholesterol, LDL-cholesterol, triglyceride, and MDA serum levels (P< 0.05, Table III) but other tested parameters was not revealed any significant changes. Therefore, spirulina supplementation shows a significant effect on the level of total cholesterol, triglyceride, and MDA levels in diabetic patients with higher triglyceride, total cholesterol, and MDA levels after 8 weeks of intervention with spirulina (p<0.01, Table III).

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TABLE II
Baseline characteristics of study subjects

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TABLE III
Blood profile of the study subjects after eight weeks intervention

Comparison between baselines and after eight weeks of intervention in diabetic control subjects was not revealed any significant changes in all tested parameters (P>0.05, Table III).

The correlations between baseline glucose, blood lipids, and MDA levels and spirulina supplementation are shown in Table IV. Fasting blood glucose and insulin levels at the beginning were negatively and positively correlated with alterations in fasting blood glucose and insulin, respectively (r= -0.964 and r= 0.911, p<0.01). Serum triglyceride level at the beginning was positively and negatively correlated with alterations in triglyceride and MDA, respectively (r= 0.761 and r= -0.653, p<0.01, and p<0.05). The total cholesterol level at the beginning was correlated positively with alterations in total cholesterol and LDL-cholesterol (r= 0.742 and r= 0.701, p<0.01 and p<0.01). The HDL-cholesterol level at baseline was positively correlated with alterations in HDL-cholesterol (r= 0.968, p<0.01). The LDL-cholesterol level at baseline was positively correlated with alterations in total cholesterol and LDL- cholesterol (r= 0.757 and r= 0.877, p<0.01, and p<0.01). The serum level of MDA at baseline was negatively and positively correlated with alterations in triglyceride and MDA, respectively (r= -0.695 and r= -0.961, p<0.01, and p<0.01). There was no correlation between these parameters in the control group.

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TABLE IV
The correlation coefficients between fasting blood glucose, blood profile and MDA at baseline and biochemical parameters changes (spirulina group)

