WikiJournal of Science/The effect of local millet drink (Kunu) on the testis and epididymis of adult male wistar rats
WikiJournal of Science
Open access • Publication charge free • Public peer review • Wikipedia-integrated
Previous
Volume 1(1)
Volume 1(2)
Volume 2(1)
Volume 3(1)
Volume 4(1)
Volume 5(1)
Volume 6(1)
This article has been through public peer review.
Post-publication review comments or direct edits can be left at the version as it appears on Wikipedia.First submitted:
Accepted:
Reviewer comments
PDF: Download
DOI: 10.15347/WJS/2024.001
QID: Q104785241
XML: Download
Share article
Email
| Facebook
| Twitter
| LinkedIn
| Mendeley
| ResearchGate
Suggested citation format:
Ezejindu Damian Nnabuihe; Udodi Princewill Sopuluchukwu; Enemuo Chidili Ijeoma et al. (1 March 2024). "The effect of local millet drink (Kunu) on the testis and epididymis of adult male wistar rats". WikiJournal of Science 7. doi:10.15347/WJS/2024.001. Wikidata Q104785241. ISSN 2470-6345. https://upload.wikimedia.org/wikiversity/en/a/ae/The_effect_of_local_millet_drink_%28Kunu%29_on_the_testis_and_epididymis_of_adult_male_wistar_rats.pdf.
Citation metrics
AltMetrics
Page views on Wikipedia
Wikipedia: Content from this work is used in the following Wikipedia article: Kunu.
License: This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction, provided the original author and source are credited.
Editors:Thomas Shafee contact
Reviewers: (comments)Ebrahim Talebi
Charles Bristone
Ghadeer Bustani
Article information
Abstract
Kunu is a local beverage drink that finds its origin in the northern part of Nigeria. This study was aimed at determining the effect of the liquid drink on the epididymis, testes, sperm parameters, and hormonal assay.
Methods: A total of sixteen rats were used for this study and the animals were separated into four groups of four rats each (A-D). The animals were then sacrificed and the testes and epididymis were harvested and fixed in 10% formal saline. Group A was fed only rat feed and water. Groups B, C, and D were fed 0.2 ml, 0.9 ml, and 2.5 ml of Kunu respectively orally using a metal cannula for 21 days.
Findings: There was a significant increase (P<0.05) in the relative testicular weights of groups B, C, and D as compared with those of group A. There was a significant decrease (P<0.05) in sperm count in groups B, C, and D when compared to group A. There was an insignificant increase (P>0.05) in FSH in groups B, C, and D when compared to group A. The histopathological findings revealed that the group B rats of 0.2ml and group C rats of 0.9ml showed epididymal tissue with moderate accumulation of spermatozoa and testicular tubules with moderately enhanced spermatogenesis. The group D rats showed well-accumulated spermatozoa in the epididymal lumen and improved spermatogenesis in the testis as did group A.
Conclusion: Kunu beverage may not be used as a natural male fertility booster since it does little to improve sperm count, motility, morphology, pH, and hormonal levels of FSH and testosterone.
To test if the Kunu drink from Nigeria may be useful for fertility in men, we measured its effects in Wistar rats by feeding them different amounts of Kunu over 21 days. Although Kunu caused a small increase in testicle weight, it slightly lowered sperm count and caused no other major changes in sperm when viewed under a microscope or in the rats’ male hormones. These results in rats mean it’s unlikely that Kunu improves fertility in people.
Introduction
In a sexual world like ours, there is an urgency for people across the globe to meet their sexual needs daily. The problem of infertility touches on several factors which affect both males and females. In cases of male factor infertility which concentrates on testicular activity and sperm production as well as libido, there are two options for raising testosterone production and enhancing sperm production which is: the use of synthetic steroids and natural boosters.[1]
The use of synthetic steroids such as synthetic testosterone and gonadotropins has adverse effects such as reduced testes size, micturition problems, gynecomastia, sleep disturbances, etc.,[1] which is why a better approach to the problem of male factor infertility (due to azoospermia, oligospermia or any other related spermatic problem) may be the use of natural boosters of which the local northern drink Kunu (Figure 1) is a prominent example.
