Very low-calorie ketogenic diet (VLCKD): a therapeutic nutritional tool for acne?

Acne vulgaris (acne) is a complex, chronic inflammatory skin disease involving the pilosebaceous unit [1]. The prevalence of acne varies by time and country, and lifestyle may influence it [2, 3]. This skin condition affects 70–80% of adolescents and persists into the 20 s and 30 s in about 64% and 43% of affected individuals, respectively [4, 5]. In addition, several studies show that acne is more common in adult females when compared to adult males [6, 7]. Of interest, Chang J et al. reported a 1.5-fold higher proportion of dermatology visits for acne among women compared to men ages 20–29 years [8]. This sex difference in dermatological care may be tied to an increased acne severity among adult women as well as an increased impact on quality of life in this population [6‐8]. In this context, acne patients may have significant quality of life (QoL) impairment [9] and its assessment, as an integral part of acne management in these patients, is recommended by several international guidelines [10, 11]. The Dermatology Life Quality Index (DLQI) is the most widely used health-related quality of life questionnaire in dermatology, particularly in studies on acne [10, 12].

Acne can result in enduring scarring and hyperpigmentation [13, 14], necessitating effective prevention and treatment to mitigate its significant impact on patients' quality of life [13]. A characteristic feature of acne patients is lesion pleomorphism, where different types of lesions, both inflammatory (such as papules, pustules, and nodules) and non-inflammatory (like comedones), may coexist in the same individual [1]. The clinical manifestations of acne can vary widely based on factors such as the severity, number, and type of predominant lesions [1].

The multifaceted pathogenesis of acne is attributed to several factors, including hyperseborrhea, hyperkeratinization of the pilosebaceous duct, colonization by Propionibacterium acnes, and perifollicular inflammation [15]. Abnormal desquamation of the sebaceous follicle epithelium (comedogenesis), sebaceous gland hyperplasia with seborrhea, increased bacterial colonization, and immunologic and inflammatory elements are the main pathophysiologic factors influencing acne development [15].

Key players in acne pathophysiology involve complex immunochemical pathways associated with inflammation, encompassing various inflammatory mediators and their target receptors, such as cytokines, defensins, peptidases, sebaceous lipids, and neuropeptides [16]. Elevated levels of prostaglandin E2 and peroxisome proliferator-activated receptor (PPAR)-γ can contribute to sebaceous gland hyperplasia and excessive sebum production, leading to inflammation and acne lesions [17]. Propionibacterium acnes also plays a role in triggering the release of pro-inflammatory cytokines [17].

In addition to increased sebum production and altered keratinization, recent discoveries highlight the microbiome as a third major player in acne development, interacting with the innate immune system [18]. The intestinal flora's influence on acne is speculated to involve interactions with the mammalian target of rapamycin (mTOR) pathway [19‐21]. Metabolites from the gut microbiota may regulate cell expansion, fat metabolism, and metabolic functions through the mTOR pathway [22]. The interplay between mTOR and gut microbiota may form a mechanism by which the intestinal flora exacerbates acne, particularly in cases of gut dysbiosis and a disrupted intestinal barrier, creating a positive feedback loop and amplifying host metabolism and inflammation [23].

Apart from the traditional factors linked to acne, recent findings have established a connection between oxidative stress and the development of this condition [24]. Notably, strains associated with acne could release porphyrins, leading to an escalation in reactive oxygen species (ROS) formation and initiating an inflammatory response in keratinocytes [25]. This inflammatory process is linked to an imbalance between oxidants and antioxidants [24]. The role of ROS in acne vulgaris pathogenesis is significant, influencing the mTOR pathway, PPAR, toll-like receptor (TLR), and the innate immune system, thereby causing inflammation through alterations in the production of various pro-inflammatory cytokines like tumor necrosis factor (TNF)-α, interleukin (IL)-8, and IL-1 [24].