DISCUSSION

In the present study we the effect of spirulina on lipid profile, glucose, and malondialdehyde levels in new cases of type 2 diabetes were assessed. After eight weeks of spirulina supplementation, significant differences were shown in the serum levels of total cholesterol, low-density lipoprotein (LDL)-cholesterol, triglyceride, and malondialdehyde. Spirulina is thought to improve blood lipid profile (Torres-Duran et al., 1998Torres-Duran PV, Miranda-Zamora R, Paredes-Carbajal MC, Mascher D, Diaz-Zagoya JC, Juarez-Oropeza MA. Spirulina maxima prevents induction of fatty liver by carbon tetrachloride in the rat. Biochem Mol Biol Int. 1998;44(4):787-93.) and decrease oxidative stress (Shklar, Schwartz, 1988Shklar G, Schwartz J. Tumor necrosis factor in experimental cancer regression with alphatocopherol, beta-carotene, canthaxanthin and algae extract. Eur J Cancer Clin Oncol. 1988;24(5):839-50.). Dyslipidemia and oxidative stress are observed in most diabetic patients. Spirulina may be a good supplementation for type 2 diabetic patients. Study of (Park, Ahn, 2007Park JS, Ahn CW. Educational program for diabetic patients in Korea--multidisplinary intensive management. Diabetes Res Clin Pract. 2007;77 Suppl 1:S194-8.) on healthy elderly people with normal fasting blood glucose level showed that there is an association between the effects of spirulina supplementation and a decrease in fasting blood glucose level, while another study indicated no decrease in fasting blood glucose among type 2 diabetic patients (Lee, Park, 2008Lee EH, Park JE, Choi YJ, Huh KB, Kim WY. A randomized study to establish the effects of spirulina in type 2 diabetes mellitus patients. Nutr Res Pract. 2008;2(4):295-300.). Similar to the results of the present study, a study indicated that spirulina may have no effects on blood glucose levels in diabetic patients (Lee et al., 2008Lee EH, Park JE, Choi YJ, Huh KB, Kim WY. A randomized study to establish the effects of spirulina in type 2 diabetes mellitus patients. Nutr Res Pract. 2008;2(4):295-300.). A study is reported the anti-diabetic property of spirulina (Layam, Reddy, 2006Layam A, Reddy CLK. Antidiabetic property of spirulina. Diabetologia croatica. 2006;35(2):29-33.). In the present study, oral administration of spirulina did not change blood glucose level and had no hypoglycemic effect, while other studies have shown that administration of spirulina affects blood glucose levels and helps control blood glucose levels in streptozotocin-induced diabetic animals (Pandey et al., 2011Pandey JP, Tiwari A, Mishra G, Mishra R. Role of Spirulina maxima in the control of blood glucose levels and body weight in streptozotocin induced diabetic male Wistar rats. J algal biomass utln. 2011;2(4):35-7.; Sharoud, 2015Sharoud MN. Protective effect of spirulina against paracetamol-induced hepatic injury in rats. J Exp Biol Agric Sci. 2015;3(1):44-53.). Thus, spirulina may not be used as a functional food for the regulation of blood glucose in diabetic patients. The results of the present study are consistent with some other studies (Layam, Reddy, 2006Layam A, Reddy CLK. Antidiabetic property of spirulina. Diabetologia croatica. 2006;35(2):29-33.; Lee et al., 2008Lee EH, Park JE, Choi YJ, Huh KB, Kim WY. A randomized study to establish the effects of spirulina in type 2 diabetes mellitus patients. Nutr Res Pract. 2008;2(4):295-300.). Study of Park and Kim (Park, Kim, 2003Park J, Kim W. The effect of Spirulina on lipid metabolism, antioxidant capacity and immune function in Korean elderly. Korea J Nutr . 2003;36:287-97.) indicated that triglyceride, total cholesterol, and LDL-cholesterol serum levels significantly reduced in Korean elderly people after spirulina intervention for 24 weeks. Our results are in agreement with the findings of other studies (Parikh, Mani, Iyer, 2001Parikh P, Mani U, Iyer U. Role of Spirulina in the Control of Glycemia and Lipidemia in Type 2 Diabetes Mellitus. J Med Food. 2001;4(4):193-9.; Park, Kim, 2003Park J, Kim W. The effect of Spirulina on lipid metabolism, antioxidant capacity and immune function in Korean elderly. Korea J Nutr . 2003;36:287-97.; Torres-Duran et al., 1998Torres-Duran PV, Miranda-Zamora R, Paredes-Carbajal MC, Mascher D, Diaz-Zagoya JC, Juarez-Oropeza MA. Spirulina maxima prevents induction of fatty liver by carbon tetrachloride in the rat. Biochem Mol Biol Int. 1998;44(4):787-93.). Abnormal glucose metabolism may be accompanied by abnormal lipid metabolism. This may be considered that there is an association between abnormal metabolism of lipid and metabolic disorders in diabetic patients. Some studies reported increased lipid profiles in diabetic rats (Parikh, Mani, Iyer, 2001Parikh P, Mani U, Iyer U. Role of Spirulina in the Control of Glycemia and Lipidemia in Type 2 Diabetes Mellitus. J Med Food. 2001;4(4):193-9.; Sethi et al., 2004Sethi J, Sood S, Seth S, Talwar A. Evaluation of hypoglycemic and antioxidant effect of Ocimum sanctum. Indian J Clin Biochem. 2004;19(2):152-5.). This may be associated with insulin deficiency and elevated cortisol levels, which has a significant role in the accumulation of fat (Jurgonski, Juskiewicz, Zdunczyk, 2008Jurgonski A, Juskiewicz J, Zdunczyk Z. Ingestion of black chokeberry fruit extract leads to intestinal and systemic changes in a rat model of prediabetes and hyperlipidemia. Plant Foods Hum Nutr. 2008;63(4):176-82.). Naturally, lipoprotein lipase hydrolyzes triglycerides activates by insulin. Hypertriglyceridemia may occur when the enzyme is inactivated due to insulin deficiency (Hristova, Aloe, 2006Hristova M, Aloe L. Metabolic syndrome-neurotrophic hypothesis. Med Hypoth. 2006;66(3):545-9.). Spirulina may reduce the endogenous synthesis of lipids. The reduced glucose-6-phosphatase activity through the pentose phosphate pathway may decrease glutathione/oxidized glutathione ratio, which can convert NADPH to NADP⁺ (Shirwaikar, Rajendran, 2004Shirwaikar A, Rajendran K, Dinesh Kumar C, Bodla R. Antidiabetic activity of aqueous leaf extract of Annona squamosa in streptozotocin-nicotinamide type 2 diabetic rats. J Ethnopharmacol. 2004;91(1):171-5.). Spirulina may also have an important role in the production of high NADP⁺ that regulates lipogenesis, reduces tissue damage (because of oxidative stress), and causes high resistance for diabetes (Bopanna et al., 1997Bopanna K, Kannan J, Sushma G, Balaraman R, Rathod S. Antidiabetic and antihyperlipaemic effects of neem seed kernel powder on alloxan diabetic rabbits. India J Pharmacol. 