Long-acting microneedle patch loaded with adipose collagen fragment for preventing the skin photoaging in mice

Harnessing innovation in microneedle technology for Women's healthcare

Women's health management plays a crucial role in modern healthcare, encompassing the prevention, detection, and treatment of female diseases. However, existing technologies often face challenges, such as the invasiveness and discomfort associated with serological testing and injection-based therapies. Microneedles, as an emerging technology in biomedical engineering, demonstrate significant advantages. These micron-sized transdermal devices are applicable in a range of applications, from drug delivery to interstitial fluid sampling, and their painless, minimally invasive nature significantly enhances medication compliance. In recent years, microneedles have been widely utilized in women's health management, showing promising results in early disease prevention and subsequent treatment. Although there are reviews about microneedles applied in disease treatment management, few of them focus on the application of microneedles in the prevention and early detection of women's disease. Herein, we present a comprehensive overview of the current application status of microneedles in women's health management, with a special emphasis on their design and mechanism for disease prevention, and treatment in women. Finally, we discuss the advantages and limitations of microneedles in women's health management, and propose suggestions for future research direction.

A review on recent advances and challenges of microneedle technology for enhanced topical treatment of skin disorders

Microneedles are tiny, minimally invasive needles that are made to create microchannels over a subcutaneous layer of the skin. These micro-injuries encourage the secretion of growth factors and prompt collagen synthesis. The reasons for using microneedling therapy have increased significantly, leading to its widespread adoption in dermatology. This review article discussed recent advances and challenges of microneedle technology for enhanced topical treatment of skin disorders. It discussed the effective and safe use of microneedles for treating different types of skin conditions like acne, scars, alopecia, melasma, skin rejuvenation, and photo-damage. The drug delivery through the skin was enhanced and rare or permanent adverse effects were not mentioned, while temporary redness and post-inflammatory hyperpigmentation were frequently seen. Microneedling seems to be a generally reliable and secure treatment choice for various skin conditions. More extensive and randomized clinical trials were necessary to ensure their safety and efficacy across diverse populations, conditions, and treatment durations. This trial helps to identify optimal dosages, long-term outcomes, and any adverse effects that may not appear in smaller studies. They also enable comparisons with existing therapies, ensuring the technology's generalizability and value. Moreover, such trials are essential for regulatory approval and to determine which microneedle technologies work best for specific uses.

Efficacy and Cellular Mechanism of Biomimetic Marine Adhesive Protein-Based Coating Against Skin Photoaging

Skin photoaging is a problem worldwide, clinically often accompanied by collagen decline, increased wrinkles, loss of skin elasticity, structurally weakened skin, and other complications, which urgently demand effective treatment strategies. The biosafety and efficacy of single-function therapies for repairing skin photoaging are still challenging for clinical medicine today. At present, numerous studies report that the wet adhesive proteins driven from marine organisms play a critical role in the biomedical material field, particularly in aquatic environments. In this study, a natural recombinant protein-based coating from scallop byssal protein is prepared to investigate the efficacy and cellular mechanism in accelerating the repair of UVB-induced photoaging in a mouse model. In vitro experiments demonstrate the safety of the coating and its efficacy in enhancing cell adhesion, spreading, proliferation, and migration. Additionally, the coating effectively scavenges reactive oxygen species, promotes the expression of cell adhesion molecules and anti-apoptotic proteins, and inhibits inflammatory responses. In animal tests, the coating exhibited remarkable adsorption properties, showing significant potential for in situ regenerative therapy, as evidenced by its ability to protect against UVB-induced skin photoaging and oxidative stress. These findings suggest that Sbp9Δ coating provides a simple, safe, and innovative strategy for treating skin photoaging.

Augmenting dermal collagen synthesis through hyaluronic acid-based microneedle-mediated delivery of poly(l-lactic acid) microspheres

Poly(L-lactic acid) (PLLA) can stimulate collagen synthesis through a foreign body response. However, inappropriate injection techniques and localized PLLA clustering can lead to complications and adverse events. This study developed a composite microneedle (MN) device comprising an array of PLLA microsphere (PLLA MP)-loaded hyaluronic acid needle tips with a supporting patch (PLLA MP-MN). This device was designed to deliver PLLA MPs precisely and uniformly to the dermis and to provide dual stimulation through MN puncture and MP implantation, thereby enabling the rapid and long-lasting regeneration of dermal collagen. When applied to rat skin, the MN array evenly distributed the PLLA MPs throughout the penetrated regions, which prevented local PLLA overdosing and elicited a milder inflammatory response compared with that induced by intradermal PLLA MP injections. An in vivo efficacy study revealed that MN-mediated delivery of PLLA MPs not only promptly initiated collagen production through microwound-triggered wound-healing cascades in the early treatment stage but also enabled the long-term stimulation of collagen deposition through MP-induced foreign body reactions, thereby significantly enhancing neocollagenesis. This innovative PLLA MP-MN system can augment the benefits and minimize the adverse effects associated with traditional PLLA fillers, providing a safe and reliable anti-aging therapeutic option.

