Evidence supporting the use of: Prune
For the health condition: Osteoporosis

Links: Go back one page, Tool main page, Ingredients list, Health conditions list, Body systems list

Synopsis

Source of validity: Scientific
Rating (out of 5): 3

Prunes (dried plums) have garnered scientific interest for their potential role in supporting bone health and managing osteoporosis. Several studies, both in animals and humans, have investigated the effects of prunes on bone mineral density (BMD) and bone metabolism. Prunes are rich in nutrients such as vitamin K, boron, potassium, and polyphenols, all of which may contribute to bone health. Preclinical animal studies have shown that prunes can prevent bone loss in models of osteoporosis, likely by modulating bone turnover markers and favorably affecting bone microarchitecture.

Notably, a 2011 randomized controlled trial published in the British Journal of Nutrition found that postmenopausal women who consumed 100 grams of prunes daily for one year experienced significantly less loss of BMD in the ulna and spine compared to a control group that consumed dried apples. Follow-up studies have supported these findings, suggesting that prunes may help maintain or even improve BMD in postmenopausal women, a population at high risk for osteoporosis. The mechanism is believed to involve the antioxidant and anti-inflammatory properties of prunes, as well as their ability to suppress bone resorption.

While results are promising, limitations include relatively small sample sizes and short study durations. Thus, while there is moderate scientific support for prunes in osteoporosis management, larger and longer-term studies are needed to confirm these effects and determine optimal dosing.

More about prune
More about Osteoporosis

Other ingredients used for Osteoporosis

7-hydroxymatairesinol (HMR)
Alfalfa
algal oil
alpha-ketoglutarate (AKG)
anthocyanins
ashwagandha
astragalus
beta caryophyllene
sesame
blueberry
boron
bovine
broccoli
calcium
catechins
caterpillar mushroom
cissus quadrangularis
collagen
collard
conjugated linoleic acid (CLA)
curcumin
DHEA (dehydroepiandrosterone)
DPA (docosapentaenoic acid)
EPA (eicosapentaenoic acid)
fish protein
genistein
genistin
glycitin
gooseberry
hesperetin
hesperidin
horsetail
ipriflavone
knotweed
kale
lentinula edodes mycelia
lignans
maca
magnesium
manganese
microcrystalline hydroxyapatite concentrate (MCHC)
olive
omega-3 fatty acids
phosphorus
pomegranate
prune
quercetin
rehmannia glutinosa
resveratrol
rutin
sardines
silicon
soybean
specialized pro-resolving mediators (SPMs)
strontium
tocotrienols
tomato
vitamin C
vitamin D
vitamin D3
vitamin K
seaweed
whey protein
zinc
red clover
haliotis
cistanche
dioscorea
fern
royal jelly
Equol (proprietary)
barrenwort
goji berry
AMP-activated protein kinase (AMPK)
soy isoflavones
8-Prenylnaringenin
Animal Tissue
Antler
Apigenin
Algas calcareas
Acacetin
Astragaloside
Ampelopsin
Algal protein
Algalin
Abalone
Arctiin
Astragalin
Animal protein
Bok Choy
Bovine Protein
biochanin
Bone Protein
Calycosin
Cod Liver Oil
Cyanidin
Chinese Ligustrum berry
DHEA
Daidzein
Diosgenin
Drynaria
Diosmetin
epicatechin
Ecdysteroids
Eicosapentaenoic Acid
Eucommia ulmoides
Estrogen
Fo-Ti
formononetin
Fish
Flavanones
Flavans
Flavanols
Flavones
Hyperoside
Isoflavones
icariin
Kaempferol
Lycium
Lithothamnion
Legume protein
Mineral Blend
Marine Protein
Milk Protein
Naringenin
Neoeriocitrin
Puerarin
Phytoecdysteroid
Phaeophyceae
Polysaccharides
Procyanidin
Proanthocyanidins
Polyunsaturated Fat
Paeoniflorin
Phytoestrogens
Polymethoxylated flavones
Rehmannia
Soy
Soy Protein
silica
Shilajit
Stilbenoid
Ursolic Acid
Vegetable Protein
Wakame
Xanthophyll