1997;29(3):162.). Spirulina may also have therapeutic effects such as preventing and decreasing the damages caused by hyperlipidemia and antioxidant activity (Bertolin et al., 2009Bertolin T, Pilatti D, Vendrametto C, Giacomini V, Bava-rescocs L, Colla J. Effect of Microalga Spir-ulina maxima(Arthrospira platensis) on Hippocampus Lipoperoxida-tion and Lipid Profile in Rats with Induced Hypercholesterolemia. Braz Arch Biol Technol. 2009;52(5):1253-9.). Studies on different animal models revealed that spirulina reduces plasma and hepatic total cholesterol, LDL-cholesterol, and triglycerides, while studies on humans have shown a significant decrease in the total cholesterol, LDL-cholesterol, and triglycerides levels (Ramamoorthy, Premakumari, 1996Ramamoorthy A, Premakumari S. Effect of supplementation of Spirulina on hypercholesterolemic patients. J Food Sci Technol 1996;33(2):124-8.). These findings are in agreement with our results (Ramamoorthy, Premakumari, 1996Ramamoorthy A, Premakumari S. Effect of supplementation of Spirulina on hypercholesterolemic patients. J Food Sci Technol 1996;33(2):124-8.; Shklar, Schwartz, 1988; Torres-Duran et al., 1998Torres-Duran PV, Miranda-Zamora R, Paredes-Carbajal MC, Mascher D, Diaz-Zagoya JC, Juarez-Oropeza MA. Spirulina maxima prevents induction of fatty liver by carbon tetrachloride in the rat. Biochem Mol Biol Int. 1998;44(4):787-93.). Some other studies have reported that spirulina lowering effect on triglycerides can be because of spirulina's influence on lipoprotein metabolism (Iwata, Inayama, Kato, 1990Iwata K, Inayama T, Kato T. Effects of Spirulina platensis on plasma lipoprotein lipase activity in fructose-induced hyperlipidemic rats. J Nutr Sci Vitaminol (Tokyo). 1990;36(2):165-71.). Their studies on spirulina-treated rats showed a significant elevation in lipoprotein lipase activity when compared to rats with a high fructose diet. Free radicals may play an important role in the pathogenesis of diabetes (Gürler et al., 2000Gürler B, Vural H, Yilmaz N, Oguz H, Satici A, Aksoy N. The role of oxidative stress in diabetic retinopathy. Eye. 2000;14(5):730.). Free radicals are associated with many biochemical pathways such as glucose autoxidation, polyol pathway, and protein glycation (Aly, Mantawy, 2012Aly H, Mantawy M. Comparative effects of zinc, selenium an vitamin E or their combination on carbohydrate metabolizing en-zymes and oxidative stress in streptozotocin induced-diabetic rats. Europ Rev Med Pharmacologic Sci. 2012;16:66-78.). Lipid peroxidation can cause injury proteins, lipids, carbohydrates, and nucleic acids and also mediators of tissue injury in cardiovascular pathology and cell membrane or internal cellular components destruction (Burton et al., 1990Burton KP, Morris AC, Massey KD, Buja LM, Hagler HK. Free radicals alter ionic calcium levels and membrane phospholipids in cultured rat ventricular myocytes. J Mol Cell Cardiol. 1990;22(9):1035-47.). There is an important association between oxidative stress and the etiology of diabetic complications (Giugliano, Ceriello, Paolisso, 1996Giugliano D, Ceriello A, Paolisso G. Oxidative stress and diabetic vascular complications. Diabetes care. 1996;19(3):257-67.). Studies of Kim and Kim (Kim, Kim, 2005Kim WY, Kim MH. The change of lipid metabolism and immune function caused by antioxidant material in the hypercholesterolemic elderly women in Korea. J Nutr Health. 2005;38(1):67-75.) on healthy elderly subjects with spirulina supplementation for eight weeks indicated elevated total antioxidant status and reduced thiobarbituric acid reactive substance. Similar to the present study, the study on spirulina extract has shown that spirulina decreases the oxidative process (Pinero Estrada et al., 2001Pinero Estrada JE, Bermejo Bescos P, Villar del Fresno AM. Antioxidant activity of different fractions of Spirulina platensis protean extract. Farmaco. 2001;56(5-7):497-500.). The correlation analysis showed that baseline serum triglycerides, total cholesterol, LDL-cholesterol, and MDA levels indicated a higher decrease in this lipid profile and MDA levels. Although significant elevation in the serum MDA level of diabetic subjects was observed in the present study, it significantly decreased after spirulina supplementation (from 6.0±1.43 nm/l to 4.88±1.16 nm/l.). Oral administration of spirulina may prevent the pathogenic effects of diabetes. This may be because of the secretion of insulin from pancreatic islet β-cells or blood glucose transport to the peripheral tissue (Quoc and Pascaud, 1996Quoc KP, Pascaud M. Effects of dietary γ-linolenic acid on the tissue phospholipid fatty acid composition and the synthesis of eicosanoids in rats. Annal Nutr Metabol. 1996;40(2):99-108.). The study of (Nagaoka et al., 2005Nagaoka S, Shimizu K, Kaneko H, Shibayama F, Morikawa K, Kanamaru Y. A novel protein C-phycocyanin plays a crucial role in the hypocholesterolemic action of Spirulina platensis concentrate in rats. J Nutr. 2005;135(10):2425-30) also showed the mechanism by which spirulina decreases hypercholesterolemia (Ramamoorthy, Premakumari, 1996Ramamoorthy A, Premakumari S. Effect of supplementation of Spirulina on hypercholesterolemic patients. J Food Sci Technol 1996;33(2):124-8.). Different hypotheses have been suggested to identify possible mechanisms for the hypolipidemic effect of Spirulina. Gamma-linolenic acid (GLA) content of spirulina is necessary to synthesis Prostaglandin (PG) in our body. Prostaglandin (Especially PG1) can affect and regulate different biochemical functions such as the regulation of cholesterol synthesis (Mani et al., 2007Mani UV, Iyer UM, Dhruv SA, Mani IU, Sharma KS. Therapeutic utility of Spirulina. Spirulina in human nutrition and health: CRC press; 2007. p. 85-114.). It was reported that Spirulina inhibited lipid peroxidation (Expressed as malondialdehyde) (Miranda et al., 1998Miranda MS, Cintra RG, Barros SB, Mancini Filho J. Antioxidant activity of the microalga Spirulina maxima. Braz J Med Biol Res. 1998;31(8):1075-9.). Phycocyanin (a pigment of spirulina) induces the formation of free radicals. It has been shown that the effect of Phycocyanin was attributed to the inhibition of reaction involved in the formation of the reactive metabolite and possibly because of its radical scavenging activity (Kuriakose, Kurup, 2010Kuriakose GC, Kurup MG. Hepatoprotective effect of Spirulina lonar on paracetamol induced liver damage in rats. Asian J Exp Biol Sci. 2010;1(3):614-23.).

