The Skin Aging Process and Anti-Aging Strategies

Introduction

Appearances play a vital role in society as it is how one communicates to others their identity and it strongly influences how one is perceived. Moreover, when living in the age of social media, influencers, and photoshop, the average person is now exceedingly aware of their physical appearance. It is easy to fall victim to setting unrealistic expectations for oneself, especially when comparing the average person to the meticulously retouched images of celebrities posted to the public. Filters used to smooth out wrinkles on Instagram posts, fillers injected to plump up tissue to diminish laugh lines, [1] and makeup to cover up any sunspots that have developed all show a marked aversion to aging in their picture-perfect society. In 2012, a survey conducted by the market research company NPD Group found that women between the ages of 18 and 24 found that fewer than 20% considered anti-aging skin care to be important. However, a survey of the same demographics in 2018 by beauty consumer analysts discovered that this statistic rose to more than 50% of women adding products in their routine to defy wrinkles [2] (Graph 1). The notable 150% increase in utilizing preventive skin care is reflective of the generation’s growing unwillingness to show the physical signs of aging. Nonetheless this attempt to delay the aging process is not unique to Millennials or Gen Z.

Graph 1.

As early as 30 BC, Cleopatra was known to take daily baths in donkey-milk for the anti-aging and skin-softening properties of the hydroxy acids in the milk and during the Tang-dynasty, Empress Wu Zlitan maintained her famed beauty through the years by washing her face with powdered Chinese motherwort and cold water [3] Since then, science and technology has advanced to be able to identify the specific active compounds that made these treatments effective. In doing so, these compounds are able to be purified for higher efficacy in treatment. Furthermore, the development of new treatment methods for the purpose of anti-aging have taken the world by a storm. A study done by the American Society of Plastic Surgeons reported that 3.4 million injections of soft tissue filler were done in 2020 alone. This value is second only to Botox injections being the most popular minimally invasive cosmetic procedure with a total of 4.4 million procedures done. In addition to fillers, other popular anti-aging methods include serums, resurfacing creams, “vampire facials’’ and more that claim to help create a smoother and fuller appearance of the skin.

As concerns about the physical manifestation of aging grow and people continue to take an active role in either the prevention or reversion of aging skin, treatment methods have become more accessible and normalized in the modern world. While anti-aging claims are an effective marketing tool in drawing consumers to a product or procedure, these claims must be backed up with actual mechanisms that work to rejuvenate the skin - whether it is through stimulation of collagen production or the removal of damaging reactive oxidative species. There are so many products on the market with varying ingredients and price points, so it is important to know which ones are actually effective in producing anti-aging results and which ones are pointless. While there is not yet a proven effective product capable of eliminating all signs of aging, there are products and treatments that are clinically proven to have wrinklereducing effects and work to visibly reduce signs of aging.

Aging Process

Graying hair, shrinking stature, and cracking joints are all telltale signs of aging everyone hopes to escape, with the most famous indication being the appearance of fine lines and wrinkles on the skin. Wrinkles are the creases and folds that form in the skin as a by-product of the aging process as the skin loses its elasticity over time. As the separation of the body from the outside environment, the skin is impacted by aging factors that are both intrinsic and extrinsic. Intrinsic aging is determined genetically and describes the unavoidable physiological process resulting in the development of fine wrinkles in thin, dry skin. Extrinsic aging factors encompass environmental factors such as sun exposure, air pollution, and smoking that produce rough textured skin and the formation of deeper, coarse wrinkles [4]. To protect from these external factors, the skin has multiple layers to serve as a defense against pathogens, UV light, physical injuries, and more. The 3 most commonly known layers of the skin are the epidermis, dermis, and hypodermis - all varying in structure and function. Lesser known is that each of these layers has several sublayers aiding in the functionalities of the skin.

The outermost layer, the epidermis, is divided into the stratum Basale, stratum spinosum, stratum granulosum, stratum lucidum, and the stratum corneum [5]. Of these, the skin barrier has been located primarily at the intercellular lipid matrix of the uppermost layer of the epidermis, the stratum corneum. The stratum corneum consists of 20-30 cell layers of keratin and horny scales (made up of anucleate squamous cells, or dead keratinocytes) as well as the crucial lipid matrix containing cholesterol, free fatty acids, and ceramides. These compounds making up the lipid matrix are together known as a “natural moisturizing factor” as they function to keep the deeper layers of skin, such as the dermis and hypodermis, well-nourished and hydrated. The primary purpose of the skin barrier is to remain as tight as possible and in doing so, it plays three vital roles. First, it protects the body from external stressors such as UV radiation, pollution, and chemicals. Second, the barrier functions to retain water in the skin and maintain healthy levels of hydration through the prevention of excessive trans epidermal water. Trans epidermal water loss refers to the amount of water that passively evaporates via the surface of the skin, and it is a good measure of effectiveness of the skin barrier system [6].

Third, the skin barrier is responsible for transporting nutrients through itself and into the skin to preserve the health of the major organ. Ultimately, these tasks in conjunction operate to maintain homeostasis among the body’s many systems [7]. If the skin barrier does not work as, it should, the epidermis will become vulnerable to damage and unable to fight off external aggressors, such as free radicals that can result in the formation of discoloration and premature wrinkles. In fact, up to 90% of visible skin aging is due to environmental factors, such as sun exposure [8]. Over time, with improper care, the skin barrier will become impaired and result in less hydrated skin that is more susceptible to harm. With normal, healthy skin, the top layer is continually shed as it is being renewed by a self-replenishing pool of stem cells existing in the basal layer. However, as people age, this pool of stem cells becomes diminished resulting in slower cell turnover rates [9]. This slowing divide of cells causes the dermis layer to thin. The dermis consists of interwoven elastin and collagen fibers, offering support and elasticity. As the interconnected fibers loosen with time, depressions are created on the skin surface that are unable to heal, resulting in the development of wrinkles [10].