Correction of Infraorbital Dark Circles Using Autologous Adipose-Derived Collagen Filler: A Novel Regenerative Option

BACKGROUND

Numerous intrinsic and extrinsic factors, notably the aging process, contribute to the development of infraorbital dark circles. These features, commonly associated with old age and fatigue, are caused by a disruption of dermal melanin and impairment of skin barrier function. Common aesthetic concerns affecting patients with infraorbital dark circles are primarily owing to lean and translucent lower eyelid skin overlying the orbicularis oculi muscle. This study aimed to present a novel technique for correcting infraorbital dark circles utilizing an adipose-derived extracellular matrix concentrate-adipose collagen fragment (ACF)-to correct infraorbital dark circles.

METHODS

Female patients (n = 94) aged 20-38 who presented infraorbital dark circles were enrolled to assess the efficacy of this technique for an eight-month follow-up. Following intradermal injections with ACF filler, the clinical outcome was determined by responses to GAIS and patient satisfaction surveys. Statistical analysis was performed with the one-way ANOVA test, and a p value of < 0.05 was considered statistically significant.

RESULTS

Patients (n = 92) completed a single treatment session and underwent an eight-month follow-up. Eighty patients (86%) reported being "highly satisfied" or "satisfied" with the outcome and responded that the technique resulted in brighter, tighter, and smoother infraorbital skin. Over 97% of patients were rated as "improved," "much improved" and "Very much improved" throughout the follow-up on GAIS by three independent surgeons (p < 0.05). The statistical analyses demonstrated the percentage differences among groups are highly significant (p < 0.0001). No irregularity or lump was observed during the follow-up. Two patients were excluded from the study due to having undergone cosmetic eyelid surgery.

CONCLUSION

Intradermal ACF filler represents a novel approach to addressing infraorbital dark circles and yields significantly high patient satisfaction. ACF fillers provide a degree of bio-stimulation, and adipose-derived concentrate is a natural filler with regenerative effects used in periorbital rejuvenation.

LEVEL OF EVIDENCE IV

This journal requires that authors assign a level of evidence to each article. For a full description of these Evidence-Based Medicine ratings, please refer to the Table of Contents or the online Instructions to Authors www.springer.com/00266 .

Recent Developments in Using Microneedle Patch Technology as a More Efficient Drug Delivery System for Treating Skin Photoaging

Skin photoaging, resulting from prolonged exposure to ultraviolet (UV) radiation, is characterized by intricate biological changes involving oxidative damage and structural alterations. Despite an increasing demand for effective interventions, the current therapeutic options for treating skin photoaging are limited. We discovered through literature data search on PubMed that recent research has shifted its focus to the application of microneedle patches as an innovative approach to address this concern. Microneedle patches, serving as a novel transdermal delivery system, exhibit the potential to deliver bioactive substances such as cytokines, cellular vesicles, gene fragments and even alive algae to mitigate the effects of skin photoaging. This review aims to provide a comprehensive overview of recent advancements in research about utilizing microneedle patches for the treatment of skin photoaging and potential future directions in leveraging microneedle patches as clinical therapeutic agents for skin rejuvenation. Ultimately, we believe that microneedle patches have a broader application prospect in the fields of medical cosmetology and anti-photoaging.