In conclusion, our study concluded that spirulina supplementation may have a beneficial effect on lipid profile and MDA levels through an interventional 8 weeks. This effect may protect subjects against free radicals and the development of some diseases such as atherosclerosis. The study also indicated that the spirulina supplementation showed a potential lipid-lowering effect on new case type 2 diabetic patients which may help the diabetics to have control on lipid levels. In addition, spirulina may be used as a functional food for the management of lipid profiles and MDA levels, which are among the most common complications in diabetic patients. Our study was not shown any significant change in the FBS level between 2 groups. Further studies are required to assess the exact mechanism of spirulina actions on lipid profiles, FBS, and MDA levels.

ACKNOWLEDGMENT

The authors would like to thank the Research Deputy of Golestan University of Medical Sciences for financial support. This research project was derived from MSc thesis in Clinical Biochemistry. The corresponding author wishes to thank Mrs HORMAT ALSADAT AZMAND ROSTAMI for her sincere help.

REFERENCES

Abdel-Daim MM, Abuzead SM, Halawa SM. Protective role of Spirulina platensis against acute deltamethrin-induced toxicity in rats. PLoS One. 2013;8(9):e72991.
Akbarzadeh A, Norouzian D, Mehrabi M, Jamshidi S, Farhangi A, Verdi AA, et al. Induction of diabetes by streptozotocin in rats. India J Clin Biochem. 2007;22(2):60-4.
Aly H, Mantawy M. Comparative effects of zinc, selenium an vitamin E or their combination on carbohydrate metabolizing en-zymes and oxidative stress in streptozotocin induced-diabetic rats. Europ Rev Med Pharmacologic Sci. 2012;16:66-78.
Anitha L, Chandralekha K. Effect of supplementation of Spirulina on blood glucose, glycosylated hemoglobin and lipid profile of male non-insulin dependent diabetics. Asia J Experiment Biologic Sci. 2010;1(1):36-46.
Benedetti S, Benvenuti F, Pagliarani S, Francogli S, Scoglio S, Canestrari F. Antioxidant properties of a novel phycocyanin extract from the blue-green alga Aphanizomenon flos-aquae. Life Sci. 2004;75(19):2353-62.
Bertolin T, Pilatti D, Vendrametto C, Giacomini V, Bava-rescocs L, Colla J. Effect of Microalga Spir-ulina maxima(Arthrospira platensis) on Hippocampus Lipoperoxida-tion and Lipid Profile in Rats with Induced Hypercholesterolemia. Braz Arch Biol Technol. 2009;52(5):1253-9.
Bopanna K, Kannan J, Sushma G, Balaraman R, Rathod S. Antidiabetic and antihyperlipaemic effects of neem seed kernel powder on alloxan diabetic rabbits. India J Pharmacol. 1997;29(3):162.
Burton KP, Morris AC, Massey KD, Buja LM, Hagler HK. Free radicals alter ionic calcium levels and membrane phospholipids in cultured rat ventricular myocytes. J Mol Cell Cardiol. 1990;22(9):1035-47.
El-Baky HHA, El Baz F, El-Baroty GS. Enhancement of antioxidant production in Spirulina platensis under oxidative stress. Acta Physiologiae Plantarum. 2009;31(3):623.
Ferreira-Hermosillo A, Torres-Durán P, Shamosh-Halabe S, Juarez-Oropeza M. Biological effects of Spirulina and current research on its antioxidant activity. Toctli RICTB. 2011;2(1):1-13.
Giugliano D, Ceriello A, Paolisso G. Oxidative stress and diabetic vascular complications. Diabetes care. 1996;19(3):257-67.
Gürler B, Vural H, Yilmaz N, Oguz H, Satici A, Aksoy N. The role of oxidative stress in diabetic retinopathy. Eye. 2000;14(5):730.
Hemalatha K, Pugazhendy K, Jayachandran K, Jayanthi C, Meenambal M. Studies on the protective efficacy of Spirulina against lead acetate induced hepatotoxicity in Rattus norvegicus. Int J Chem Anal Sci. 2012;3:1509-12.
Hirata T, Tanaka M, Ooike M, Tsunomura T, Sakaguchi M. Antioxidant activities of phycocyanobilin prepared from Spirulina platensis. J Appli Phycol. 2000;12(3-5):435-9.
Hristova M, Aloe L. Metabolic syndrome-neurotrophic hypothesis. Med Hypoth. 2006;66(3):545-9.
Iwata K, Inayama T, Kato T. Effects of Spirulina platensis on plasma lipoprotein lipase activity in fructose-induced hyperlipidemic rats. J Nutr Sci Vitaminol (Tokyo). 1990;36(2):165-71.
Jarouliya U, Zacharia JA, Kumar P, Bisen PS, Prasad GB. Alleviation of metabolic abnormalities induced by excessive fructose administration in Wistar rats by Spirulina maxima. Indian J Med Res. 2012;135:422-8.
Jurgonski A, Juskiewicz J, Zdunczyk Z. Ingestion of black chokeberry fruit extract leads to intestinal and systemic changes in a rat model of prediabetes and hyperlipidemia. Plant Foods Hum Nutr. 2008;63(4):176-82.
Kim WY, Kim MH. The change of lipid metabolism and immune function caused by antioxidant material in the hypercholesterolemic elderly women in Korea. J Nutr Health. 2005;38(1):67-75.
Kuriakose GC, Kurup MG. Hepatoprotective effect of Spirulina lonar on paracetamol induced liver damage in rats. Asian J Exp Biol Sci. 2010;1(3):614-23.
Layam A, Reddy CLK. Antidiabetic property of spirulina. Diabetologia croatica. 2006;35(2):29-33.