Aging and Role of Collagen

Collagen is the most abundant protein present in mammalians, serving as one of the main building blocks for a range of tissue types including bones, skin, muscles, and hair. The 3 parallel polypeptide strands are found in a left-handed, polyproline II-type helical formation with a one-residue stagger forming a right-handed triple helix [11]. This stagger contains a special amino acid sequence specifying that every third amino acid must be glycine while the 2 remaining residues are often either proline or hydroxyproline [12]. This structure results in incredible stability and versatility of the protein, allowing it to play key roles throughout the body in various forms. In the skin, collagen fibers are found in the dermis layer to form fibroblasts where new cells can grow in addition to playing a role in replacing and restoring dead skin cells [13]. As one ages not only does the body produce less collagen, causing a decline in the structural integrity of the skin, but this process can be hastened by exposure to harmful extrinsic factors like ultraviolet rays and smoking. The breakdown of the complex network of fibers leads to wrinkles as the layers underneath the epidermis lose their firmness. This is visualized in the diagram below through the comparison of the many layers shown as the collagen-elastin network progresses from younger skin to aging skin [14] (Figure 1).

Figure 1.

Not only is overall collagen production reduced, but the type of collagen being also produced is different in aging skin as well. Currently, there are a total of 28 different forms of collagen in the body including both fibril-forming as well as non-fibril forming proteins. Of these, the most predominant types of collagens are Type I, Type II, and Type III. Type I is the most common type of collagen, making up 80-90% of skin, hair, and nails and is composed of two ⍺1 chains and one ⍺2 chain coiled around each other [15]. Type II is mainly found in cartilage to support joint health and it contains three identical ⍺1-polypeptide chains of 1,060 amino acid residues [16]. Type III supports Type I collagen in maintaining skin and bone health and it is made of three ⍺1(III) chains supercoiled in a right-handed triple helix to form a homotrimer. In older skin, the collagen structure will look irregular as the proportion of collagen types in the skin changes with age. While young skin is composed of 80% Type I collagen and 15% Type III collagen, aging skin has shown an increase in the ratio of Type III to Type I collagen - largely due to the loss of Type III collagen [17]. With age, overall collagen content per unit area of skin surface is said to decline at a rate of approximately 1% per year as fibroblasts become less active [13]. In fact, a study conducted by MINERVA Research Labs reported that peak collagen content was identified between the ages of 25-34, followed by a gradual decline over the coming decades [18] (Graph 2).

Graph 2.

This, created by MINERVA Research Labs depicts the increase of collagen content until the mid-20s. Shortly after begins the progressive loss of collagen equating to an almost 25% decrease over the span of 4 decades. The synthesis of collagen fibers is primarily done by the fibroblasts of the skin, meaning that the rejuvenation of this biomatrix can only be efficiently improved with a supply of supplemental nutrients via the bloodstream. As the skin’s natural collagen supply diminishes, the introduction of collagen via injection, topical treatment, or oral ingestion can work to replenish the collagen that has been lost or even stimulate the production of more collagen after absorption. A randomized, placebo-controlled, blind study by Bloke was used to investigate the effects of drinking a test product containing a blend of 2.5 grams of collagen peptides, acerola fruit extract, biotin, vitamin C, and other compounds. Performed on women 35 years and older, this study, in conjunction with others totaling a pool of 805 patients, demonstrated that collagen supplements are effective in increasing hydration, dermal collagen density, and elasticity of the skin [19]. Another study done by Porsche et al. reported that the intake of 2.5 grams of collagen a day over an 8 week period produced an increase in procollagen Type I as well as elastin, leading to a significant reduction in eye wrinkle volume [20]. Although the formation of wrinkles is inevitable as a byproduct of the aging process, researchers are actively working to find ways to minimize the appearance of these fine lines. While there are developing treatment methods, a second way to combat wrinkles is through preventive measures.

Preventive Measure as Anti-Aging Efforts

A popular preventive measure for reducing or delaying the appearance of wrinkles is through nutrition to combat the effects of reactive oxygen species (ROS). Reactive oxygen species are generated as by-products when molecular oxygen is utilized by aerobic organisms to perform essential metabolic reactions within the body. ROS is a term used to define any oxygen-containing reactive including hydrogen peroxide (H2O2), hydroxyl radicals (˙OH), peroxyl radicals (LOO˙), and more [21]. In addition to involvement in metabolic processes, ROS also play important roles in wound healing, inflammatory responses, and apoptosis. As the skin functions as a barrier to protect from external harmful agents, when the skin becomes inflamed high levels of ROS are generated for the purpose of removing and destroying invading microorganisms and breaking down any damaged tissue. As mediators of inflammatory responses, ROS activate cell signaling to increase the production and release of proinflammatory cytokines to instigate inflammatory responses.

In the presence of nitric oxide, calcium, and pathogens within human cells, the balance between oxidant and antioxidants is affected and results in the generation and accumulation of ROS in cells. The resulting imbalance between oxidative and antioxidative events induces oxidative stress, leading to oxidative reactions. ROS are reactive species that show molecular aggregation and are capable of causing serious damage to biomolecules including lipids, nucleic acids and proteins. This deterioration to DNA and other biomolecules can also induce other structural and functional damages leading to cell and tissue injury. As DNA, lipid, and protein structures are altered, there is a resulting dysregulation of cellsignaling pathways that trigger downstream signaling cascades to alter cytokine release. As the cytokines are not released regularly, the induced inflammatory response is prolonged and causes tissue damage and the exacerbation of inflammatory skin diseases [22]. To defend against these attacks, a series of antioxidant defenses have been developed to protect vital biomolecules from ROS damage. Antioxidants perform their duties by 3 major modes of action:

(a) Directly scavenging already-formed ROS,

(b) Inhibit formation of ROS from cellular sources,

(c) Remove or repair harm caused by ROS.

