Protective actions of melatonin and growth hormone on the aged cardiovascular system.
Study Goal
The researchers aimed to determine whether melatonin, alone or combined with growth hormone (GH), could counteract oxidative stress, apoptosis, and inflammation in the aging heart using a senescence-accelerated mouse model.
Results Summary
Melatonin treatment prevented age-dependent cardiac alterations in senescence-accelerated prone mice, reducing oxidative stress, inflammation, and apoptosis markers while increasing anti-inflammatory and antiapoptotic markers. Combined administration with GH showed additive benefits compared to either hormone alone.
Population
Senescence-accelerated prone mice (10-month-old) compared to 2-month-old controls.
Effective Dosage
Not specified
Duration
Not specified
Interactions
None mentioned
| Intervention | Direction | Endpoint | Population | Dosage | Impact | Claim # |
|---|---|---|---|---|---|---|
Growth hormone (GH) | decrease | cardiac aging | - | - | seem to prevent | #1 |
melatonin | decrease | cardiac aging | - | - | seem to prevent | #2 |
Growth hormone (GH) | increase | antioxidant properties | - | - | exhibit | #3 |
melatonin | increase | antioxidant properties | - | - | exhibit | #4 |
Growth hormone (GH) | decrease | oxidative stress | - | - | decrease | #5 |
melatonin | decrease | oxidative stress | - | - | decrease | #6 |
Growth hormone (GH) | decrease | apoptosis | - | - | decrease | #7 |
melatonin | decrease | apoptosis | - | - | decrease | #8 |
- | increase | inflammation markers | hearts from senescence-accelerated prone 10-month-old animals | - | significantly increased | #9 |
- | increase | oxidative stress markers | hearts from senescence-accelerated prone 10-month-old animals | - | significantly increased | #10 |
- | increase | apoptosis markers | hearts from senescence-accelerated prone 10-month-old animals | - | significantly increased | #11 |
- | decrease | anti-inflammatory markers | hearts from senescence-accelerated prone 10-month-old animals | - | decreased | #12 |
- | decrease | antiapoptotic markers | hearts from senescence-accelerated prone 10-month-old animals | - | decreased | #13 |
- | decrease | endothelial nitric oxide synthase | hearts from senescence-accelerated prone 10-month-old animals | - | decreased | #14 |
- | no change | - | Senescence-accelerated resistant animals | - | showed no significant changes | #15 |
GH treatment | decrease | age-dependent cardiac alterations | senescence-accelerated prone group | - | prevented | #16 |
melatonin treatment | decrease | age-dependent cardiac alterations | senescence-accelerated prone group | - | prevented | #17 |
combined administration of GH plus melatonin | decrease | age-related changes | senescence-accelerated prone hearts | - | reduced | #18 |
Growth hormone (GH) | decrease | oxidative stress | aging heart | - | may be potential agents for counteracting | #19 |
melatonin | decrease | oxidative stress | aging heart | - | may be potential agents for counteracting | #20 |
Growth hormone (GH) | decrease | apoptosis | aging heart | - | may be potential agents for counteracting | #21 |
melatonin | decrease | apoptosis | aging heart | - | may be potential agents for counteracting | #22 |
Growth hormone (GH) | decrease | inflammation | aging heart | - | may be potential agents for counteracting | #23 |
melatonin | decrease | inflammation | aging heart | - | may be potential agents for counteracting | #24 |
Epidemiological studies indicate that certain aspects of lifestyle and genetics act as risk factors for a variety of cardiovascular disorders, including coronary disease, hypertension, heart failure and stroke. Aging, however, appears to be the major contributor for morbidity and mortality of the impaired cardiovascular system. Growth hormone (GH) and melatonin seem to prevent cardiac aging, as they contribute to the recovery of several physiological parameters affected by age. These hormones exhibit antioxidant properties and decrease oxidative stress and apoptosis. This paper summarizes a set of studies related to the potential role that therapy with GH and melatonin may play in the protection of the altered cardiac function due to aging, with a focus on experiments performed in our laboratory using the senescence-accelerated mouse as an aging model. In general, we observed significantly increased inflammation, oxidative stress and apoptosis markers in hearts from senescence-accelerated prone 10-month-old animals compared to 2-month-old controls, while anti-inflammatory and antiapoptotic markers as well as endothelial nitric oxide synthase were decreased. Senescence-accelerated resistant animals showed no significant changes with age. GH or melatonin treatment prevented the age-dependent cardiac alterations observed in the senescence-accelerated prone group. Combined administration of GH plus melatonin reduced the age-related changes in senescence-accelerated prone hearts in an additive fashion that was different to that displayed when administered alone. GH and melatonin may be potential agents for counteracting oxidative stress, apoptosis and inflammation in the aging heart.