Lee EH, Park JE, Choi YJ, Huh KB, Kim WY. A randomized study to establish the effects of spirulina in type 2 diabetes mellitus patients. Nutr Res Pract. 2008;2(4):295-300.
Mani U, Desai S, Iyer U. Studies on the long-term effect of spirulina supplementation on serum lipid profile and glycated proteins in NIDDM patients. J Nutraceutic Function Med Food. 2000;2(3):25-32.
Mani UV, Iyer UM, Dhruv SA, Mani IU, Sharma KS. Therapeutic utility of Spirulina. Spirulina in human nutrition and health: CRC press; 2007. p. 85-114.
Miranda MS, Cintra RG, Barros SB, Mancini Filho J. Antioxidant activity of the microalga Spirulina maxima. Braz J Med Biol Res. 1998;31(8):1075-9.
Nagaoka S, Shimizu K, Kaneko H, Shibayama F, Morikawa K, Kanamaru Y. A novel protein C-phycocyanin plays a crucial role in the hypocholesterolemic action of Spirulina platensis concentrate in rats. J Nutr. 2005;135(10):2425-30
Pandey JP, Tiwari A, Mishra G, Mishra R. Role of Spirulina maxima in the control of blood glucose levels and body weight in streptozotocin induced diabetic male Wistar rats. J algal biomass utln. 2011;2(4):35-7.
Parikh P, Mani U, Iyer U. Role of Spirulina in the Control of Glycemia and Lipidemia in Type 2 Diabetes Mellitus. J Med Food. 2001;4(4):193-9.
Park HJ, Lee YJ, Ryu HK, Kim MH, Chung HW, Kim WY. A randomized double-blind, placebo-controlled study to establish the effects of spirulina in elderly Koreans. Ann Nutr Metab. 2008;52(4):322-8.
Park J, Kim W. The effect of Spirulina on lipid metabolism, antioxidant capacity and immune function in Korean elderly. Korea J Nutr . 2003;36:287-97.
Park JS, Ahn CW. Educational program for diabetic patients in Korea--multidisplinary intensive management. Diabetes Res Clin Pract. 2007;77 Suppl 1:S194-8.
Pinero Estrada JE, Bermejo Bescos P, Villar del Fresno AM. Antioxidant activity of different fractions of Spirulina platensis protean extract. Farmaco. 2001;56(5-7):497-500.
Ponce-Canchihuaman JC, Perez-Mendez O, Hernandez-Munoz R, Torres-Duran PV, Juarez-Oropeza MA. Protective effects of Spirulina maxima on hyperlipidemia and oxidative-stress induced by lead acetate in the liver and kidney. Lipids Health Dis. 2010;9:35.
Premkumar K, Abraham SK, Santhiya ST, Ramesh A. Protective effect of Spirulina fusiformis on chemical-induced genotoxicity in mice. Fitoterapia. 2004;75(1):24-31.
Quoc KP, Pascaud M. Effects of dietary γ-linolenic acid on the tissue phospholipid fatty acid composition and the synthesis of eicosanoids in rats. Annal Nutr Metabol. 1996;40(2):99-108.
Qureshi M, Kidd M, Ali R. Spirulina platensis extract enhances chicken macrophage functions after in vitro exposure. J Nutr Immunol. 1996;3(4):35-45.
Ramamoorthy A, Premakumari S. Effect of supplementation of Spirulina on hypercholesterolemic patients. J Food Sci Technol 1996;33(2):124-8.
Rodriguez-Hernandez A, Ble-Castillo JL, Juarez-Oropeza MA, Diaz-Zagoya JC. Spirulina maxima prevents fatty liver formation in CD-1 male and female mice with experimental diabetes. Life Sci. 2001;69(9):1029-37.
Salazar M, Chamorro GA, Salazar S, Steele CE. Effect of Spirulina maxima consumption on reproduction and peri- and postnatal development in rats. Food Chem Toxicol. 1996;34(4):353-9.
Satoh K. Serum lipid peroxide in cerebrovascular disorders determined by a new colorimetric method. Clin Chim Acta. 1978;90(1):37-43.
Sethi J, Sood S, Seth S, Talwar A. Evaluation of hypoglycemic and antioxidant effect of Ocimum sanctum. Indian J Clin Biochem. 2004;19(2):152-5.
Sharoud MN. Protective effect of spirulina against paracetamol-induced hepatic injury in rats. J Exp Biol Agric Sci. 2015;3(1):44-53.
Shirwaikar A, Rajendran K, Dinesh Kumar C, Bodla R. Antidiabetic activity of aqueous leaf extract of Annona squamosa in streptozotocin-nicotinamide type 2 diabetic rats. J Ethnopharmacol. 2004;91(1):171-5.
Shklar G, Schwartz J. Tumor necrosis factor in experimental cancer regression with alphatocopherol, beta-carotene, canthaxanthin and algae extract. Eur J Cancer Clin Oncol. 1988;24(5):839-50.
Sprietsma JE, Schuitemaker GE. Diabetes can be prevented by reducing insulin production. Med Hypotheses. 1994;42(1):15-23.
Thornalley PJ. Methods for studying the binding of advanced glycated proteins to receptors for advanced glycation endproducts (AGE receptors). Oxidant Antioxidant: Springer; 2002. p. 49-62.
Torres-Duran PV, Miranda-Zamora R, Paredes-Carbajal MC, Mascher D, Diaz-Zagoya JC, Juarez-Oropeza MA. Spirulina maxima prevents induction of fatty liver by carbon tetrachloride in the rat. Biochem Mol Biol Int. 1998;44(4):787-93.
WHO: World Health Organization. Prevention and Management of the Global Epidemic of Obesity. Report of the WHO Consultation on Obesity. WHO: Geneva, 1998; (Technical Report Series, No. 894). 1998
Wolf S. The potential role of oxidation and its complications: novel implications for theory and therapy. Diabetic complicat Sci Clin Aspect. 1987.