Obesity, a condition characterized by excess body weight and adipose tissue accumulation, has been associated with various inflammatory and metabolic disorders [26]. However, the link between obesity and acne is not fully understood, but emerging evidence suggests a potential connection through inflammatory and hormonal mechanisms [27]. Obesity is known to induce a state of chronic low-grade inflammation, marked by increased levels of pro-inflammatory cytokines and adipokines [26]. This inflammatory state may contribute to the development and exacerbation of acne by influencing the pathways involved in sebum production, follicular hyperkeratinization, and immune responses in the skin [27]. Additionally, obesity is often associated with insulin resistance and elevated levels of insulin-like growth factor 1 (IGF-1) [28], both of which have been implicated in the pathogenesis of acne [1]. Moreover, the gut microbiota, which plays a crucial role in maintaining overall health, can be altered in individuals with obesity [29, 30]. The interplay between obesity, gut dysbiosis, and acne may involve complex interactions among inflammation, hormonal regulation, and the immune system [31]. Very low-calorie ketogenic diet (VLCKD) has been shown to have anti-inflammatory and antioxidant effects, improve insulin sensitivity, and modulate the gut microbiota. Addressing acne through dietary interventions, such as VLCKD, could potentially impact both acne and the associated inflammatory and gut dysbiosis components [31].

To date, there is a large gap in the scientific literature on the use of VLCKDs for skin diseases. While there is some evidence supporting the use of ketogenic diets in psoriasis [32, 33], to our knowledge, no studies to date have evaluated the efficacy of VLCKD in reducing the clinical severity of acne. Thus, considering the existence of inflammation, oxidative stress, and dysbiosis in patients with acne, we suppose that a highly antioxidant and anti-inflammatory dietary therapy such as VLCKD, beyond the well-known weight loss effects, can contribute to improve both oxidation and dysbiosis and, consequently, improve the clinical severity of acne. In this context, the main aim of this study was to evaluate the efficacy of 45 days of active phase of VLCKD in reducing the clinical severity of acne in a group of young women with treatment-naïve moderate acne and grade I obesity.

The study population included 31 women with treatment-naïve moderate acne (19 ≥ GAGS ≤ 30, median value 24), grade I obesity (BMI 30.03 to 34.65 kg/m², median value 33.05 kg/m²), aged 18 to 30 years.

Anthropometric characteristics and body composition of the study population at baseline and after 45 days of the active phase of VLCKD are reported in Table 1. After 45 days of the active phase of VLCKD, in the entire study population, both BMI (Δ%: − 8.08 ± 1.52, p < 0.001) and WC (Δ%: − 7.51 ± 1.67, p < 0.001) were significantly reduced compared to baseline. After 45 days of the active phase of VLCKD, fat mass (FM) (kg and %) (Δ%: − 11.34 ± 4.90 and − 11.34 ± 4.90, both p < 0.001) and fat free mass (FFM) (kg) (Δ%: − 1.66 ± 1.38, p < 0.001) were significantly reduced while FFM (%) (Δ%: + 7.02 ± 2.32, p < 0.001) slightly increased. A significant increase in PhA (Δ%: + 8.60 ± 7.40, p < 0.001) compared to the baseline was also detected.

Parameters of dysbiosis (TMAO) and oxidative stress (dROMs) in the study population at baseline and after 45 days of the active phase of VLCKD are reported in Table 2. After 45 days of the active phase of VLCKD, in the entire study population, we observed significant reductions in TMAO (Δ%: − 51.97 ± 15.98, p < 0.001) and dROMs (Δ%: − 38.07 ± 18.40, p < 0.001) levels compared to baseline.

The dermatological parameters of the study population at baseline and after 45 days of the active phase of VLCKD are shown in Table 3. Of note, after 45 days of the active phase of VLCKD, both the GAGS score (Δ%: − 31.46 ± 9.53, p < 0.001), and the DLQI score (Δ%: − 45.44 ± 24.02, p < 0.001) decreased significantly compared to baseline (Fig. 3).

