Vitamin D₃ dapat bertindak sebagai antioksidan yang melindungi neuron terhadap kerusakan disebabkan stres oksidatif. Efek neurotoksik yang dimediasi oleh meningkatnya stress oksidatif dapat disebabkan oleh etanol. Otak kecil adalah salah satu daerah otak yang paling sensitif terhadap efek neurotoksik yang disebabkan oleh etanol. Penelitian ini bertujuan untuk mengetahui efek neuroprotektif vitamin D₃ untuk mencegah penurunan jumlah sel Purkinje cerebellum terhadap efek neurotoksik diinduksi etanol. Lima belas jantan galur Wistar (Rattus norvegicus) dibagi secara acak menjadi tiga kelompok. Kelompok kontrol diberi larutan garam normal, kelompok etanol diberi larutan etanol 20% dengan dosis 3  g / kg BB / hari dan vitamin D3 kelompok diberikan vitamin D3 1 pg / kg BB / hari dalam etanol 20% solusi dengan dosis 3 g / kg BB / hari, intraperitoneal. Setelah 30 hari perlakuan, tikus perfusi dan otak kecil itu dibedah untuk persiapan histologis. Pewarnaan histologi dengan violet cresyl dengan metode fractionator. Hasil penelitian menunjukkan jumlah sel Purkinje cerebellum kelompok etanol (744,552 ± 208.172,22)  lebih kecil dari kelompok kontrol (957,240 ± 160.353,03) dan vitamin D3 (983,448  ± 152.387,49) , tetapi secara statistik tidak berbeda bermakna (p> 0,05) jumlah sel Purkinje cerebellum antara ketiga kelompok. Disimpulkan bahwa vitamin D3 belum terbukti  memiliki efek neuroprotektif untuk mencegah penurunan jumlah sel Purkinje cerebellum disebabkan oleh pemberian etanol selama 30  hari.

Vitamin D₃ can act as an antioxidant that protects neurons against damage caused by oxidative stress. Neurotoxic effects that are mediated by increased oxidative stress can be induced by the ethanol. Cerebellum is one of the brain regions most sensitive to neurotoxic effects induced by the ethanol. The purpose of this study was to determine the neuroprotective effects of vitamin D₃ to prevent the decrease in the number of cerebellar Purkinje cells to the neurotoxic effects induced by ethanol. Fifteen male Wistar rats (Rattus norvegicus) were randomly divided into three groups. The control group was given normal saline solution; the ethanol group was given 20% ethanol solution at a dose of 3 g/kg BW/ day; and the vitamin D₃ group was given vitamin D₃ 1 µg/kg BW/day in 20% ethanol solution at a dose of 3 g/kg BW/day, intraperitoneally. After 30 day treatment, the rats were perfused and the cerebellum was dissected for histological preparations. Histological staining with cresyl violet was performed to assess the number of cerebellar Purkinje cells by the method of fractionator. The results showed the number of cerebellar Purkinje cells in the ethanol group (744.552 ± 208.172,22) was less than the control group (957.240 ± 160.353,03) and vitamin D₃ (983.448 ± 152.387,49) , but statistically not significant difference ( p>0.05) on the number of cerebellar Purkinje cells among the three groups. It can be concluded that vitamin D₃ had not been proven for its neuroprotective effect to prevent the decrease in the number of cerebellar Purkinje cells caused by ethanol administration for 30 days.

Feldman D, Malloy PJ, Gross C. Vitamin D: Biology, Action and Clinical Implications. In: Marcus R, Feldman D, Nelson DA, Rosen CJ, editors. Osteoporosis, 2nd edition. San Diego: Elsevier Academic Press, 2001 :257-302

Bikle D. Nonclassic Actions of Vitamin D. J Clin Endocrinol Metab, 2009; 94 (1): 26-34.

Wiseman H. Vitamin D is A Membrane Antioxidant: Ability to Inhibit Iron-Dependent Lipid Peroxidation in Liposomes Compared to Cholesterol, Ergosterol and Tamoxifen and Relevance to Anticancer Action. FEBS Lett, 1993; 326 (1-3): 285-8.

Sardar S, Singh M. Vitamin D3 as A Modulator of Cellular Antioxidant Defence in Murine Lymphoma. Nutrition Research, 2000; 20 (1): 91102.

Lin AMY, Fan SF, Yang DM, Hsu LL, Yang CHJ. Zinc-Induced Apoptosis in Substantia Nigra of Rat Brain: Neuroprotection by Vitamin D3. Free Radic Biol Med, 2003; 34 (11): 1416-25.

Landfield PW, Cadwallader-Neal L. Long-term Treatment with Calcitriol (1,25(OH)2 vit D3) Retards A Biomarker Of Hippocampal Aging in Rats. Neurobiol Aging, 1998; 19 (5): 46977.

Sardar S, Chakrabotty A, Chatterjee M. Comparative Effectiveness of Vitamin D3 and Dietary Vitamin E on Peroxidation of Lipids and Enzymes of the Hepatic Antioxidant System in Sprague-Dawley Rats. Internat J Vitam Nutr Res, 1996; 66 (1): 39-45.

Kannan K, Jain SK. Oxidative Stress and Apoptosis. Pathophysiology, 2000; 7 (3): 15363.