To reduce the risk of oxidative stress-related issues one could implement a plant-based diet with high volumes of intake of fruits, vegetables, and other foods rich in antioxidants. A meatbased diet is low in antioxidants while plant-based foods are antioxidant rich due to the presence of thousands of bioactive food constituents. These constituents - including flavonoids, tannins, stilbenes, phenolic acids, and lignans - are called phytochemicals that are redox active molecules and function as antioxidants. When comparing the meats versus plant-based foods, plants have 5 to 33 times higher mean antioxidant content when compared to the values for animal-based foods [23]. Long-term exposure to UV radiation is also a major cause of skin aging that can be reduced through preventive measures. Photoaging causes alterations in the structure of skin such as epidermal stratum corneum integrity, skin thickness, hydration and lipidation leading to the development of wrinkles and skin relaxation. UV exposure can lead to the generation of excess ROS in the skin that then in turn activate pathways related to skin aging including: “MMP1-mediated aging, MAPK/AP-1/NF-kB/tumor necrosis factor (TNF)-⍺/IL-6-mediated inflammation-induced aging, and p53/BAX/cleaved caspase-3/ cytochrome c-mediated apoptosis-induced aging [24].

”The activation of transcription factors like NF-kB promote inflammation-induced signaling and create oxidative stress by increasing ROS production to lead to skin cell apoptosis [25]. UVB-induced ROS generation is capable of activating the MAPK pathway leading to the expression of MMPs. MMPs are able for the degradation of the extracellular matrix in the skin, leading to the formation of wrinkles [26]. As the risks that come with overexposure to UV radiation become abundantly clear, so is the importance of using protection against the sun’s rays. It is recommended to stay out of the sun from 10:00 am to 2:00 pm when the sun’s rays are the strongest, and when going outside, one should dress to protect by wearing covering materials such as a long-sleeved shirt, a hat, and sunglasses. On skin that is not covered, the FDA recommends to wear a sunscreen offering broad-spectrum protection that is SPF 30 or higher [27]. Sunscreens can be made with organic filters that absorb UV radiation energy to convert into unnoticeable infrared energy. The structure responsible for this absorption is chromophore, consisting of electrons engaged in multiple bond sequences between atoms. Upon absorption, the UV photon holds enough energy to result in an electron transfer to a higher energy orbit within the chromophore molecule [28]. From this excited state, different relaxation processes occur dependent on the ability of the UV filter to convert the absorbed energy in order to bring it down to the ground state energy. Inorganic filters are also used in sunscreens as pigment grade powders of metal oxides like zinc oxide in conjunction with organic filters to enhance sun protection. Unlike organic filters, these metal oxides work by reflecting and diffusing UV radiation so that it only reaches the skin, rather than becoming absorbed past it [29].

Changing the Perception

When considering anti-aging, there are two ways of looking at it: perception versus making real changes to the skin. To simply change perception, multiple methods can be used such as filters for a blurring effect or the use of makeup like foundation and concealers to lessen the appearance of any unwanted fine lines. It is important to note that many makeup brands will advertise their products as having the ability to “reduce the appearance of wrinkles” which is important to distinguish from “will reduce wrinkles”. The difference is that the former is a cosmetic claim whereas the latter is a drug claim. The FDA defines cosmetics as “articles intended to be rubbed, poured, sprinkled, or sprayed on, introduced to, or otherwise applied to the human body...for cleansing, beautifying, promoting attractiveness, or altering the appearance” [30]. For example, mica is an earth-derived silicate mineral that is included in many cosmetic products to provide a shimmering effect on the skin surface. In doing so, it not only provides protection against the sun’s rays, but it also diffuses reflected light off of the skin so that wrinkle lines are not as pronounced [31]. While mica is able to fulfill the cosmetic claim of reducing the appearance of wrinkles, there are other treatment options that work to reduce the physical presence of wrinkles. One such example is Botulinum Toxin (BTX).

While it cannot entirely discontinue the aging process of the skin, regular injections are able to slow down the visible effects of aging by helping manage the further stimulation of dynamic wrinkles. BTX-subtype A (BTX-A) is a potent neurotoxin that blocks the presynaptic release of acetylcholine at the neuro-muscular junction to produce temporary chemical denervation [32]. The toxin binds to presynaptic neurons of the pre-selected muscles within an hour and clinically reversible chemical denervation and paralysis begin after 24 to 48 hours of the injection [33]. It is only on Day 28 that the nerve sprouts are able to mediate partial restoration and new neuro-muscular junctions begin to form near the site of the old junction and by Day 62-91 there is complete recovery of muscle function. As the muscular changes achieved through BTX-A are completely reversible, treatment should be repeated every 3 to 4 months to maintain results [34]. Like Botox, dermal fillers can be injected, but they differ in function by adding fullness to areas that have thinned due to age. Biodegradable fillers, like collagen and Hyaluronic Acid (HA) fillers are reabsorbed by the body and typically have effects lasting 6 to 18 months [35].