Table 4 reports the simple and adjusted correlations among changes in the GAGS score and changes in the study parameters after 45 days of the active phase of VLCKD. Changes in the GAGS score positively correlated with changes in weight (p = 0.004), BMI (p = 0.001), WC (p = 0.012), total body water (TBW) (lt) (p = 0.001), extracellular water (ECW) (lt) (p < 0.001), ECW (%) (p = 0.001), FM (kg) (p = 0.023), skeletal muscle mass (SMM) (p = 0.012), TMAO (p = 0.020), dROMs (p < 0.001) and DLQI (p < 0.001) and negatively with R (p = 0.010), Xc (p < 0.001), PhA (p < 0.001), ICW (%) (p = 0.001), BCM (p = 0.017), and BCMI (p = 0.016). Interestingly, the correlations with dROMs (p < 0.001) (Fig. 4) and PhA (p = 0.005) were maintained even after adjustment for Δ% FM.

Table 5 reports the simple and adjusted correlations among changes in the DLQI score and changes in the study parameters after 45 days of the active phase of VLCKD. Changes in the DLQI score positively correlated with changes in weight (p < 0.001), BMI (p < 0.001), WC (p = 0.002), ECW (lt) (p < 0.001), ECW (%) (p < 0.001), FM (kg) (p < 0.001), FM (%) (p < 0.001), TMAO (p < 0.001), dROMs (p < 0.001) and GAGS (p < 0.001) and negatively with Xc (p < 0.001), PhA (p < 0.001), ICW (lt) (p < 0.001), ICW (%) (p = 0.001), FFM (%) (p = 0.002), BCM (p < 0.001) and BCMI (p < 0.001). Of note, the correlations with dROMs (p < 0.001) and PhA (p < 0.001) were maintained even after adjustment for Δ% FM.

In this study, a cohort of 31 women with treatment-naïve moderate acne and grade I obesity underwent the active phase of VLCKD for 45 days. As expected, at the end of the active phase of VLCKD, anthropometric measurements showed significant reductions in both BMI and WC, and, for body composition, FM (kg and %) decreased significantly, while FFM (%) showed a slight increase. In addition, there were also notable increments observed in PhA, and this was consistent with previous research [39, 42, 43]. PhA is a BIA parameter that serves as an indicator of cellular health and the distribution of body fluids. It has been recognized as a prognostic marker for both the incidence of illnesses and the likelihood of mortality in cases of chronic inflammatory conditions [57]. It’s worth noting that PhA values tend to be diminished in a significant portion of inflammatory disorders, which encompass conditions like psoriasis and hidradenitis suppurativa [58, 59].

The results of this study are promising for acne patients. The results of our study represented a novel finding, as they showed a significant reduction in TMAO and dROMs levels after the 45-day active phase of VLCKD in women with acne and obesity. This novel finding not only underscored the potential efficacy of VLCKD in the management of these conditions but also indicated a positive impact on oxidative stress and gut dysbiosis, both potential mechanisms influencing acne severity. Together, in fact, the simultaneous decrease in the GAGS score and DLQI score added an additional level of significance to our results. This dual improvement not only suggests an improvement in acne severity but also highlights a substantial improvement in participants’ overall quality of life. These findings carry significant implications regarding the potential benefits of VLCKD, particularly for patients struggling with acne and obesity, a category of patients particularly exposed to dysbiosis, oxidative stress, and a high risk of cardiovascular diseases [60‐62].

In this scenario, the decline in oxidative stress, as indicated by reduced levels of dROMs, and the amelioration of gut dysbiosis, represented by decreased TMAO levels, induced by VLCKD, may collectively constitute the underlying pathophysiological mechanism associated with the beneficial outcomes of this dietary therapy in mitigating the clinical severity of acne. Presently, there exists a substantial gap in the scientific literature regarding the utilization of VLCKDs in diverse skin disorders [63, 64]. Despite some evidence supporting the use of VLCKDs in psoriasis [32], there is a notable absence of clinical studies, to the best of our knowledge, assessing the effectiveness of VLCKD in treating acne.

