1. Dias NC, Marinho NP, Barbalho SM, Araújo AC, Detregiachi CRP, Audi M, et al. Medicinal Plants in Physical Exercise: A Review. Europ J Med Plants. 2021;32(1):1-21. [
View at Publisher] [
DOI] [
Google Scholar]
2. Zeng Q, Man R, Luo Y, Zeng L, Zhong Y, Lu B, et al. IRF-8 is Involved in Amyloid-beta1-40. (Abeta1-40)-induced microglial activation: a new implication in Alzheimer's disease. J Mol Neurosci. 2017;63(2):159-64. [
View at Publisher] [
DOI] [
PMID] [
Google Scholar]
3. Amini M, Pedram MM, Moradi A, Jamshidi M, Ouchani M. GC-CNNnet: diagnosis of Alzheimer's Disease with PET Images Using Genetic and Convolutional Neural Network. Comput Intell Neurosci. 2022;2022:7413081. [
View at Publisher] [
DOI] [
PMID] [
Google Scholar]
4. Singh G, Kapoor IP, Pandey SK, Singh UK, Singh RK. Studies on essential oils: part 10; antibacterial activity of volatile oils of some spices. Phytother Res. 2002;16(7):680-2. [
View at Publisher] [
DOI] [
PMID] [
Google Scholar]
5. Abdollahi M, Farzamfar B, Salari P, Khorram Khorshid HR, Larijani B, Farhadi M, et al. Evaluation of acute and sub-chronic toxicity of Semelil (ANGIPARSTM), a new phytotherapeutic drug for wound healing in rodents. DARU J Pharm Sci. 2008;16(S1):7-14. [
View at Publisher] [
Google Scholar]
6. Parnow A, Gharakhanlou R, Gorginkaraji Z, Rajabi S, Eslami R, Hedayati M, et al. Effects of endurance and resistance training on calcitonin gene -related Peptide and acetylcholine receptor at slow and fast twitch skeletal muscles and sciatic nerve in male wistar rats. Int J Pept. 2012;2012:962651. [
View at Publisher] [
DOI] [
PMID] [
Google Scholar]
7. Reinsberger C. Of running mice and exercising humans - the quest for mechanisms and biomarkers of exercise induced neurogenesis and plasticity. German Journal of Sports Medicine/ Dtsch Z Sportmed. 2015;66(2):36-41. [
view at publisher] [
DOI] [
Google Scholar]
8. Breijyeh Z, Karaman R. Comprehensive Review on Alzheimer's Disease:Causes and Treatment. Molecules. 2020;25(24):5789. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
9. Tahvili F, Ahmadi M. The Effect of Endurance Training and Saffron Extract on Plasma Levels of Interleukin 17 and 18 in Alzheimer's Rats by Trimethyltin Chloride. Compl Med J Arak Univ Med Sci. 2020;10(2):148-59. [
view at publisher] [
DOI] [
Google Scholar]
10. Harutyunyan H, Sharoyan S, Antonyan A, Mardanyan S. Herbal preparations prevent beta-amyloid peptide induced hippocampal cell damage. Int J Herb Med.2017;5(4):92-105. [
view at publisher] [
Google Scholar]
11. Jafarzadeh GH, Shakerian S, Farbood Y, Ghanbarzadeh M. Effect of One Session of Resistance Exercises on Expression of BDNF Gene and TrkB Receptor in Alzheimer Model Male Wistar Rats. J Adv Biomed Sci. 2018;8(4):1167-76. [
view at publisher] [
DOI] [
Google Scholar]
12. Gabriele RMC, Abel E, Fox NC, Wray S, Arber C. Knockdown of Amyloid Precursor Protein: Biological Consequences and Clinical Opportunities. Front Neurosci. 2022;16:835645. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
13. Li WW, Shen YY , Tian DY , Bu XL , Zeng F , Liu YH , et al. Brain Amyloid-β Deposition and Blood Biomarkers in Patients with Clinically Diagnosed Alzheimer's Disease. J Alzheimers Dis. 2019;69(1):169-78. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
14. Bazazzadegan N, Dehghan Shasaltaneh M, Saliminejad K, Kamali K, Banan M, Khorram Khorshid HR. The Effects of Melilotus officinalis Extract on Expression of Daxx, Nfkb and Vegf Genes in the Streptozotocin-Induced Rat Model of Sporadic Alzheimer's Disease. Avicenna J Med Biotechnol. 2017;9(3):133-37. [
view at publisher] [
PMID] [
Google Scholar]
15. Schiavoni G, Mattei F, Sestili P, Borghi P, Venditti M, Morse HC III, et al. ICSBP is essential for the development of mouse type I interferon-producing cells and for the generation and activation of CD8alpha(+) dendritic cells. J Exp Med. 2002;196(11):1415-25. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
16. Golestani S, Edalatmanesh MA, Hosseini M. The effects of sodium valproate on learning and memory processes in trimethyltin model of Alzheimer's disease. Shefaye Khatam. 2014;2(3):19-26. [
view at publisher] [
DOI] [
Google Scholar]
17. Vasefi M, Ghaboolian-Zare E, Abedelwahab H, Osu A. Neurochemistry International Environmental toxins and Alzheimer's disease progression. Neurochem Int. 2020;141:104852. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
18. Masuda T, Tsuda M, Yoshinaga R, Tozaki-Saitoh H, Ozato K, Tamura T, et al. IRF8 is a critical transcription factor for transforming microglia into a reactive phenotype. Cell Rep. 2012:1(4):334-40. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