Heaton MB, Mitchell JJ, Paiva M. Amelioration of Ethanol-Induced Neurotoxicity in the Neonatal Rat Central Nervous System by Antioxidant Therapy. Alcohol Clin Exp Res, 2000; 24 (4): 512-8.

Shirpoor A, Minassian S, Salami S, KhademAnsari MH, Ghaderi-Pakdel F, Yeghiazaryan M. Vitamin E Protects Developing Rat Hippocampus and Cerebellum Against Ethanol-Induced Oxidative Stress and Apoptosis. Food Chemistry, 2008; 113 (2009): 115-20.

World Health Organization. WHO Global Status Report on Alcohol 2004. Geneva: World Health Organization, 2004. Available from URL: http://www.searo.who.int/LinkFiles/Alcohol_ and_Substance_abuse_Indonesia.pdf.

Diamond I, Messing RO. Neurologic Effects of Alcoholism. West J Med, 1994; 161 (3): 27987.

Butterfield DA, Howard B, Yatin S, Koppal T, Drake J, Hensley K, et al. Elevated Oxidative Stress in Models of Normal Brain Aging and Alzheimer’s Disease. Life Sci, 1999; 65 (1819): 1883-92.

Maier SE, West JR. Alcohol and Nutritional Control Treatments During Neurogenesis in Rat Brain Reduce Total Neuron Number in

Locus Coeruleus, But Not in Cerebellum or Inferior Olive. Alcohol, 2003; 30 (1): 67-74.

Chen SY, Sulik KK. Free Radical and EthanolInduced Cytotoxicity in Neural Crest Cells. Alcohol Clin Exp Res, 1996; 20 (6): 1071-6.

Henderson GI, Chen JJ, Schenker S. 1999. Ethanol, Oxidative Stress, Reactive Aldehydes and the Fetus. Front Biosci, 1999; 4: D54150.

Miki T, Harris S, Wilce P, Takeuchi Y, Bedi KS. The Effect of the Timing of Ethanol Exposure During Early Postnatal Life on Total Number of Purkinje cells in Rat Cerebellum. J Anat, 1999 ; 194 (Pt 3): 423-31.

Chen WJ, Parnell SE, West JR. Neonatal Alcohol and Nicotine Exposure Limits Brain Growth and Depletes Cerebellar Purkinje Cells. Alcohol, 1998; 15 (1): 33-41.

Maier SE, West JR. Regional Differences in Cell Loss Associated with Binge-Like Alcohol Exposure During the First Two Trimesters Equivalent in the Rat. Alcohol, 2001; 23 (1): 49-57.

Thomas JD, Goodlett CR, West JR. AlcoholInduced Purkinje Cell Loss Depends on Developmental Timing of Alcohol Exposure and Correlates with Motor Performance. Brain Res Dev Brain Res, 1998; 105 (2): 159-66.

Ge Y, Belcher SM, Pierce DR, Light KE. Detection of Purkinje Cell Loss Following Drug Exposures to Developing Rat Pups using Reverse Transcriptase-Polymerase Chain Reaction (RT-PCR) Analysis for Calbindin-D28k mRNA Expression. Toxicol Lett , 2004; 150 (3): 325-34.

Pauli J, Wilce P, Bedi KS. Acute Exposure to Alcohol during Early Postnatal Life Causes A Deficit in the Total Number of Cerebellar Purkinje Cells in the Rat. J Comp Neurol, 1995; 360 (3): 506-12.

Renis M, Calabrese V, Russo A, Calderone A, Barcellona ML, Rizza V. Nuclear DNA Strand Breaks during Ethanol-Induced Oxidative Stress in Rat Brain. FEBS Lett, 1996; 390 (2): 153-6.

Montoliu C, Sancho-Tello M, Azorin I, Burgal M, Valles S, Renau-Piqueras J, et al. Ethanol Increases Cytochrome P4502E1 and Induces Oxidative Stress in Astrocytes. J Neurochem, 1995; 65 (6): 2561-70.

Hunt JV, Smith CC, Wolf SP. Autooxidative Glycosylation and Possible Involvement of Peroxides and Free Radicals in LDL Modification by Glucose. Diabetes, 1990; 39 (11): 1420-4.

Coleman MD, Eason CR, Bailey JC. The Therapeutic use of Lipoic Acid in Diabetes: A Current Perspective. Environ Toxicol Pharmacol, 2001; 10 (4): 167-72.

Hockenbery H, Oltvai Z, Yin X, Milliman C, Korsmeyer S. Bcl-2 Functions in an Antioxidant Pathway to Prevent Apoptosis. Cell, 1993; 75 (2): 241-51.

Ibi M, Sawada H, Nakanishi M, Kume T, Katsuki H, Kaneko S, et al. Protective Effects of 1 Alpha, 25-(OH)(2)D(3) Against the Neurotoxicity of Glutamate and Reactive Oxygen Species in Mesencephalic Culture. Neuropharmacology, 2001; 40 (6): 761-71.

Prufer K, Veenstra TD, Jirikowski GF, Kumar R. Distribution of 1,25-Dihydroxyvitamin D3 Receptor Immunoreactivity in the Rat Brain and Spinal Cord. J Chem Neuroanat, 1999; 16 (2): 135-45.

Langub MC, Herman JP, Malluche HH, Koszewski NJ. Evidence of Functional Vitamin D Receptors in Rat Hippocampus. Neuroscience, 2001; 104 (1): 49-56.