Innovative Approaches to Shorten Treatment Time

Innovative Approaches to Shorten Treatment Time

**Early Intervention with Invisalign First for Kids**

Early intervention with Invisalign First for kids represents a revolutionary approach in orthodontic care, designed to address dental issues at a young age. This innovative treatment is tailored for children between the ages of 6 and 10, who are in the early stage of dental development. Crowded or crooked teeth can be corrected with braces or aligners Kids' dental alignment services crossbite. By using clear aligners similar to those used in standard Invisalign treatments, Invisalign First provides a discreet and comfortable alternative to traditional braces.


The benefits of early intervention with Invisalign First are extensive. It allows for the early treatment of issues such as crowding, spacing, and alignment problems, which can prevent more severe complications later in life. This system also guides the growth of the jaws and dental arches, ensuring there is enough space for permanent teeth to erupt properly. This not only helps in reducing the need for future extractions or extensive treatments but also sets the stage for a more straightforward and shorter Phase 2 treatment during the teenage years.


Invisalign First is also beneficial in terms of comfort and convenience. The removable aligners make it easier for children to maintain good oral hygiene habits, reducing the risk of cavities and gum disease during treatment. The treatment process is less time and cost-intrusion compared to traditional braces, requiring fewer office visits and potentially shorter treatment times. This can be a desirable option for parents looking for a quicker and more convenient orthodontic solution for their children.


The use of digital technology in Invisalign First allows for precise planning and visualization of the treatment outcome, ensuring that the process is both transparent and effective. With features like customizable retainers and the option to continue enjoying favorite foods without restrictions, Invisalign First offers a comfortable and user friendly experience for young patients.


In summary, early intervention with Invisalign First for kids is an innovative approach that not only shortening treatment time but also provides a comprehensive solution to early orthodontic issues. It offers a comfortable, discreet, and effective way to guide dental development, setting the stage for a lifetime of healthy smiles.

Invisalign First is designed for children aged 6 to 10, using clear, removable aligners to address early orthodontic needs, promoting proper jaw development and teeth alignment without traditional braces. —

In the ever-advocatted journey to perfect dental alignment, innovative treatments have become the highlight of orthodontic progress. Invisalign First, specifically designed for children aged 6 to 10, is a cutting-edge approach that uses clear, removable aligners to address early orthodontic needs. This method not only offers a comfortable alternative to traditional braces but also helps in promoting proper jaw development and teeth alignment.


Invisalign First is part of Phase 1 treatment, which is a proactive approach to orthodontics. It intercepts developing issues before they become more serious, such as crowding, spacing, and jaw misalignment. By using custom-made aligners, this treatment gently guides teeth into better positions, creating space for incoming adult teeth and addressing functional issues early on. The aligners are virtually invisible and removable, making them ideal for young patients who need to eat, brush, or floss without any additional challenges.


One of the most innovative features of Invisalign First is how it utilizes 3D dental imaging technology to tailor the treatment to each child's specific needs. This personalized approach allows orthodontists to accommodate the eruption of permanent teeth and the natural growth of a child's jaw, making it an effective tool for early intervention.


In the scope of shortening treatment and ensuring long term dental well being, Invisalign First can be a beneficial option. By addressing issues early, it can prevent more severe orthodontic problems from developing in the future, which might have called for more extensive and costly treatments. This not only short term benefits but also long term, as it can help children avoid more extensive orthodontic treatments as they get into their adult years.


Invisalign First also offers a more discreet and comfortable option for children, which can make the orthodontic journey smoother for both young patients and their parents. The aligners are light, soft, and easy to remove, making them less restrictive than traditional metal braces. This approach allows children to enjoy their daily activities without any additional concerns about their orthodontic treatment.




Innovative Approaches to Shorten Treatment Time - natural rubber

  1. smile
  2. space
  3. surgery

In the end, Invisalign First is a step in the right innovative approach to orthodontics, especially for young patients. It offers a more comfortable, discreet, and effective way to address early dental issues, promoting healthy jaw development and teeth alignment without the need for traditional braces.

More about us:

Social Media:

Facebook About Us:


Citations and other links

The rise of accelerated orthodontics and what it means for patients

 The rise of accelerated orthodontics and what it means for patients

The rise of accelerated orthodontics has significantly shifted the way patients approach orthodontic treatment, offering a faster and more effective route to achieving a straighter smile.. This innovative approach is particularly appealing to individuals with busy schedules or those who need rapid results, such as for special events like a wedding or graduation.

