Effects of Pomegranate Extract on IGF-1 Levels and Telomere Length in Older Adults (55–70 Years): Findings from a Randomised Double-Blinded Controlled Trial

With the global population of older adults steadily increasing, there is a corresponding increase in age-related diseases and health challenges [1]. Ageing is a complex biological process influenced by genetic, environmental and lifestyle factors, and multiple factors are involved in the manifestation of ageing, including telomere shortening [2]. Telomeres are protective caps at the end of chromosomes that prevent their instability by shielding genetic material from degradation, preventing chromosomal end-to-end fusions and ensuring proper replication during cell division. As telomeres progressively shorten with each cell division, they contribute to cellular ageing and senescence [3]. It has been suggested that telomere length measurement could serve as a promising clinical tool for age-related diseases [4], and there is evidence showing an inverse association between telomere length and BMI [5], as well as between telomere length and blood pressure levels [6]. Evidence from cell research showed that oxidative stress can accelerate telomere shortening, thereby speeding the ageing process and contributing to age-related diseases [7]. Targeting oxidative stress could therefore potentially represent a therapeutic strategy to slow down the ageing process and age-related diseases.

IGF-1 is a hormone increasingly recognised for its role in ageing and longevity, though its role remains controversial. Multiple studies suggest that IGF-1 is a biological marker of ageing, with lower concentrations associated with an increased risk of atherosclerosis, cardiovascular mortality and heart failure in older adults [8,9]. Findings from a review including both animal and human studies additionally highlight the role of IGF-1 in reducing oxidative stress, apoptosis and inflammatory signalling, suggesting a potential disease protective role in normal vascular ageing [10,11,12]. Although the exact mechanisms remain unclear, it is hypothesized that the effect may be mediated through the downregulation of tumour necrosis factor-alpha (TNF-α) in macrophages, an effect reported in humans [11]. However, IGF-1 has also been associated with negative effects on longevity, with proposed mechanisms including increased cellular proliferation and risk of tumour [13].

Some evidence suggests a complex interaction between IGF-1 and telomere length, proposing that elevated IGF-1 levels can independently predict longer telomere length. A study including 551 adults aged 65 years and older reported a significant association between higher IGF-1 and longer telomere length after adjusting for age, gender, disease status and BMI [14]. IGF-1 may reduce oxidative stress and inflammation [15], which are thought to be key mechanisms driving increased immune cell turnover and telomere shortening.

Polyphenols, abundant in fruits and vegetables, are well-known for their antioxidant and anti-inflammatory properties and have garnered increasing interest for their potential anti-ageing effects. Limited human studies suggest that polyphenols may reduce telomere shortening, likely due to their antioxidant and anti-inflammatory activities [16,17,18]. Furthermore, polyphenols have been shown to upregulate IGF-1 in both animal and cell models [19,20]. Pomegranate extract (PE) has recently attracted particular attention due to its potent antioxidant properties and its potential as a sustainable option in the face of climate change [21,22]. An animal study demonstrated that administering pomegranate peel for two months enhanced telomerase reverse transcriptase expression, reduced oxidative stress and elevated IGF-1 levels in aged rats [23]. Given the limited studies, our study aimed to explore the effects of PE on telomere length and IGF-1 levels in older adults (55–70 years), with the goal of gaining insights into the mechanisms linking polyphenols to ageing and informing the need for longer-term studies.

The study was conducted according to the guidelines laid down in the Declaration of Helsinki and received ethical approval from the Manchester Metropolitan University Faculty of Health and Education (reference number: 47627). Written informed consent was obtained from all participants before they joined the study. Recruitment occurred between December 2022 and June 2024. The study was registered with clinicaltrials.gov (NCT05588479).

The advertisement led to 355 individuals expressing interest, of whom 296 were assessed for eligibility and 86 met the eligibility criteria for participation. These participants were equally assigned to the PE and PL groups. Eight participants withdrew after their initial appointment, leaving 76 who completed the full intervention. In some cases (n = 4), challenges with blood collection during specific appointments resulted in incomplete data for certain participants. Consequently, 72 participants completed data from all three appointments and were included in the final analysis. The overall attrition rate was 11.6%. The CONSORT flow diagram has included in Figure 1.

The majority of participants were female (61%) and White British (83%). The mean age of the population is 61.22 (4.31) years, and the average BMI was 23.91 (3.25) kg/m², with 65.28% belonging to the normal weight category. Characteristics of the study population is presented in Table 4.

Independent t-tests showed no significant differences in age (p = 0.12) and baseline levels of BMI (p = 0.78), waist circumference (p= 0.31), waist-to-hip ratio (p = 0.3), body fat percentage (p = 0.58), SBP (p = 0.71) and DBP (p = 0.52) between the PE and PL groups. No significant between-group differences in gender (p= 0.85) and ethnicity (p = 0.33) were noted. Compliance was estimated to be high (87%).