Kunu is a popular drink (Figure 1) consumed throughout Nigeria but mostly in the North. It can be made from grains such as millet, sorghum, maize, and rice. The variety of drinks made from sorghum is a milky light-brown color while that of maize or millet is whitish. Generally, consumption cuts across all age groups and social status with the peak of consumption being the hot season of the year (February – June) when it is served chilled, particularly Kunun Zaki.[2]
Testes, also called testicle in animals, is the organ that produces sperm and androgen. In humans, the testes occur as a pair of oval-shaped organs. Both functions of the testes are influenced by gonadotropic hormones produced by the anterior pituitary gland. Luteinizing hormone (LH) is also produced but the anterior pituitary gland results in testosterone release. Both hormones are needed to support the process of spermatogenesis.[3] There are two phases in which the testes grow substantially: namely in embryonic and pubertal stages.[4] After puberty, the volume of the testes is increased compared to the pre-pubertal size.
Hence, this work set out to assess the effects of Kunu on histomorphology of the testes and epididymis, and parameters of sperm count, sperm motility, and sperm viability using the short-term in vivo assays in adult male Wistar rats.
Methods
Materials
The following materials were used in this experiment: Sixteen male Wistar rats, oral cannula, Kunu (local beverage), four standard cages, distilled water, cotton wool and hand gloves, beakers and measuring cylinder, animal weighing balance (CAMRY LB11), electronic weighing balance (NAPCO Precision Instruments JA-410), diethyl Ether, vital top feed (Jos, Nigeria), dissecting kit, EDTA container and plain container, micro-hematocrit centrifuge SH120, capillary tube, 5 ml hypodermic syringe, Deep and flat feeding plates, Plastic bottles, 10% buffered formalin, hemocytometer, filter paper (Whatman qualitative filter paper n. 1, sigma Aldrich WHA1001042), thermostat oven (DHG-9023A, PEC MEDICAL USA), and spectrophotometer (Model 721).
Preparation of Kunu
Millet grains were soaked in a bowl of water and left overnight. The soaked millet was mixed with chops of dried sweet potatoes and ginger and blended into a paste. The paste mixture was divided into two equal parts; the one part was stirred with boiling water and left to cool. The other part was then poured into this mixture, and the new mixture was then stirred to achieve thickness, and then sieved to remove the chaff.
Experimental Animal
Sixteen male Wistar rats weighing between 170-200 g were used for this study. The animals were allowed to acclimatize for two weeks, after which they were randomly selected into 4 groups of 4 animals each.
Group A served as a control (the animals received only water and feed). Group B received 100 mg/kg or 0.2 ml of Kunu. Group C received 400 mg/kg or 0.9 ml of Kunu. Group D received 1200 mg/kg or 2.5 ml of Kunu.
The administration of drinks lasted for 21 days, taking place between 7 to 10 am daily. The animals were then sacrificed after the aforementioned period, semen and blood collected for seminal analysis and hormonal assay test, while the testes and epididymis were harvested for histopathological findings.
Acute Toxicity Test (LD50) of Kunu
The acute toxicity test of Kunu (local beverage) was carried out in the Department of Anatomy, Faculty of Basic Medical Sciences, Nnamdi Azikiwe University, Nnewi Campus, Nnewi, Anambra State according to the method employed by Lorke.[5] No toxic effect was observed on the treatment of Kunu drink up to the effective dose of 5000 mg/kg body weight of adult Wistar rats. The behavior of the treated rats appeared normal, and no deaths occurred.
Procedure for Semen Collection
The caudal epididymis was isolated from the testes and lacerated in a warm physiological solution to collect semen for sperm characteristics studies. A sperm count was conducted according to the method described by Hafez[6] using a microscope with an improved Neubauer hemocytometer. Sperm motility (%) was determined through a light microscope within 5 minutes of isolation of sperm from the epididymis.[7] Sperm viability was examined based on the method reported by Bearden and Fuquay.[8] Eosin and Fast Green were used to distinguish motile (live) sperm from non-motile groups (dead) sperm. These sperm cells were counted under 40× magnification. The average count of motile and non-motile groups was recorded, from which the viability percentage was calculated. The number and percentage of normal sperm were determined according to the method proposed by Chemineau et al.[9] based on the slides used for the calculation of sperm viability.
Procedure for Hormonal Assay
Testosterone Test
Testosterone levels were determined in the serum of male rats by Elecsys Analyzer, D-Vi-S, using kits from Roche Diagnostics GmbH, D-68298, Mannheim, Germany.
