| Literature DB >> 23384060 |
Hatem M Abuohashish1, Salim S Al-Rejaie, Khaled A Al-Hosaini, Mihir Y Parmar, Mohammed M Ahmed.
Abstract
<span class="abstract_title">BACKGROUND: Plant <span class="Chemical">flavonoids are emerging as potent therapeutic drugs effective against a wide range of aging diseases particularly bone metabolic disorders. Morin (3,5,7,20,40-pentahydroxyflavone), a member of flavonols, is an important bioactive compound by interacting with nucleic acids, enzymes and protein. The present study was designed to investigate the putative beneficial effect of morin on diabetic osteopenia in rats.Entities:
Year: 2013 PMID: 23384060 PMCID: PMC3582624 DOI: 10.1186/1758-5996-5-5
Source DB: PubMed Journal: Diabetol Metab Syndr ISSN: 1758-5996 Impact factor: 3.320
Figure 1Effects of morin on (A) animals final body weight, (B) blood glucose and (C) insulin levels. Data were expressed as Mean±S.EM (n=6) and analyzed using one-way ANOVA followed by Student Newman-Keuls as post hoc test. ***a P<0.001 and **a P<0.01 Control vs STZ group; *b P<0.05 STZ vs. STZ+M15 or STZ+M30 groups.
Effects of morin on trabecular morphometric parameters measured by micro-CT in femur head of diabetic rats
| BMD (g/cm3) | 0.772±0.022 | 0.627±0.011**a | 0.653±0.034 | 0.732±0.025*b |
| BV/TV (%) | 0.444±0.021 | 0.277±0.021**a | 0.341±0.018 | 0.369±0.028*b |
| SMI | 0.874±0.101 | 1.655±0.101**a | 1.381±0.131 | 1.298±0.137 |
| Tb.N (mm-1) | 3.534±0.143 | 2.515±0.197*a | 2.914±0.165 | 3.339±0.202*b |
| Tb.Sp (mm) | 0.173±0.011 | 0.224±0.009*a | 0.197±0.002 | 0.176±0.009*b |
| Tb.Th (mm) | 0.123±0.002 | 0.107±0.002**a | 0.115±0.001 | 0.118±0.002*b |
| Tb.Po (%) | 58.614±1.382 | 66.537±0.611*a | 61.038±1.643 | 58.285±2.532*b |
Data were expressed as Mean±S.EM (n=6) and analyzed using one-way ANOVA followed by Student Newman-Keuls as post hoc test. *a P<0.05 and **a P<0.01 Control vs STZ group; *b P<0.05 STZ vs. STZ+M15 or STZ+M30 groups.
Figure 23D micro CT image showing morin protective effects on trabecular bone (Green portion) of the femur head of normal and diabetic rats.
Figure 3Effects of morin on serum levels of (A) DPD, (B) OC, (C) BALP and (D) CTX in diabetic rats. Data were expressed as Mean±S.EM (n=6) and analyzed using one-way ANOVA followed by Student Newman-Keuls as post hoc test. *a P<0.05 and **a P<0.01 Control vs STZ group; *b P<0.05 and **b P<0.01 STZ vs. STZ+M15 or STZ+M30 groups.
Figure 4Effects of morin on serum levels of (A) IL-1β, (B) IL-6 and (C) TNF-α in diabetic rats. Data were expressed as Mean±S.EM (n=6) and analyzed using one-way ANOVA followed by Student Newman-Keuls as post hoc test. *a P<0.05 and **a P<0.01 Control vs STZ group; *b P<0.05 STZ vs. STZ+M15 or STZ+M30 groups.
Figure 5Effects of morin on serum levels of (A) TBARS and (B) GSH in diabetic rats. Data were expressed as Mean±S.EM (n=6) and analyzed using one-way ANOVA followed by Student Newman-Keuls as post hoc test. *a P<0.05 and **a P<0.01 Control vs STZ group; *b P<0.05 STZ vs. STZ+M15 or STZ+M30 groups.