19. Bellenguez C, Küçükali F, Jansen IE, Kleineidam L, Grau SM, Amin N, et al. New insights into the genetic etiology of Alzheimer's disease and related dementias. Nature. Nat Genet. 2022:54(4):412-36. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
20. Hagemeyer N, Prinz M. Burning down the house: IRF7 makes the difference for microglia. EMBO J. 2014;33(24):2885-6. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
21. Frederiksen KS, Larsen CH, Hasselbalch SG, Christensen AN, Høgh P, Wermuth L, et al. A 16-Week Aerobic Exercise Intervention Does Not Affect Hippocampal Volume and Cortical Thickness in Mild to Moderate Alzheimer's Disease. Front Aging Neurosci. 2018;10:293. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
22. Glass CK, Saijo K, Winner B, Marchetto MC, Gage FH. Mechanisms underlying inflammation in neurodegeneration. 2010;140(6):918-34. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
23. Muñoz A, Costa M. Nutritionally mediated oxidative stress and inflammation. Oxid Med Cell Longev. 2013;2013:610950. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
24. Kim SJ, Schätzle S, Ahmed SS, Haap W, Jang SH, Gregersen PK, et al. Increased cathepsin S in Prdm1-/- dendritic cells alters the TFH cell repertoire and contributes to lupus. Nat Immunol. 2017;18(9):1016-24. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
25. Hu N, Yu JT, Tan L, Wang YL, Sun L, Tan L. Nutrition and the Risk of Alzheimer's Disease. Biomed Res Int. 2013;2013:524820. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
26. Pleşca‐Manea L, Pârvu AE, Parvu M, Taămaş M, Buia R, Puia M. Effects of Melilotus officinalis officinalis on acute inflammation. Phytother Res. 2002;16(4):316-9. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
27. Larijani B, Heshmat R, Bahrami A, Delshad H, Ranjbar Omrani G, Mohammad K, et al. Effects of intravenous Semelil (ANGIPARSTM) on diabetic foot ulcers healing: A multicenter clinical trial. DARU J Pharm Sci. 2008;16(S1):35-40. [
view at publisher] [
Google Scholar]
28. Safarpour AR, Kaviyani F, Sepehrimanesh M, Ahmadi N, Hosseinabadi OK, Tanideh N,et al. Antioxidant and Anti-Inflammatory Effects of Gel and Aqueous Extract of Melilotus officinalis L. in Induced Ulcerative Colitis: A Rattus norvegicus Model. Ann Colorectal Res. 2015;3(2):1-7. [
view at publisher] [
DOI] [
Google Scholar]
29. Chen XQ, Mobley WC. Exploring the Pathogenesis of Alzheimer Disease in Basal Forebrain Cholinergic Neurons: Converging Insights from Alternative Hypotheses. Front Neurosci. 2019;13:446. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
30. Irandoust K, Taheri M, Sadeghi A. The effect of exercise (swimming and running) on motor function, learning and spatial memory in elder male wistar rats. J Sports Motor Develop Learn. 2014;6(2):259-70. [
view at publisher] [
DOI]
31. Freitas GB, Lourenco MV, Felice FG. Protective actions of exercise-related FNDC5/Irisin in memory and Alzheimer's disease. J Neurochem. 2020;155(6):602-11. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
32. Bazyar Y, Edalatmanesh MA, Hosseini SA, Zar A. The effects of endurance training and gallic acid on BDNF and TNF-a in male rats with Alzheimer. Intern J Appl Exerc Physiol. 2016;5(4):45-54. [
view at publisher] [
Google Scholar]
33. Khodadadi D, Gharakhanlou R, Naghdi N, Salimi M, Azimi SM, Shahed A. The effect of 4 weeks of exercise preconditioning on soluble amyloid beta level and memory impairment in rats with Alzheimer's disease induced by Aβ1-42 injection. Razi J Med Sci. 2018;24(165):66-76. [
view at publisher] [
Google Scholar]
34. Vital TM, Soleman Hernández SS, Pedroso RV, Ligo Teixeira CV, Garuffi M, Stein AM, et al. Effects of weight training on cognitive functions in elderly with Alzheimer's disease. Dement Neuropsychol. 2012;6(4):253-59. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
35. Lee J. Effects of Aerobic and Resistance Exercise Interventions on Cognitive and Physiologic Adaptations for Older Adults with Mild Cognitive Impairment: A Systematic Review and Meta-Analysis of Randomized Control Trials. Int J Environ Res Public Health. 2020;17(24):9216. [
view at publisher] [
DOI] [
PMID] [
Google Scholar]
36. Pasand MH, Alipour F, Borhan Haghighi M. Alzheimer's disease: Background, current and future aspects. Shefaye Khatam. 2016;4(3):70-80. [
view at publisher] [
DOI] [
Google Scholar]
37. Alivand F, Karimzadeh F. The effect of exercise on the memory improvement: a review of cellular and molecular mechanisms. Shefaye Khatam. 2015;3(4):123-30. [
view at publisher] [
DOI] [
Google Scholar]
38. Yazdani H, Soltani Tehrani B, Babaei P. Effects of kiss peptin13 on spatial memory in streptozotocin-induced Alzheimer's disease (AD) in Rats. J Guilan Univ Med Sci. 2015;24(93):54-62. [
view at publisher] [
Google Scholar]