Determination of Follicle Stimulating Hormone by Radioimmunoassay Technique
Serum levels of follicle-stimulating hormone (FSH) were assayed by RIA using reagents supplied by Rat Pituitary Distribution and NIDDK (Bethesda, MD, USA)
Statistical Analysis
The statistical analysis of this research was done using Analysis of Variance (ANOVA) followed by multiple comparison using least statistical difference (LSD) and Student’s t-test in the SPSS version 23 software package and P < 0.05 was considered as the level of statistical significance.
Results and discussion
The male hormones are typically adequate to produce healthy sperms, however when this is not the case, many men take fertility drugs to increase their sperm count and motility. Indeed, there is ample evidence indicating a steady decline in human sperm count and quality.[10] The anterior pituitary is responsible for controlling the male hormones from the testes, hence, sperm production. Around 2% of men with infertility experience secondary hypogonadism (pituitary gland disease). This condition is treatable by either pharmaceutical or natural means. There are very few drugs, approved by the U.S. Food and Drug Administration (FDA), may help in stimulating sperm production such as clomiphene, letrozole, synthetic testosterone pills, bromocriptine, imipramine, etc.,[11] yet often these come with various side effects such as breast enlargement, changes in libido, liver problems, high blood pressure, etc.[12] Hence, there is a growing call, despite the low cost and commonness of these drugs, to use natural remedies (such as the beverage, Kunu, that this study chose to investigate) to address low fertility whilst aiming to avoid adverse effects.
The results of this study showed that there was no significant change in weight of the experimental rat groups B, C, and D just as that of the control (Table 1). This could be attributed to the low fat and protein content of the beverage. This study differs from the report made by Abolfazl et al.[13] who reported that Zingiber officinale (ginger), a condiment of Kunu, increased the body weight significantly in Wistar rats at 1 g/kg of body weight.
Groups | Body weight (g) | Mean ± SEM | P - Value | T- Value |
---|---|---|---|---|
Group A | Initial | 160.00 ± 20.00 | 0.588 | -0.640 |
Final | 176.66 ±14.52 | |||
Group B | Initial | 186.67 ± 8.81 | 0.208 | -1.835 |
Final | 213.33 ±12.01 | |||
Group C | Initial | 173.33 ± 8.81 | 0.225 | -1.732 |
Final | 203.33 ± 8.81 | |||
Group D | Initial | 183.33 ± 6.66 | 0.221 | -1.075 |
Final | 193.33 ± 6.66 |
- Data were analyzed using One-way ANOVA, and data were considered significant at P < 0.05* and P > 0.05 means not significant.
There was a significant increase (P < 0.05) in the relative testicular weight in the other groups when compared with the control group (Table 2). This agrees with the discovery of Ekaluo et al.[14] who reported a significant increase in the weight of the testis of albino rats administered with Cyperus esculentus (used in making Kunu aya) 1.8g/kg body weight which is due to the availability of the antioxidant vitamin C in Kunu and its protective role against oxidative stress and morphological changes of the testicular tissues. Results also revealed a significant decrease (P < 0.05) in relative epididymal weight group B compared to the control. The mechanism of this discrepancy is not understood, more so it disagrees with the work of Ekaluo et al.[14] who reported increasing weight of epididymis of the rats given an aqueous extract of Cyperus esculentus 1.8 g/kg body weight.
Organ weight | Group | Mean ±SEM | P-value | F-value |
---|---|---|---|---|
Relative testicular weight (g) | Group A | 0.60 ±0.00 | ||
Group B | 0.77 ±0.00 | 0.000* | 39.661 | |
Group C | 0.78 ±0.01 | 0.000* | ||
Group D | 0.71 ±0.02 | 0.000* | ||
Relative epididymis weight (g) | Group A | 0.50 ±0.00 | ||
Group B | 0.37 ±0.05 | 0.014* | 6.606 | |
Group C | 0.34 ±0.01 | 0.005* | ||
Group D | 0.46 ±0.02 | 0.444 |
- Data were analyzed using One-way ANOVA, followed by LSD comparison, and data were considered significant at P < 0.05 and P > 0.05 means not significant, it is also significant at the level of 0.01 and less.
There was a significant decrease (P < 0.05) in sperm motility in the experimental groups when compared with the control (Table 3). This does not agree with the findings of Abolfazl et al.[13] who state increased levels of sperm viability and motility of the Wistar rats given Zingiber officinale, found in Kunu, at 1g/kg body weight. There was also a significant (P > 0.05) decrease in the total sperm count in group B and an insignificant (P < 0.05) decrease in groups C, and D when compared to the control. This contradicts the findings of Hafez[6] who reported a significant increase in sperm quality and quantity of Wistar rats fed with 2 g/kg body weight of ginger roots and cinnamon bark.