ETHICS APPROVAL AND CONSENT TO PARTICIPATE:

The ethnic committee of Golestan University of Medical Sciences approved the study (With ethics number: IR.GOUMS.1396.41)
FUNDING:

This work has been supported by the Research Deputy of the Golestan University of Medical Science.

Publication Dates

Publication in this collection
02 Sept 2022
Date of issue
2022

History

Received
03 Feb 2019
Accepted
05 July 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Abdel-Daim MM, Abuzead SM, Halawa SM. Protective role of Spirulina platensis against acute deltamethrin-induced toxicity in rats. PLoS One. 2013;8(9):e72991.

[2] Akbarzadeh A, Norouzian D, Mehrabi M, Jamshidi S, Farhangi A, Verdi AA, et al. Induction of diabetes by streptozotocin in rats. India J Clin Biochem. 2007;22(2):60-4.

[3] Aly H, Mantawy M. Comparative effects of zinc, selenium an vitamin E or their combination on carbohydrate metabolizing en-zymes and oxidative stress in streptozotocin induced-diabetic rats. Europ Rev Med Pharmacologic Sci. 2012;16:66-78.

[4] Anitha L, Chandralekha K. Effect of supplementation of Spirulina on blood glucose, glycosylated hemoglobin and lipid profile of male non-insulin dependent diabetics. Asia J Experiment Biologic Sci. 2010;1(1):36-46.

[5] Benedetti S, Benvenuti F, Pagliarani S, Francogli S, Scoglio S, Canestrari F. Antioxidant properties of a novel phycocyanin extract from the blue-green alga Aphanizomenon flos-aquae. Life Sci. 2004;75(19):2353-62.

[6] Bertolin T, Pilatti D, Vendrametto C, Giacomini V, Bava-rescocs L, Colla J. Effect of Microalga Spir-ulina maxima(Arthrospira platensis) on Hippocampus Lipoperoxida-tion and Lipid Profile in Rats with Induced Hypercholesterolemia. Braz Arch Biol Technol. 2009;52(5):1253-9.

[7] Bopanna K, Kannan J, Sushma G, Balaraman R, Rathod S. Antidiabetic and antihyperlipaemic effects of neem seed kernel powder on alloxan diabetic rabbits. India J Pharmacol. 1997;29(3):162.

[8] Burton KP, Morris AC, Massey KD, Buja LM, Hagler HK. Free radicals alter ionic calcium levels and membrane phospholipids in cultured rat ventricular myocytes. J Mol Cell Cardiol. 1990;22(9):1035-47.

[9] El-Baky HHA, El Baz F, El-Baroty GS. Enhancement of antioxidant production in Spirulina platensis under oxidative stress. Acta Physiologiae Plantarum. 2009;31(3):623.

[10] Ferreira-Hermosillo A, Torres-Durán P, Shamosh-Halabe S, Juarez-Oropeza M. Biological effects of Spirulina and current research on its antioxidant activity. Toctli RICTB. 2011;2(1):1-13.

[11] Giugliano D, Ceriello A, Paolisso G. Oxidative stress and diabetic vascular complications. Diabetes care. 1996;19(3):257-67.

[12] Gürler B, Vural H, Yilmaz N, Oguz H, Satici A, Aksoy N. The role of oxidative stress in diabetic retinopathy. Eye. 2000;14(5):730.

[13] Hemalatha K, Pugazhendy K, Jayachandran K, Jayanthi C, Meenambal M. Studies on the protective efficacy of Spirulina against lead acetate induced hepatotoxicity in Rattus norvegicus. Int J Chem Anal Sci. 2012;3:1509-12.

[14] Hirata T, Tanaka M, Ooike M, Tsunomura T, Sakaguchi M. Antioxidant activities of phycocyanobilin prepared from Spirulina platensis. J Appli Phycol. 2000;12(3-5):435-9.

[15] Hristova M, Aloe L. Metabolic syndrome-neurotrophic hypothesis. Med Hypoth. 2006;66(3):545-9.

[16] Iwata K, Inayama T, Kato T. Effects of Spirulina platensis on plasma lipoprotein lipase activity in fructose-induced hyperlipidemic rats. J Nutr Sci Vitaminol (Tokyo). 1990;36(2):165-71.

[17] Jarouliya U, Zacharia JA, Kumar P, Bisen PS, Prasad GB. Alleviation of metabolic abnormalities induced by excessive fructose administration in Wistar rats by Spirulina maxima. Indian J Med Res. 2012;135:422-8.

[18] Jurgonski A, Juskiewicz J, Zdunczyk Z. Ingestion of black chokeberry fruit extract leads to intestinal and systemic changes in a rat model of prediabetes and hyperlipidemia. Plant Foods Hum Nutr. 2008;63(4):176-82.

[19] Kim WY, Kim MH. The change of lipid metabolism and immune function caused by antioxidant material in the hypercholesterolemic elderly women in Korea. J Nutr Health. 2005;38(1):67-75.

[20] Kuriakose GC, Kurup MG. Hepatoprotective effect of Spirulina lonar on paracetamol induced liver damage in rats. Asian J Exp Biol Sci. 2010;1(3):614-23.

[21] Layam A, Reddy CLK. Antidiabetic property of spirulina. Diabetologia croatica. 2006;35(2):29-33.

[22] Lee EH, Park JE, Choi YJ, Huh KB, Kim WY. A randomized study to establish the effects of spirulina in type 2 diabetes mellitus patients. Nutr Res Pract. 2008;2(4):295-300.

[23] Mani U, Desai S, Iyer U. Studies on the long-term effect of spirulina supplementation on serum lipid profile and glycated proteins in NIDDM patients. J Nutraceutic Function Med Food. 2000;2(3):25-32.

[24] Mani UV, Iyer UM, Dhruv SA, Mani IU, Sharma KS. Therapeutic utility of Spirulina. Spirulina in human nutrition and health: CRC press; 2007. p. 85-114.

[25] Miranda MS, Cintra RG, Barros SB, Mancini Filho J. Antioxidant activity of the microalga Spirulina maxima. Braz J Med Biol Res. 1998;31(8):1075-9.

[26] Nagaoka S, Shimizu K, Kaneko H, Shibayama F, Morikawa K, Kanamaru Y. A novel protein C-phycocyanin plays a crucial role in the hypocholesterolemic action of Spirulina platensis concentrate in rats. J Nutr. 2005;135(10):2425-30

[27] Pandey JP, Tiwari A, Mishra G, Mishra R. Role of Spirulina maxima in the control of blood glucose levels and body weight in streptozotocin induced diabetic male Wistar rats. J algal biomass utln. 2011;2(4):35-7.

[28] Parikh P, Mani U, Iyer U. Role of Spirulina in the Control of Glycemia and Lipidemia in Type 2 Diabetes Mellitus. J Med Food. 2001;4(4):193-9.