The duration of the filler is dependent on the source and extent of cross-linking, as well as the concentration and size of each product. As hyaluronic acids are linear polymeric dimers of N-acetyl glucosamine and glucuronic acid, the degree and methods of chain cross-linking, the uniformity and size of particles, and concentration of particles will all vary and impact the clinical effects of the filler. With greater cross-linking and concentration, the viscosity, elasticity, and resistance to degradation all increase. Additionally, larger particle products in high concentrations will absorb more water and increase the degree of tissue swelling following injection [36]. Unlike biodegradable fillers, nonbiodegradable fillers work by provoking a foreign body reaction to stimulate the fibroblastic deposition of collagen surrounding nonabsorbable microspheres. One example of this type of filler is SilikonⓇ1000 which is a medical-grade pure form of silicon - upon injection, the body will form collagen around these silicone particles to increase volume in the tissue [37]. However, owing to the permanent nature of these fillers, complications are much more difficult to treat. Another treatment that is a popular treatment for skin rejuvenation is Autologous Platelet-rich Plasma (PRP).

PRP is made from fresh whole blood containing high concentrations of platelets. In these platelets there are ⍺-granules that secrete various growth factors including transforming growth factor (TGF), insulin-like growth factor (GF), and platelet-derived growth factor (PDGF) [38]. These factors are responsible for regulating processes such as cell migration, proliferation and differentiation, and promoting extracellular matrix accumulation. In this way, PRP is also capable of inducing collagen synthesis by stimulating the activation of fibroblasts, which can then in turn rejuvenate the skin [39].

Some of the Useful Approved Drugs

The Food and Drug Administration defines a drug as “articles (other than food) intended to affect the structure or any function of the body of man or other animals” [30]. To do so, active ingredients are used to produce desired biological or chemical effects. For example, retinoids vitamin A derivatives that have been proven clinically to reduce acne, prevent wrinkles, reverse the effects of sun damage, and more. As lipophilic molecules, retinoids are able to diffuse through phospholipid membranes such as the cell membrane where it is able to bind to various receptors. The resulting ligand-receptor complexes are able to directly bind to specific DNA sequences called “retinoic acid response elements” (RARE) as transcription factors or by indirectly repressing the transcription factor AP-1.31-33 [40]. The activation of RARE and the repression of AP-1 expression allows retinoids to act as powerful agents able to regulate gene expression to influence cellular differentiation and proliferation. Following treatment with retinol and retinoic acid, there is a resulting epidermal thickening due to the inhibition of collagen degradation and an increase in collagen synthesis. To determine the molecular mechanism for these changes, the expression of 12 genes were determined.

After retinol and retinoic acid treatment, there were increases in the gene expression of COL1A1 and COL3A1 responsible for the production of procollagen I and procollagen III proteins. The retinol treatment resulted in a 1.34-fold increase in COL1A1 gene expression and a 1.43-fold increase in COL3A1. After retinoic acid treatment, there was a 2.48-fold increase in the expression of the COL1A1 gene and a 2.77-fold increase for COL3A1. A facial wrinkle analysis conducted after 12 weeks of treatment showed a significant reduction in wrinkle scores: at the cheeks the scores were reduced by 63.74% and the eye areas were reduced by 38.74% [41]. Vitamin C is another compound that can be found in serums, as topical creams, or ingested to play a metabolic role in collagen synthesis and as an antioxidant. Ascorbic acid (AA) is an alpha-keto lactone that exists as a monovalent hydroxyl anion at physiologic pH levels. As an antioxidant, ascorbate undergoes a stepwise donation of 2 electrons where the intermediate compound following the donation of 1 electron is the ascorbate free radical. This radical functions as an effective free radical scavenger and suppresses matrix-metalloproteinases associated with collagen degradation [42]. AA also functions as a cofactor in the production of 2 enzymes required for collagen synthesis. Prolyl hydroxylase stabilizes the collagen molecule while lysis hydroxylase gives structural strength via intermolecular cross-linking - AA is consumed non stoichiometrically during translation within ribosomes for the formation of both of these enzymes [43].

While the use of vitamin C alone functions to remove ROS, combining the additional active ingredient vitamin E can provide maximal anti-aging and brightening effects. When vitamin C and E work synergistically, the elimination of free radicals is much more efficient as vitamin C is able to regenerate oxidized vitamin E into its reduced form. Furthermore, vitamin E possesses lipid-soluble properties allowing it to pass down via sebaceous gland secretions into the deepest layers of the stratum corneum to occupy cell membranes and provide protection from oxidative stress [44]. The effectiveness of this synergistic anti-aging process is proven as the topical use of 15% L-ascorbic acid with 1% alpha-tocopherol provides significantly more protection withstanding sunburn cell formation when compared to the use of either active ingredient alone [45]. Peptides are amino acids that structure the specific proteins necessary for the skin. Studies have shown that the ingestion of collagen peptides with other active compounds can rejuvenate skin and other damaged tissues. As peptides travel throughout the body, they will encounter sites with fibroblasts, stimulating them to produce more compounds like collagen, elastin, and hyaluronic acid. With long term use, there is noticeable improvement in skin elasticity and hydration leading to more youthful, firmer-looking skin [15].

Antiaging Cosmeceuticals

While active ingredients are proven to work, they are only as effective as how far they are going into the skin. Topical treatments are meant to reduce systematic exposure and the ingredients mainly only go as deep as the epidermis to address whatever issue must be solved. However, when creating products with the purpose of anti-aging the problem with topical presentation is getting enough of the active ingredient past the top layers of the skin and to the target tissue. The penetration of actives further into the skin or penetration to a specified layer of the skin can maximize the effectiveness of these active ingredients. Derma zone is a cosmeceutical company that integrates its nanotechnology platform and science to perform transformative skin care through more effective delivery of active compounds [46]. As a cosmeceutical company, beyond the transient appearance of skin enhancement Derma zone formulas contain pure and potent bioactive ingredients to provide in-depth penetration of the epidermis and make true changes to the biochemical processes to impact the mechanisms of aging. Derma zone technology provides innovative delivery and deeper penetration of these active ingredients and botanicals. Transdermal drugs describe a vast category of drugs that serve as vessels for delivering drugs for both local and systemic mechanisms [47].