Sperm parameters | Groups | Mean ±SEM | P-value | F-value |
---|---|---|---|---|
Sperm Motility (%) | Group A | 90.00 ±2.88 | ||
Group B | 83.33 ±1.67 | 0.047* | 13.888 | |
Group C | 76.67 ±1.66 | 0.002* | ||
Group D | 73.00 ±1.52 | 0.000* | ||
Total Sperm Count (x10^6/L) | Group A | 6.80 ±0.05 | ||
Group B | 3.81 ±0.07 | 0.459 | 13.636 | |
Group C | 6.38 ±0.27 | 0.001* | ||
Group D | 6.58 ±0.69 | 0.701 |
- Data were analyzed using One-way ANOVA, followed by LSD comparison, and data were considered significant at P < 0.05 and P > 0.05 means not significant, it is also significant at the level of 0.01 and less.
Sperm pH in groups B, C, and D slightly increased when compared to the control group A (Table 4). This is in concordance with the work of Ekaluo et al.[14] on the effects of aqueous extract of Cyperus esculentus on male albino rats at 1.8 g/kg per body weight which revealed a concomitant improvement in semen pH. This is due to higher sperm production as a result of an increase in testosterone stimulation of the spermatogonia cells to undergo successful spermatogenesis, sperm maturation in the epididymis and the secretory activity of the accessory sex glands as a result of the acidic pH environment provided by Kunu.
Sperm parameters | Group | Mean SEM | P-value | F-value |
---|---|---|---|---|
Sperm pH | Group A | 6.16 ±0.16 | ||
Group B | 6.33 ±0.16 | 0.650 | 1.296 | |
Group C | 6.50 ±2.88 | 0.650 | ||
Group D | 6.83 ±0.33 | 0.096 |
- Data were analyzed using One-way ANOVA, followed by LSD comparison and data were considered significant at P < 0.05 and P > 0.05 means not significant, it is also significant at the level of 0.01 and less.
The tabular results also evidence a significant (P < 0.05) decrease in testosterone levels in the test groups when compared with the control group (Table 5). This sharply contrasts with the report of Ayodele et al.[15] on their work on ginger and cinnamon on male albino rats at 10 mg/kg body weight.
Hormone | Groups | Mean ±SEM | P-value | F-value |
---|---|---|---|---|
Follicular Stimulating Hormone (uIu/L) | Group A | 2.80 ±0.10 | ||
Group B | 2.73 ±0.08 | 0.771 | 0.545 | |
Group C | 2.70 ±0.05 | 1.000 | ||
Group D | 2.60 ±0.05 | 0.392 | ||
Testosterone (ng/mL) | Group A | 4.80 ±0.05 | ||
Group B | 4.03 ±0.12 | 0.001* | 16.700 | |
Group C | 4.10 ±0.15 | 0.002* | ||
Group D | 3.80 ±0.05 | 0.000* |
- Data were analyzed using One-way ANOVA followed by LSD comparison and data were considered significant at P < 0.05 and P > 0.05 means not significant, it is also significant at the level of 0.01 and less.
An insignificant decrease (P > 0.05) in normal sperm in group B and C and an insignificant increase (P > 0.05) in group D was recorded (Table 6) as compared with group A and this counters Khaki et al.[16] who worked on the Anti-oxidant effect of Ginger and Cinnamon on Spermatogenesis Dys-function of Diabetes Rats. There was an insignificant (P > 0.05) decrease in abnormal sperm in group B and D and an insignificant increase (P > 0.05) in group C when compared to group A. This is in agreement with the work of Ekaluo et al.[14] that states that there was no significant (P > 0.05) effect of aqueous extract of Cyperus esculentus on sperm head abnormality but slight increases in a dose-dependent manner.
Hormone | Groups | Mean ±SEM | P-value | F-value |
---|---|---|---|---|
Normal Sperm (%) | Group A | 86.67 ±3.33 | ||
Group B | 86.66 ±1.67 | 1.000 | 0.667 | |
Group C | 86.00 ±1.67 | 1.000 | ||
Group D | 90.00 ±0.00 | 0.282 | ||
Abnormal Sperm (%) | Group A | 13.37 ± 3.33 | ||
Group B | 13.33 ±1.67 | 1.000 | 0.667 | |
Group C | 14.00 ±1.67 | 1.000 | ||
Group D | 10.00 ±0.00 | 0.282 |
- Data were analyzed using One-way ANOVA followed by LSD comparison, and data were considered significant at P < 0.05 and P > 0.05 means not significant, it is also significant at the level of 0.01 and less.