[29] Park HJ, Lee YJ, Ryu HK, Kim MH, Chung HW, Kim WY. A randomized double-blind, placebo-controlled study to establish the effects of spirulina in elderly Koreans. Ann Nutr Metab. 2008;52(4):322-8.

[30] Park J, Kim W. The effect of Spirulina on lipid metabolism, antioxidant capacity and immune function in Korean elderly. Korea J Nutr . 2003;36:287-97.

[31] Park JS, Ahn CW. Educational program for diabetic patients in Korea--multidisplinary intensive management. Diabetes Res Clin Pract. 2007;77 Suppl 1:S194-8.

[32] Pinero Estrada JE, Bermejo Bescos P, Villar del Fresno AM. Antioxidant activity of different fractions of Spirulina platensis protean extract. Farmaco. 2001;56(5-7):497-500.

[33] Ponce-Canchihuaman JC, Perez-Mendez O, Hernandez-Munoz R, Torres-Duran PV, Juarez-Oropeza MA. Protective effects of Spirulina maxima on hyperlipidemia and oxidative-stress induced by lead acetate in the liver and kidney. Lipids Health Dis. 2010;9:35.

[34] Premkumar K, Abraham SK, Santhiya ST, Ramesh A. Protective effect of Spirulina fusiformis on chemical-induced genotoxicity in mice. Fitoterapia. 2004;75(1):24-31.

[35] Quoc KP, Pascaud M. Effects of dietary γ-linolenic acid on the tissue phospholipid fatty acid composition and the synthesis of eicosanoids in rats. Annal Nutr Metabol. 1996;40(2):99-108.

[36] Qureshi M, Kidd M, Ali R. Spirulina platensis extract enhances chicken macrophage functions after in vitro exposure. J Nutr Immunol. 1996;3(4):35-45.

[37] Ramamoorthy A, Premakumari S. Effect of supplementation of Spirulina on hypercholesterolemic patients. J Food Sci Technol 1996;33(2):124-8.

[38] Rodriguez-Hernandez A, Ble-Castillo JL, Juarez-Oropeza MA, Diaz-Zagoya JC. Spirulina maxima prevents fatty liver formation in CD-1 male and female mice with experimental diabetes. Life Sci. 2001;69(9):1029-37.

[39] Salazar M, Chamorro GA, Salazar S, Steele CE. Effect of Spirulina maxima consumption on reproduction and peri- and postnatal development in rats. Food Chem Toxicol. 1996;34(4):353-9.

[40] Satoh K. Serum lipid peroxide in cerebrovascular disorders determined by a new colorimetric method. Clin Chim Acta. 1978;90(1):37-43.

[41] Sethi J, Sood S, Seth S, Talwar A. Evaluation of hypoglycemic and antioxidant effect of Ocimum sanctum. Indian J Clin Biochem. 2004;19(2):152-5.

[42] Sharoud MN. Protective effect of spirulina against paracetamol-induced hepatic injury in rats. J Exp Biol Agric Sci. 2015;3(1):44-53.

[43] Shirwaikar A, Rajendran K, Dinesh Kumar C, Bodla R. Antidiabetic activity of aqueous leaf extract of Annona squamosa in streptozotocin-nicotinamide type 2 diabetic rats. J Ethnopharmacol. 2004;91(1):171-5.

[44] Shklar G, Schwartz J. Tumor necrosis factor in experimental cancer regression with alphatocopherol, beta-carotene, canthaxanthin and algae extract. Eur J Cancer Clin Oncol. 1988;24(5):839-50.

[45] Sprietsma JE, Schuitemaker GE. Diabetes can be prevented by reducing insulin production. Med Hypotheses. 1994;42(1):15-23.

[46] Thornalley PJ. Methods for studying the binding of advanced glycated proteins to receptors for advanced glycation endproducts (AGE receptors). Oxidant Antioxidant: Springer; 2002. p. 49-62.

[47] Torres-Duran PV, Miranda-Zamora R, Paredes-Carbajal MC, Mascher D, Diaz-Zagoya JC, Juarez-Oropeza MA. Spirulina maxima prevents induction of fatty liver by carbon tetrachloride in the rat. Biochem Mol Biol Int. 1998;44(4):787-93.

[48] WHO: World Health Organization. Prevention and Management of the Global Epidemic of Obesity. Report of the WHO Consultation on Obesity. WHO: Geneva, 1998; (Technical Report Series, No. 894). 1998

[49] Wolf S. The potential role of oxidation and its complications: novel implications for theory and therapy. Diabetic complicat Sci Clin Aspect. 1987.

Nutritional composition Per 100 g	Amounts
General
Total fat (g)	5
Saturated fat (g)	2.2
Cholesterol (mg)	0
Total carbohydrates (g)	16
Dietary fiber(g)	7
Sugars (g)	0
Protein (g)	67
Vitamins
Vit A (as Beta carotene) (IU)	375000
Vitamin E (IU)	7
Vitamin K1 (μg)	2000
Vit K2 (μg)	500
Thiamin (B1)( μg)	117
Riboflavin (B2)( μg)	4667
Niacin (B3)( μg)	13333
Vit (B6) (μg)	10000
Folate (μg)	200
Vit B12 (μg)	300
Biotin (μg)	33 <
Pantothenic acid (μg)	150
Minerals
Calcium (mg)	333
Iron (mg)	217
Phosphorous(mg)	1100
Iodine (μg)	500
Magnesium (mg)	500
Zinc (mg)	3
Selenium (mg)	30
Copper (mg)	0.7
Manganese (mg)	13
Chromium (μg)	13333
Sodium(mg)	1000
potassium(mg)	2000
Carotenoids & Phytonutrients
Gama linolenic Acid (GLA) (mg)	1067
Zeaxanthin (mg)	300
Total carotenoids (mg)	500
Chlorophyll (mg)	1000
c-phycocyanin (mg)	8000
Superoxide dismutase (units)	36000