Figure 2.

True transdermal medication is the application of a drug through the skin with the intent to drive the compound into the bloodstream to promote systemic exposure across the skin. However instead of driving the active ingredients through the epidermal layer and into the bloodstream, Derma zone transdermal technology seeks to transport ingredients to the depths of the epidermis to depot there for a slow release rather than breaking into the dermis. At this layer, the capsule is broken to release the active compounds that are now free to interact with viable cells [48]. In the transportation of active compounds, Derma zone uses materials that are bioavailable to the skin to encapsulate the active ingredients in a lipophilic outer membrane that is able to efficiently penetrate the skin and be delivered to the target area. For this purpose, Derma zone has developed Nano-Lipidic Particle (NLP) nanotechnology to serve as transport. The process of making this patented NLP nanotechnology can be done in 3 phases. In Phase I, there is the development of an NLP precursor, to which water and ethanol are added to complete Phase II. Then in Phase III, the NLP liposome is completely formed with the addition of water and the active ingredient it is meant to transport (Figure 2) [49]. When fully formed, the NLP liposome will look like the illustration below. With this technology, Derma zone is able to encapsulate almost any compound. Not only are the ingredients to form NLP natural to biological organisms, it is also easily incorporated into existing processes of manufacturing and yields a more efficient and economic delivery of active ingredients. The only limitation is that the capsules are less than 200 nm, so compounds larger than a few thousand Dalton are unable to fit in the NLP liposome. Nonetheless, active ingredients such as acetyl hexapeptide-8, vitamin C, geranium maculatum oil, octanoate, and many others are able to be encapsulated and are used in the products sold through Derma zone’s brands including CleomeⓇ, Kara VitaⓇ, and Hyssop HealthⓇ [50].

Conclusion

As the largest organ and a physical barrier between the internal human body and harmful microbes and chemicals, the skin plays an essential role as the body’s first line of defense and in maintaining homeostasis among the many systems and biological mechanisms that keep us alive. Not only is it impacted by intrinsic factors that change as the aging process advances, but it must also bear the damage inflicted by years of exposure to unavoidable damaging external factors producing visible blemishes like wrinkles, age spots, and rough patches of skin. Furthermore, as people age the slowing of cell turnover rates and reduction in collagen production result in thinner skin with irregular depressions as the elastin-collagen network of fibers breaks down and loses its structural integrity. To combat these effects, both preventive and treatment measures can be undertaken to minimize the appearance of wrinkles. As vital metabolic reactions proceed within the body and UV radiation infiltrates from outside the body, reactive oxygen species are generated that have the ability to degrade biomolecules like DNA when produced in excess leading to oxidative stress. Preventive methods like consuming a healthy diet rich in antioxidants and minimizing sun exposure by covering up and the application of daily sunscreen can reduce the negative effects of excess ROS. While reflective creams and cosmetic foundation can be used to hide the perception of aging externally, minimally invasive cosmetic treatments like Botox, dermal fillers, and platelet-rich plasma each work in unique ways to lessen the appearance of wrinkles internally [51]. Even more effective in treating aging skin is the use of drugs that are capable of affecting the behavior of cells and processes within the body to reverse aging at a cellular level which manifests in a physical form of more pliable skin, better barrier integrity, and reduction of fine lines. Such compounds include retinoids, vitamins, and peptides. To be effective defenses against skin aging at a cellular level, these compounds must first be able to penetrate the living and nonliving layers of skin to interact with target molecules and processes. To move further than topical treatment, transdermal drugs like the NLP liposome, can be utilized to transport active ingredients and aid in deeper penetration for higher efficacy in reducing the effects of the aging processes.

Future Trends

The maintenance of cellular health is coordinated by generegulatory pathways and a number of cell biological processes. It was once thought that aging is an inevitable process and the natural result of entropy on the cells, tissues, and organs of the body, bringing about the gradual decline of many bodily functions [52] Now, rather than seeing aging as a process of life, scientists are beginning to view physical aging as a disease process. Both the cellular and molecular mechanisms by which aging occurs reveal intricate series of signals and pathways that are responsible for the monitoring and control of lifespan of a cell as it ages. This information reveals that the breakdown of cellular processes is in fact the result of a programmatic decision by the cell to either continue or discontinue maintenance procedures with age. As a result, it only makes sense that cellular reprogramming can be used to reverse the aging leading to the decline in activities and function of mesenchymal stem/stromal cells (MSCs). Through the in-depth studying of these molecular events and pathways, the science of antiaging will be furthered and come another step closer to reversing the aging process. In fact, Dr. Wan-Ju Li is the lead of one such study. When comparing non-rejuvenated parental MSCs to reprogrammed MSCs, scientists were able to recognize the GATA6/SHH/FOXP1 pathway as a key mechanism in the regulation of MSC aging and rejuvenation [53]. The continuation of identifying the underlying mechanisms controlling cell aging-related activities will help improve understanding of the causes of aging and play significant roles in the future of regenerative medicine.