Histopathological results of photomicrographs (Figures 2 and 3) showed moderate epididymal accumulation of spermatozoa and testicular tissue with slightly enhanced seminiferous tubules and mildly improved spermatogenesis. This opposes the work of Arash et al.[16] who reported that 100 mg/kg ginger and cinnamon fed rats showed increased spermatogenesis and testicular architecture. Dissimilar results were also found by the administration of Cyperus esculentus (Kunu aya) by Ekaluo et al.[14] in male albino rats. Also, 2.5 ml of Kunu shows well enhanced epididymal architecture as well as accumulated luminal spermatozoa with a corresponding enhanced testicular tissue and well improved spermatogenesis. This hardly corresponds with the study carried out by Ayodele et al.[15] on dietary supplementation of ginger and turmeric improves reproductive function in hypertensive male rats and that carried out by Ekaluo et al.,[14] the effect of aqueous extract of Cyperus esculentus who reported improved spermatogenesis and testicular tissue enhancement in the 180 mg/kg administration of ginger, a major condiment of Kunu.
Conclusion
In conclusion, this scientific study shows that local millet drink, Kunu (Kunu-zaki) even though a product of ginger (which has antioxidant and androgenic properties with the capacity of increasing sperm parameters) does little to improve sperm count, motility, morphology, pH, and hormonal levels of FSH and testosterone in Wistar rat. Kunu instead attempts to maintain or slightly reduce normal levels of these parameters and the testicular and epididymal architectures. These negative results in the Wistar rat animal model indicate that Kunu is unlikely to act as a natural fertility booster in males.
Additional information
Acknowledgements
I sincerely acknowledge the Department of Anatomy, Faculty of Basic Medical sciences, Nnamdi Azikiwe University for their support in the course of this research work.
Competing interests
No conflict of interest.
Ethics statement
Ethical approval with the ethical number; NAU/FBMS/ETH-123 was obtained from the ethical committee, Faculty of Basic Medical Sciences, College of Health Sciences, Nnamdi Azikiwe University.
Location of Study
This study was carried out at the Animal House of the Faculty of Basic Medical Sciences, College of Health Sciences, Nnamdi Azikiwe University, Nnewi Campus, Anambra State. Ethical approval was also obtained from the ethical committee.
Author contributions
Damian Nnabuihe Ezejindu supervised the findings of this work and contributed to the development of the novel theory. Princewill Sopuluchukwu Udodi prepared the manuscript for publication, analyzed the anthropometric data collected and interpreted the histological slides. Enemuo Chidili Ijeoma sourced for the literatures. Okafor Emeka Christian and Okeke Somadina Nnamdi took part in breeding the animals used for the study, Agulanna Ambrose Echefulachi, Ifeanacho Ezetaonu Abireh, Idorenyin Umoh and Kingsley Akaninyene Okon interpreted the micrographs while Okara Andy-Davis Chidi assisted in tissue processing.
References
- ↑ 1.0 1.1 Bazar, RM (2011). Healthy Prostate: The Extensive Guide To Prevent and Heal Prostate Problems Including Prostate Cancer, BPH Enlarged Prostate and Prostatitis. Mansons Landing, British Columbia: Self-published. ISBN 978-1466369252.
- ↑ Terna, G; Jideani, IA; Nkama, I (2002). "Nutritional composition of different types of kunu produced in gauche and gumbo states of Nigeria". International Journal of Food Properties 5 (2): 351–357. doi:10.1081/JFP-120005790. https://www.tandfonline.com/doi/full/10.1081/JFP-120005790.
- ↑ Skinner, MK; Fritz, IB (1985). "Testicular peritubular cells secrete a protein under androgen control that modulates Sertoli cell functions". Proceedings of the National Academy of Sciences 82 (1): 114–118. doi:10.1073/pnas.82.1.114. https://www.pnas.org/doi/abs/10.1073/pnas.82.1.114.
- ↑ Gilbert, SF (2000). Developmental Biology (6th ed.). Sunderland, Massachusetts: Sinauer Associates. ISBN 978-0878932436. https://www.ncbi.nlm.nih.gov/books/NBK9983/.