Parameters	Spirulina treated diabetic patients (n=15)	Diabetic controls (n=15)	P-value
Age (years)	46.70±8.10	47.30±8.80	0.262
Gender (male/female, n)	6/9	5/10	-
BMI (kg/m2)	28.27±2.05	27.21±1.83	0.171
Fasting blood glucose (mg/dl)	186.60±36.86*	174.07±33.40	0.040
Insulin (ng/dl)	6.52±5.21	5.45±5.54	0.152
Total cholesterol (mg/dl)	193.40±36.52	199.20±21.88	0.066
LDL-cholesterol (mg/dl)	106.33±36.75	119.13±20.25	0.081
HDL-cholesterol (mg/dl)	40.46±10.93	40.80±9.42	0.251
Triglyceride (mg/dl)	231.13±86.31*	195.33±47.19	0.020
MDA (nmol/l)	6.0±1.43*	5.02±0.97	0.030

Parameters	Spirulina treated diabetic patients (n=15)		P-value	Diabetic control (n=15)		P-value
Parameters	baseline	8the week		baseline	8the week
Fasting blood glucose (mg/dl)	186.60±36.86	180.93±29.49	0.11	174.07±33.40	177.73±34.53	0.24
Insulin (ng/dl)	6.52±5.21	6.18±3.50	0.59	5.45±5.54	5.22±5.23	0.38
Total cholesterol (mg/dl)	193.40±36.52	168.46±23.98*	0.001	199.20±21.88	203.66±24.91	0.89
LDL-cholesterol (mg/dl)	106.33±36.75	93.86±27.07*	0.001	119.13±20.25	123.86±23.40	0.80
HDL-cholesterol (mg/dl)	40.46±10.93	41.26±10.91	0.271	40.80±9.42	38.93±8.53	0.14
Triglyceride (mg/dl)	231.13±86.31	171.33±69.36*	0.001	195.33±47.19	203.40±44.87	0.63
MDA (nmol/l)	6.0±1.43	4.88±1.16*	0.020	5.02±0.97	5.18±1.04	0.90

Changes after intervention	Spirulina							Control
Changes after intervention	FBS(mg/ dl)	Insul (ng/dl)	TG (mg/dl)	TCHOL (mg/dl)	HDLCHOL (mg/dl)	LDLCHOL (mg/dl)	MDA (nm/l)	FBS(mg/ dl)	Insul (ng/dl)	TG(mg/ dl)	TCHOL (mg/dl)	HDLCHOLH (mg/dl)	LDLCHOL (mg/dl)	MDA (nm/l)
FBS (mg/dl)	-0.964**	-0.504	-0.532	-0.235	-0.051	-0.029	-0.045	-0.045	0.449	-0.252	-0.140	0.621	-0.383	0.162
FBS (mg/dl)	P=0.001	-0.504	-0.532	-0.235	-0.051	-0.029	-0.045	-0.045	0.449	-0.252	-0.140	0.621	-0.383	0.162
Insul (ng/dl)	-0.305	0.911**	0.129	0.222	-0.208	0.220	0.156	0.503	0.163-	-0.032	0.043	-0.389	0.279	0.112
Insul (ng/dl)	-0.305	P=0.001	0.129	0.222	-0.208	0.220	0.156	0.503	0.163-	-0.032	0.043	-0.389	0.279	0.112
TG (mg/dl)	-.184	0.182	0.761**	-0.269	-0.478	-0.430	-0.695**	-0.308	0.070	0.197	0.376	-.182	0.365	0.164
TG (mg/dl)	-.184	0.182	P=0.001	-0.269	-0.478	-0.430	-0.695**	-0.308	0.070	0.197	0.376	-.182	0.365	0.164
TCHOL (mg/dl)	-0.094	-.056	-0.130	0.742**	0.040	0.757**	0.063	0.143	-0127	0.463	0.279	-0.294	0.221	0.290
TCHOL (mg/dl)	-0.094	-.056	-0.130	P=0.001	0.040	0.757**	0.063	0.143	-0127	0.463	0.279	-0.294	0.221	0.290
HDL-CHOL (mg/dl)	-0.017	-0.173	-0.310	0.172	0.968**	0.008	0.188	0.060	0.010	0.190	0.088	-0.184	0.118	-0.340
HDL-CHOL (mg/dl)	-0.017	-0.173	-0.310	0.172	P=0.001	0.008	0.188	0.060	0.010	0.190	0.088	-0.184	0.118	-0.340
LDL-CHOL (mg/dl)	0.052	-0.006	-0.377	0.701**	-0.133	0.877**	0.280	0.317	-0.131	0.219	-0.025	-0.126	-0.065	0.295
LDL-CHOL (mg/dl)	0.052	-0.006	-0.377	P=0.001	-0.133	P=0.001	0.280	0.317	-0.131	0.219	-0.025	-0.126	-0.065	0.295
MDA (nm/l)	-0.004	0.086	-0.653*	0.094	0.261	0.285	0.961**	0.155	-0.022	-0.405	-0.422	-0.094	-0.252	0.281
MDA (nm/l)	-0.004	0.086	P=0.020	0.094	0.261	0.285	P=0.001	0.155	-0.022	-0.405	-0.422	-0.094	-0.252	0.281

Brasil

Brasil

Effect of Spirulina on Lipid Profile, Glucose and Malondialdehyde Levels in Type 2 Diabetic Patients

Abstract

INTRODUCTION

MATERIAL AND METHODS

Data Analysis

RESULTS

DISCUSSION

ACKNOWLEDGMENT

REFERENCES

ETHICS APPROVAL AND CONSENT TO PARTICIPATE:

FUNDING:

Publication Dates

History