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Discrepancies of Pediatric Data of BNT162b2 mRNA Covid-19 Vaccine in the Assessment Report of the European Medicines Agency

Clinical Efficacy

The Assessment Report of pediatric study of BNT162b2 mRNA Covid-19 Vaccine (Comirnaty) says that there was no cases of Covid-19 in 1119 adolescents 12 to 15 years of age administered vaccine (0%) and there were 18 cases in 1110 (1.6%) of those administered placebo [1]. The vaccine efficacy (Relative Risk Reduction, ARR) is 100% while the Absolute Risk Reduction (ARR) is 1.6 % (18/1119 – 0/1110) [1]. Literally, BNT162b2 mRNA Covid-19 Vaccine prevented mild Covid-19 in 1.6% of the study population. At the cut-off date, no severe cases and no deaths were reported in 12 15 years-old age group1, i.e., no benefit in respect to prevention of severe or death Covid-19 was demonstrated. Prevention of long-term Covid-19 was not investigated.

Safety: Serious Adverse Events

The Assessment Report says that the rate of Serious Adverse Events (SAEs) in adolescents in the time frame from dose 1 to one month after dose 2 (until the data cut-off, 13 March 2021) was very low and similar between vaccine and placebo arms (≤0.4%).1 However, it is a misleading statement:

1) Mixing an active drug arm and a control arm is unacceptable from a scientific point of view. Indeed, there were 5 serious adverse events (SAEs) in the vaccine arm and 2 SAEs in the placebo arm; serious psychiatric events were reported in 4 subjects in the vaccine arm and 0 in the placebo arm [1].

2) In addition, 2 adolescents originally randomized to the placebo had life-threatening SAEs after they turned 16 years during the study and were unblinded to receive BNT162b2, [1]

3) Frequency category “very low” is not consistent with the Medical Dictionary for Regulatory Activities (MedDRA). According to MedDRA, the SAEs should be classified as uncommon (frequency ≥1/1,000 to <1/100).

5 above-mentioned SAEs in adolescents of the BNT162b2 group included [1]:

1) Participant No 1 had neuralgia with 3 emergency room visits beginning day 1 after dose 2 and subsequently, abdominal pain and constipation. She was diagnosed with functional abdominal pain, referred to psychology and physical therapy after which symptoms were reported as gradually improving.

However, SAEs persisted after 1-month post Dose 2 and remained unresolved at the data cut-off (see follow up below),

2) Participants No 2 and 3 had depression,

3) Participant No 4 had concurrent anxiety and depression,

4) Participant No 5 had concurrent appendicitis and focal peritonitis.

2 adolescents originally randomized to the placebo group had life-threatening SAEs after they turned 16 years of age and were unblinded to receive BNT162b2 [1]:

1) Participant No 6: an anaphylactoid reaction reported 3 days after receiving the first dose of BNT162b2 with a duration of 1 day, leading to study withdrawal,

2) Participant No 7: a depression reported 7 days after receiving the first dose of BNT162b2 reported as ongoing/resolved at the time of data cut-off date.

SAEs reported from after 1-month post Dose 2 up to the data cutoff date included suicidal ideation and appendicitis (each appearing in 1 participant) [1]. In participants administered placebo 2 SAEs have been reported [1]. Follow-up data, consistent with Participant No 1, was presented on 28 June 2021 during a meeting organized by Senior United States Senator from Wisconsin Ronald Harold Johnson. Stephanie de Garay described the experiences of her daughter Maddie de Garay after the 2nd dose of the Pfizer Covid-19 vaccine in the pediatric study. Upon receiving her second dose on January 20th, over the next 24 hours, Maddie developed severe abdominal and chest pain. She had extreme pain in her fingers and toes making them turn white and cold. Later, abdominal, muscle, and nerve pain became unbearable. Additional symptoms included gastroparesis, nausea and vomiting, erratic blood pressure and heart rate, memory loss. She mixed up words, had brain fog, headaches, dizziness, fainting, and then seizures, developed verbal and motor tics. She lost feeling from the waist down and got muscle weakness, drastic changes in her vision, urinary retention and loss of bladder control, severe irregular menstrual cycles, and eventually got a nasogastric tube for her nutrition [2].

Discussion

By article 14-a (1) of the Regulation (EC) 726/2004, conditional marketing authorization for medicinal products intended for the treatment or prevention of seriously debilitating or life-threatening diseases may be granted before the submission of comprehensive clinical data [3]. However, Covid-19 is neither a debilitating nor life-threatening disease in the majority of adolescents [4]. Severe cases occur rarely, and predominantly in subjects with underlying conditions, adolescents with risk of severe disease due to underlying conditions were not specifically studied [1]. The study did not demonstrate any benefit in respect to the prevention of severe Covid-19. It demonstrated more SAEs instead: 5 adolescents in the BNT162b2 group reported any SAE from Dose 1 to the data cut-off date up to 1 month after Dose 2. Two adolescents originally randomized to the placebo group had life-threatening SAEs after they turned 16 years during the study and were unblinded to receive BNT162b2. These SAEs are not included in the benefitrisk assessment of the Assessment Report [1]. By the report of the Centers for Disease Control and Prevention from 1 March 2020 to 24 April 2021, the cumulative Covid-19–associated adolescent hospitalization rate was 49.9 per 100,000.2 If we assume that vaccines prevent all cases of severe Covid-19 (49.9/100,000), the absolute risk reduction is 0.05%, i.e., 2000 vaccinations might prevent 1 hospitalization. This means that effectiveness in respect to the risk of hospitalization was about 10 times lower than the frequency of SAEs (by definition, SAE results in death, is lifethreatening, requires hospitalization or prolongation of existing hospitalization, results in persistent or significant disability or incapacity, or a congenital anomaly/birth defect) [4].