- ↑ Lorke, D (1983). "A new approach to practical acute toxicity testing". Archives of Toxicology 54 (4): 275–287. doi:10.1007/BF01234480. https://link.springer.com/article/10.1007/BF01234480.
- ↑ 6.0 6.1 Hafez, DA (2010). "Effect of extracts of ginger roots and cinnamon bark on fertility of male diabetic rats". Journal of American Science 6 (10): 940–947. https://www.jofamericanscience.org/journals/am-sci/am0610/111_3708am0610_940_947.pdf.
- ↑ Ige, SF; Olaleye, SB; Akhigbe, RE; Akanbi, TA; Oyekunle, OA; Udoh, U-AS (2012). "Testicular toxicity and sperm quality following cadmium exposure in rats: Ameliorative potentials of Allium cepa". Journal of Human Reproductive Sciences 5 (1): 37–42. doi:10.4103/0974-1208.97798. https://journals.lww.com/jhrs/fulltext/2012/05010/testicular_toxicity_and_sperm_quality_following.8.aspx.
- ↑ Bearden, HJ; Fuquay, JW (1992). Applied Animal Reproduction (3rd ed.). Englewood Cliffs, New Jersey: Prentice Hall. ISBN 9780130403469.
- ↑ Chemineau, P; Geuenin, Y; Orgeur, P; Vallel, C (1991). Training Manual on Artificial Insemination in Sheep and Goats. Rome: Food and Agriculture Organization of the United Nations. ISBN 9789251028087.
- ↑ Kumar, P; Kumar, N; Thakur, DS; Patidar, A (2010). "Male hypogonadism: Symptoms and treatment". Journal of Advanced Pharmaceutical Technology & Research 1 (3): 297–301. doi:10.4103/0110-5558.72420. https://journals.lww.com/japtr/fulltext/2010/01030/Male_hypogonadism__Symptoms_and_treatment.5.aspx.
- ↑ Ochsenkühn, R; Kamischke, A; Nieschlag, E (1999). "Imipramine for successful treatment of retrograde ejaculation caused by retroperitoneal surgery". International Journal of Andrology 22 (3): 173–177. doi:10.1046/j.1365-2605.1999.00165.x. https://onlinelibrary.wiley.com/doi/10.1046/j.1365-2605.1999.00165.x.
- ↑ Malachi, R (25 June 2018). "7 fertility drugs for men to boost sperm count and motility". MomJunction. Archived from the original on 21 July 2018. Retrieved 14 July 2022.
- ↑ 13.0 13.1 Akbari, A; Nasiri, K; Heydari, M; Mosavat, SH; Iraji, A (2017). "The protective effect of hydroalcoholic extract of Zingiber officinale Roscoe (ginger) on ethanol-induced reproductive toxicity in male rats". Journal of Evidence-Based Complementary & Alternative Medicine 22 (4): 609–617. doi:10.1177/2156587216687696. https://journals.sagepub.com/doi/10.1177/2156587216687696.
- ↑ 14.0 14.1 14.2 14.3 14.4 14.5 Ekaluo, UB; Ikpeme, EV; Etta, SE; Ekpo, PB (2014). "Effect of aqueous extract of tigernut (Cyperus esculentus L.) on sperm parameters and testosterone level of male albino rats". Asian Journal of Biotechnology 7 (1): 39–45. doi:10.3923/ajbkr.2015.39.45. https://scialert.net/abstract/?doi=ajbkr.2015.39.45.
- ↑ 15.0 15.1 Akinyemi, AJ; Adedara, IA; Thome, GR; Morsch, VM; Rovani, MT; Mujica, LKS; Duarte, T; Duarte, M et al. (2015). "Dietary supplementation of ginger and turmeric improves reproductive function in hypertensive male rats". Toxicology Reports 2: 1357–1366. doi:10.1016/j.toxrep.2015.10.001. https://www.sciencedirect.com/science/article/pii/S2214750015300652?via%3Dihub.
- ↑ 16.0 16.1 Khaki, A; Khaki, AA; Hajhosseini, L; Golzar, FS; Ainehchi, N (2014). "The anti-oxidant effects of ginger and cinnamon on spermatogenesis dys-function of diabetes rats". African Journal of Traditional, Complementary and Alternative Medicines 11 (4): 1–8. doi:10.4314/ajtcam.v11i4.1. https://www.ajol.info/index.php/ajtcam/article/view/106308.