This study aimed to explore the effects of PE on telomere length and IGF-1 levels in older adults. While telomere length did not significantly change after 12 weeks of intervention, IGF-1 levels showed a small but statistically significant increase (p = 0.04). These findings are important, as they contribute to ongoing efforts to understand the effects of plant-based extracts, particularly PE as modulators of age-related biological processes and promoters of healthy ageing.

The complex role of IGF-1 in ageing suggests that these results need to be considered in context. IGF-1 has been reported to have a positive role in cardiovascular protection, exhibit insulin-like activity at higher concentrations and play a key role in bone metabolism and muscle regeneration [29]. Declining IGF-1 levels with age have been associated with reduced muscle mass [30], increased oxidative stress [31] and decreased bone mineral density [32], highlighting its importance in tissue repair and anabolic maintenance. However, elevated IGF-1 activity has also been linked to increased cancer risk and reduced lifespan, suggesting that while it supports tissue maintenance, excessive or dysregulated IGF-1 signalling may negatively impact healthy ageing [29].

In this study, the significant increase in IGF-1 levels is consistent with previous findings from animal and cellular models, where polyphenol administration was shown to upregulate IGF-1 expression [19,20,23]. Pomegranate has also been reported to improve muscle strength and recovery [33,34], effects that may be mediated through enhanced IGF-1 signalling and attenuation of oxidative stress [23]. One proposed mechanism is that polyphenols in PE stimulate hepatic IGF-1 production, thereby increasing systemic availability [35] which may contribute to improved musculoskeletal health in older adults, alongside a decrease in oxidative stress. We suggest that the modest increase observed in this study (14.09 ± 6.87 ng/mL) may be beneficial without posing adverse effects, although this hypothesis requires further investigation in long-term human studies.

The lack of significant change in telomere length indicates that this intervention did not counteract the shortening of telomeres in this older population. These results contrast with previous animal studies on the effects of pomegranate on telomeres [23] and other human studies involving different types of polyphenols [36,37]. This discrepancy may be attributed to several factors, including intervention duration, age range and baseline health status of participants. Human studies involving older populations are complex due to several influences, including the presence of various risk factors, existing health conditions and age-related declines in metabolism, which affect the bioavailability and metabolism of polyphenols [38]. Our study population was physically active and free from chronic disease, which may have influenced the outcomes by reducing the potential for observable improvements in telomere length. Notably, telomere length is a relatively stable biomarker that typically changes gradually over long periods, even years [39]. Therefore, the 12-week duration of our study may have been insufficient to detect measurable changes in telomere length. Future research should consider longer-term interventions, as well as stratifying participants by age and health status. Additionally, some studies have reported significant changes in telomerase activity rather than telomere length [36], which may highlight a methodological limitation in our study. Measuring telomerase activity could provide a more sensitive indicator of short-term effects in telomere. Finally, a larger sample size may be necessary to detect subtle changes in telomere length and to improve the statistical power of future investigations.

Furthermore, the relatively short duration of the intervention (12 weeks) may have been insufficient to observe any potential interaction between telomere and IGF-1. Telomere typically changes over longer periods, and transient changes in IGF-1 may not immediately translate into measurable effects on telomere length.

This is the first study to assess the effect of PE on telomere length in humans, focusing on older adults and examining the impact of multiple confounding factors on the outcomes. Nonetheless, several limitations should be acknowledged. Firstly, the relatively short duration of the intervention (12 weeks) may have been insufficient to detect measurable changes in telomere length, which typically occur over extended periods. Secondly, the sample size may still have lacked the statistical power to identify small but potentially meaningful effects. Thirdly, the predominance of participants with a normal body weight does not reflect the broader population, potentially affecting generalisability of results. Furthermore, the study did not assess telomerase activity, which could have provided further insights into the underlying biological mechanisms. Lastly, although dietary intake was recorded, polyphenol consumption was not specifically analysed. Given that certain polyphenols may influence IGF-1 levels, we cannot exclude the possibility that background dietary polyphenol intake may have contributed to the observed effects. Future studies should consider using biomarkers to better control for this potential confounder. These limitations highlight the need for longer-term, larger-scale studies to more comprehensively evaluate the impact of PE on telomere length and biological ageing.

The findings of this study suggest that daily supplementation with 740 mg of PE may elevate IGF-1 levels, indicating its potential to support healthy ageing in older adults, although the broader implications for longevity remain to be clarified. Future research should focus on long-term, large-scale studies to confirm these effects and further investigate the potential long-term effects of PE on counteracting telomere shortening and contributing to improved lifespan.