COVID-19 pandemics did not increase pediatric mortality in EUROMOMO countries. Instead, pediatric mortality steadily decreased from spring 2020 until June 2021, i.e., beginning of the pediatric vaccination against COVID-19 [5]. Time relation does not mean causation but still should be considered. The pediatric study did not provide data to what extent vaccination provides protection against asymptomatic infection, and whether vaccination prevents further transmission.1 The pediatric data came from the period before the emergence of the Delta variant. There are no bridging studies to extrapolate the pediatric data to today’s situation. The power of the pediatric study was neither sufficient to demonstrate any benefit in terms of reduction of the risk of severe COVID-19 or death nor the risk of serious or life-threatening adverse reactions. It should also be noted that the BNT162b2 mRNA Covid-19 vaccine has been used for mass vaccination in children and therefore any doubt regarding safety or efficacy is unacceptable [6,7].

Conclusion

1) Covid-19 should not be considered a serious, debilitating, or life-threatening disease in 12 to 15-years-old adolescents, i.e., conditions of the conditional marketing authorization are not met.

2) Known benefits of the BNT162b2 vaccine in 12 to 15-years-old adolescents do not exceed known risks. In addition, long-term risks are unknown.

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My Therapy Concept from 25 Years of Experience in Dental Sleep Medicine

Introduction

My therapy concept is based on the idea of using three highly precise aids, that exhibit very little redundancies. The combination of these aids yields a significant increase in quality, effectiveness, and efficiency of the entire treatment process. The aids I am referencing here can be split into three separate solutions: first the vector diagram as a framework, secondly the JS-Gauge® as an instrument and thirdly the F-UPS® as MAD (mandibular advancement device). In our clinic, the combination of these aids has significantly reduced laboratory and treatment times and increased our patients’ satisfaction.

Risk Profiling (Vector Diagram)

Both at the beginning and throughout the MAD therapy [1,2] it is critical to measure specific indicators to help guide decisionmaking. Thus, we can effectively weigh risks and opportunities of the MAD therapy against one another and craft an effective treatment plan. A comprehensive and tailored risk profiling [3] is a viable solution here and creating a framework to standardize the process of identifying these so-called predictors can greatly increase efficiency [4]. Said framework which i developed can be seen in Figure 1 in the form of a vector diagram, which allows us to visually compose a risk profile for each patient. This visual representation further allows for a swift comparison between consecutive risk assessments, to allow for the evaluation of progress throughout the treatment [5]. The predictor values are segmented into three risk groups and color-coded via a traffic light system (red: high risk; yellow: moderate risk; green: low risk).

Figure 1.

Figure 2.

Utilizing this visual aid allows for a quicker assessment that can be intuitively grasped by both the practitioner and the patient. This not only facilitates the interdisciplinary decision-making between the dentist and sleep specialist, but also aids the dentist with educating the patient, thus also informing the patient’s decisionmaking process. Moreover, the vector diagram helps guide the therapeutic decision-making throughout the entire MAD therapy. Therefore, the framework helps to both optimize the starting conditions for the MAD therapy and reduces the risks throughout the therapy. However, this diagram is not intended for the precise recording of all dental parameters. Nor shall it be used to assess the quality of oral health overall. The diagram’s intention is to primarily increase the quality, effectiveness, and efficiency of the therapeutic decision-making process for MAD. Above all, it aims to lay the foundation for treating large patient populations and thus making it a viable tool for the use with public health insurance providers. The risk assessment covered by the vector diagram spans the three areas of biological, mechanical, and functional values of the stomatognathic system.

The biological area relates to periodontics [6], the mechanical area to prosthetics [7] and the functional one to the function [8]. The vectors and the labelling of these 3 areas are shown with different colors light blue, dark blue and black for better visual differentiation. The collected values are marked in the diagram, either with its value in the given selection or scaled on the vector ray. This makes it easier to identify minor changes during a followup. The line connection results in the individual biological risk profile for the MAD therapy. The mechanically relevant findings for tooth loosening, the number of teeth and the profile of the support according to the Eichner classification are also collected. The Eichner classification is subdivided into the profile of the dental or implant logical support and the profile of the occlusal support. The Eichner classification is basically only a classification of the gap dentition according to the profile of the dental support zones intended for prosthetic therapy. However, this classification is not sufficient here for the risk analysis in MAD therapy. In the vector diagram, this classification is therefore further subdivided into a dental and implantological support zone profile without prosthetic gap closure, as well as the occlusal support zone profile at the time of the examination, possibly with prosthetic gap closure. The dental classification is marked without, while the occlusal classification is marked with an asterisk in the vector diagram (Figure 2).

Finally, the 3 relevant functional findings, which include active degree of protrusion, active degree of mouth opening and the graded chronic facial pain after DC/TMD need to be assessed. The active degree of protrusion is measured from the maximum retrusion into the maximum protrusion in the lying position after three attempts. In my opinion and in the opinion of many other colleagues, this is the most precise measurement method. Only values that can be achieved without locking of the jaw or pain are measured. The same procedure is used to measure the active mouth opening. Finally, the GCPS grade is entered from the assessment of the corresponding questionnaire according to DC/TMD, which completes the creation of the risk profile for the function. In (Figure 2) you can see an example of a fully completed primary assessment.

Adjustment and registration with bite gauges (JS-Gauge®)

Once the decision for or against MAD therapy and for or against preparatory measures has been made and these have been completed, the second, most important treatment step follows: the adjustment and registration of the starting position, which is critical to produce a MAD [2].

From January 1, 2022, onwards the MAD therapy will be covered by public health insurance in Germany and the requirements to receive the needed coverage include an individual three-dimensional registration of the starting position [9]. This registration must be tailored to the individual circumstances of the patient as well as to the individual design of the MAD that is to be used. Bite gauges are used as aids for this [10,11]. They offer the advantage of flexible adjustments under functional, neuromuscular conditions when compared to the use of no bite gauge or the axiographs. All bite gauges currently on the market neither fully nor ideally meet these requirements. Bite gauges, which are held between the rows of teeth by the patient biting down, are subject to variability during adjustment and registration, which reduces precision. The precision can be increased considerably by securely fixing the bite gauge to the upper jaw [12]. A bite spoon is fixed to the upper jaw with A-silicone and the lower jaw is supported by means of a support pin registry.