Highly bioactive triple-helical nano collagens for accelerated treatment of photodamaged skin

Skin damage caused by excessive UV exposure has gradually become one of the most common skin diseases, leading to desquamation, scab formation, inflammation and even skin cancer. Animal-derived hydrolyzed collagen peptides have been developed to treat UV-damaged skin; however, they have raised severe concerns such as potential viral transmission, random sequences and the lack of a triple helix structure. Nano collagen, a novel type of short collagen, has attracted increasing attention in the mimicking of natural collagen, while its applications in UV-damaged skin treatment remains unexplored. Herein, we have created a series of nano collagens and for the first time studied their capability of accelerating UV-damaged skin healing. Nano collagens, consisting of repetitive (GPO)n triplets and a GFOGER motif, display a stable triple-helical structure, significantly promoting fibroblast adhesion, proliferation, and migration. The repair effects of nano collagens have been investigated using an acute UV-damaged skin mouse model. Combo evaluations indicate that nano collagens contribute to recovering the dermis density and erythema index of UV-damaged skin. Histological analysis further demonstrates their capability of promoting the healing of damaged skin by accelerating re-epithelialization and collagen regeneration. These highly bioactive triple-helical nano collagens present a novel strategy for the treatment of UV-damaged skin, providing promising applications in cosmetics and dermatology.

Simulated skin model for in vitro evaluation of insertion performance of microneedles: design, development, and application verification

Microneedles, as a new efficient and safe transdermal drug delivery technology, has a wide range of applications in drug delivery, vaccination, medical cosmetology, and diagnostics. The degree of microneedles penetration into the skin determines the reliability of the delivery dose, but its evaluation is not yet well-established, which is one of the major constraints in the commercialization of microneedles. In this paper, a novel visual simulated skin model was developed with reference to the physical properties of real skin. The simulated skin model was well-designed and its prescription was optimized to make the thickness, hardness, elasticity, and other parameters close to those of real skin. It not only meets the need to assess the degree of insertion of microneedles but also provides a visual observation of the insertion state of microneedles.

A highly biocompatible and bioactive transdermal nano collagen for enhanced healing of UV-damaged skin

Skin damage caused by excessive UV radiation has gradually become one of the most prevalent skin diseases. Collagen has gradually found applications in the treatment of UV-damaged skin; however, their high molecular weight greatly limits their capacity to permeate the skin barrier and repair the damaged skin. Nano collagen has garnered growing attentions in the mimicking of collagen; while the investigation of its skin permeability and wound-healing capability remains vacancies. Herein, we have for the first time created a highly biocompatible and bioactive transdermal nano collagen demonstrating remarkable transdermal capacity and repair efficacy for UV-damaged skin. The transdermal nano collagen exhibited a stable triple-helix structure, effectively promoting the adhesion and proliferation of fibroblasts. Notably, the transdermal nano collagen displayed exceptional penetration capabilities, permeating fibroblast and healthy skin. Combo evaluations revealed that the transdermal nano collagen contributed to recovering the intensity and TEWL values of UV-damaged skin to normal level. Histological analysis further indicated that transdermal nano collagen significantly accelerated the repair of damaged skin by promoting the collagen regeneration and fibroblasts activation. This highly biocompatible and bioactive transdermal nano collagen provides a novel substituted strategy for the transdermal absorption of collagen, indicating great potential applications in cosmetics and dermatology.

Research Progress on New Functions of Animal and Plant Proteins

Protein is composed of peptides, essential nutrients for human survival and health, and the easy absorption of peptides further promotes human health. According to the source of the protein, it can be divided into plants, animals, and micro-organisms, which have important physiological effects on the health of the body, especially in enhancing immunity. The most widely used raw materials are animal protein and plant protein, and the protein composition formed by the two in a certain proportion is called "double protein". In recent years, China's State Administration for Market Regulation has issued an announcement on the "Implementation Rules for the Technical Evaluation of New Functions and Products of Health Foods (Trial)", which provides application conditions and listing protection for the research and development of new functions of health foods. At present, some researchers and enterprises have begun to pay attention to the potential of animal and plant proteins to be used in new functions. In this article, the research progress of animal and plant proteins in the new functions of Chinese health food is reviewed in detail, and suggestions for future research on animal and plant proteins are put forward.

Therapeutic potential of adipose tissue derivatives in skin photoaging

Photoaging, the primary cause of exogenous skin aging and predominantly caused by ultraviolet radiation, is an essential type of skin aging characterized by chronic skin inflammation. Recent studies have shown that oxidative stress, inflammation, skin barrier homeostasis, collagen denaturation and pigmentation are the main contributors to it. As a composite tissue rich in matrix and vascular components, adipose tissue derivatives have been recently gaining attention as potential therapeutic agents for various human diseases with fat-processing technology upgrades. This review analyzes both 'minimally treated' and 'nonminimally treated' fat derivatives to give an overview of the preclinical and clinical relevance of adipose tissue derivatives for antiphotoaging application, highlighting their good clinical prospects as well as discussing their safety and potential risks.