Interestingly, gut dysbiosis is implicated in elevating systemic inflammation, which correlates with the onset and clinical severity of acne [65]. Moreover, studies indicate that regular intake of probiotics, particularly those containing lactobacillus strains, over 12 weeks is associated with a significant reduction in inflammatory acne lesions (30% to 67%) and a concurrent decrease in IGF-1 levels by 32% [66‐69].

Although limited research has explored the connection between VLCKDs and microbiota, both human and animal studies report positive effects on restructuring bacterial composition and enhancing gut biological function, fostering an increase in anti-inflammatory bacteria [70]. VLCKDs may influence the gut microbiota through metabolites produced by various bacteria, resulting in improved short-chain fatty acids production, reduced lactate, and increased hydrogen sulfide [70].

Recent evidence suggests that elevated insulin levels may contribute significantly to acne development through effects on sex hormones, subsequently influencing sebum production and inflammation. VLCKDs are associated with reduced insulin levels, leading to a decline in IGF-1 levels [71], ultimately triggering an increase in IGFBP-3 levels [64, 72]. This reduction in insulin and IGF-1 levels contributes to heightened SHBG levels, leading to decreased androgen production and circulation, even in the skin, correlating with diminished sebum production [63, 64, 72]. The decline in IGF-1 levels, induced by VLCKDs, may attenuate IGF-1 signaling, leading to decreased androgen synthesis and inhibition of the AKT-mTORC1 pathway [73, 74]. The subsequent reduction in androgen levels via mTORC2-mediated AKT inactivation [75, 76], along with the increased expression of Domain Containing MTOR Interacting Protein (DEPTOR), an inhibitor of mTORC1 and mTORC2 negatively regulated by androgen receptor, further enhances mTORC1 inhibition [77].

The reduction in sebum quantity and quality hampers the overgrowth of Propionibacterium acnes, thereby improving the skin biofilm [76]. Lower levels of Propionibacterium acnes-derived lipoteichoic acid and free palmitic acid act via TLR2 to inhibit the activation of the NLRP3 inflammasome, thereby reducing Th17 cell-driven inflammation and inhibiting pro-inflammatory cytokine secretion, including IL-1β and IL-1 release [76].

Moreover, the anti-inflammatory properties of ketone bodies, extensively discussed in a recent review [78], are likely beneficial for the inflammatory nature of acne, leading to a reduction in both systemic and local inflammatory processes.

Given these factors, including the improvement of the gut microbiota and the reduction of inflammation and oxidative stress, it is hypothesized that VLCKDs may contribute to diminishing the development and clinical severity of acne.

Limitations of the study were:

We also outline the strengths of the study:

The practical implications of incorporating VLCKD into the clinical management of acne disease highlight its potential as a safe, cost-effective, and complementary treatment option, particularly for patients with obesity. This expands the range of treatment options available for individuals struggling with both acne and obesity, offering a potential solution that addresses both conditions simultaneously. However, its successful implementation requires careful consideration of individual patient characteristics, ongoing monitoring, and collaboration among healthcare professionals to ensure safety, efficacy, and long-term sustainability.

With this study, we propose for the first time VLCKD as a possible therapeutic tool for young women with moderate acne and obesity. The results of this study are promising for acne patients. In this context, given the possible side effects of medications used for acne, there is a growing need for safe, tolerable, and low-cost alternative treatments that can be used to reduce the clinical severity of moderate acne in patients with obesity, possibly also as an adjunct to pharmacological therapy for acne disease, since it has been widely demonstrated that VLCKD is tolerable, safe, and effective. Therefore, VLCKD could be used in the repertoire of clinical management of acne disease within a multidisciplinary team that includes the presence of a qualified nutritionist.