Figure 3.

This allows for more comfort due to a relaxed jaw, interferencefree adjustments and a registration in the lying treatment position without a forced bite. The JS-Gauge® (Figure 3) which i developed consists of the bite spoon, in yellow, the vertical pin, here in turquoise, and the horizontal pin, marked in blue, as well as two fixing screws, colored gray. A standout feature of the JS-Gauge® is that it can be continuously adjusted in all three spatial dimensions sagittally, vertically and transversely. The support of the horizontal pin on the tooth edges of the mandibular incisors, can be continuously adapted for a safe adjustment of the mandible on the JS-Gauge®. The adjustment and registration range (Figure 4) extends sagittally from 20 mm behind and up to 16 mm in front of the upper edge of the incisor. A vertical bite lock can be set from 2,0 mm IID to approx. 14 mm IID. Transversally, the JS-Gauge® allows adjustment 15 mm from the centerline. This transversal adjustment should also be adjusted habitually in a lying position without functional symptoms occurring. We want the patient to be as relaxed as possible.

Figure 4.

Figure 5.

The adjustment with the bite gauge should be tailored to the individual patient’s situation and the design of the MAD [13,14]. With increasing bite blockage with the same protrusion, which can be measured as inter incisor distance (IID) in relation to the upper jaw, the load on the craniomandibular system increases [15]. We can gather from this that the percentage of the same protrusion in relation to the maximum protrusion increases with increasing bite blockage [16]. In this respect, registration with bite gauges should be carried out with as little bite blockage as the bite conditions, the functional findings and the MAD Design allows. The protrusion should be adjusted from the maximum retrusion to approx. 5 mm in the comfort zone of the patient. I recommend a 5 - 10 minute control of this position with regard to the functional findings and the comfort findings of the patient. The 3D adjustment of the starting position is complete if no pathological functional findings occur, and the patient does not complain about discomfort within 5-10 minutes (Figure 5). After use, the JS-Gauge® is reprocessed with the help of the tray and the box. The reprocessing meets the requirements of the MDR (Medical Device Regulation, EU 2017/745) in all stages.

MAD (F-UPS®)

From this starting position, sleep medical titration continues after the MAD has been inserted [2,9]. In order to be able to achieve the lowest possible bite blockage, especially in patients with a deep bite or a flat Spee curve, I developed a MAD (H-UPS®) as early as 1997 [17] that enables this. This leaves the front teeth mostly free. This makes the plastic construction more unstable, yet this instability is absorbed by a steel arch to which the Herbst hinges are attached by laser welding. Although this construction has many advantages, the disadvantage is the mechanics of the Herbst hinge. As every time the patient opens his mouth during the night, a retrusion occurs, frontal elastic bands are intended to prevent this but unfortunately cannot do so completely. If the Herbst telescope is mounted on the MAD in reverse, unphysiological stresses arise on both the MAD and the dental arches as well as on the craniomandibular system when the mouth is opened. Therefore, no desired physiological conditions can be achieved. Inclined planes attached to the side also do not allow a physiological opening of the mouth and do not reliably prevent an opening of the mouth. Frontal elastics are also required here. As we can see all these approaches are at least somewhat flawed.

In my opinion, the solution lies in the fin-like design with the lateral guide elements. I developed a MAD (F-UPS®) in 2018 (Figure 6) that enables this. With these it is possible for the typically mouth openings up to 10 mm IID [18] to physiologically occur during sleep without retrusion, which constitutes a physical adjustment of the guide way of the lateral elements without any loss of effectiveness of the MAD. The guide way of the lateral elements is divided into three parts (Figure 7). From the starting position, the first part starts with a jaw opening with a protrusion movement of up to approx. 5 mm. The protrusion is intended to reflexively prevent the number of further jaw openings with a larger IID during sleep. If there is still another jaw opening, the second part of the movement follows with a jaw opening with unchanged protrusion up to 10 mm IID. Only from 10 mm IID, which normally does not occur during sleep [18], is 3. the further jaw opening with retrusion up to the disconnection of the two splint parts with release for maximum jaw opening. The fins of the F-UPS® are not made separately. In this design, the upper and lower jaw splints are CAD designed and milled from a single block. This is the only way to produce the F-UPS® with this fin design for an optimized function without retrusion and with the ideal recess in the anterior tooth area for the least possible bite blockage with very high stability.

Figure 6.

Figure 7.

Optionally, this sagittal guideway of the lateral elements can be made more precise from the starting position by a further registration in 10 mm IID to be able to shape the guideways transversely. This is e. g. recommended if the jaw opening-path shows a lateral deviation. For this purpose, after the first registration of the starting position, the sagittal, vertical, and transversal setting values are adopted from the JS-Gauge® the IID setting is increased to 10 mm and readjusted, if necessary, according to functional aspects. After frontal and lateral coating with A-silicone, the JSGauge ® is removed. This procedure is possible because the jaw relation can be transferred from a first registration to the second registration by adopting the 3D setting values of the JS-Gauge®. It is therefore not necessary to keep registrations for later new MAD productions. Knowledge of the 3D setting values of the JS gauge is sufficient for this.

Conclusion

During the development of these three aids, the treatment of my patients has steadily improved and due to the use of these aids in conjunction with each other the treatment quality has improved yet again.

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