Posted by on 2025-02-12

How emerging technologies are speeding up orthodontic treatment

 How emerging technologies are speeding up orthodontic treatment

The integration of artificial intelligence (AI) and machine learning into orthodontics is revolutionizing the field by enhancing treatment planning, identifying complex patterns, and optimizing treatment strategies.. These emerging technologies play a pivotal role in creating personalized treatment plans tailored to each patient's unique needs, significantly improving patient experiences. AI, particularly in systems like VISION, automizes tedious tasks in treatment planning by analyzing patient data over time.

Posted by on 2025-02-12

**The HealthyStart System**

The HealthyStart System represents a significant innovation in orthodontic treatment, especially for children. This system is designed to address not only dental alignment issues but also sleep-disordered breathing (SDB) problems, which are often underdiagnosed and can have long term health and behavioral issues if not treated early. The HealthyStart approach is non-invasive, non-pharmaceutical, and pain-free, making it an appealing and stress-free method for children and their parents.


A highlight of the HealthyStart System is that it works with the natural forces of tooth eruption, using soft, comfortable, removable devices to guide teeth into their ideal positions. This approach not only straightens teeth without the need for braces but also enhances jaw development and widens the airways, which can help prevent sleep apnea and other breathing issues. The system is tailored to each child's needs, ensuring a customized treatment plan that aligns with their growth and development.


The treatment involves several phases, starting with habit correction to address harmful oral habits, then using customized appliances to guide the growth and alignment of the lower jaw and ensure proper tooth eruption. This early and natural approach to orthodontic treatment can significantly reduce treatment time and improve long term results by correcting oral health habits early on.


The HealthyStart System also integrates myofunctional therapy, which is continuous and works throughout the night to improve oral function and airway health. This comprehensive approach not only improves dental health but also has a significant potential to enhance overall well-being by reducing symptoms of sleep-disordered breathing, which can include issues like ADD/ADHD, mouth breathing, and daytime sleepiness.


The FasTrack system, a recent advancement in the HealthyStart approach, enhances compliance and effectiveness by reducing the need for daytime exercises. It includes a 5-minute Pulsator session prior to sleep and nighttime wear, making the treatment easier for children to adhere to. This innovation, combined with customized adjunct devices, ensures that each child's treatment is optimized for their specific needs, making it a more personalized and less time-intensve approach to orthodontic care.


The HealthyStart System is a revolutionary departure from traditional orthodontics, not only because it is non-invasive and pain-free but also because it treats the root causes of dental and breathing issues early on. This approach can prevent more severe problems from forming later in life, making it a forward-thinking method in the field of orthodontics and sleep health.

**The HealthyStart System**

This non-invasive approach targets the natural development of children's teeth and jaw, using soft dental appliances to align teeth and address breathing issues, reducing the need for more invasive treatments.

The non-invasive approach to dental treatment in children has been a recent focus in pediatric dentistry, particularly with methods that address both tooth and jaw development. This innovative method utilizes soft dental appliances to align teeth naturally and address breathing issues, significantly reducing the need for more invasive treatments. A primary example of such an approach is the Myobrace system, which is designed to correct underlying causes of crooked teeth by teaching children proper nasal breathing, tongue placement, and swallowing patterns. This not only aligns teeth more naturally but also helps in the development of a healthy airway, which is closely connected to overall health and sleep disorders like sleep apnea.


The Myobrace system includes a series of removable oral appliances and myofunctional training, which are used to correct myofunctional habits that can contribute to dental and breathing issues. Unlike traditional orthodontics, Myobrace is not worn full time, allowing children to easily brush and floss their teeth without dietary restrictions. This approach is particularly effective when treatment starts early, between the ages of three and 10, as it can prevent more extensive interventions in the future.


The benefits of this non-invasive approach are numerous. It not only shortens treatment time by addressing underlying issues early but also offers a more comfortable experience for children, reducing anxiety and discomfort often associated with traditional dental procedures. This method aligns with the growing focus on minimally invasive dentistry, which prioritizes preserving natural tooth structure and reducing the need for invasive treatments like drilling or anesthesia. In the long term, this can result in cost-effective dental care and a more natural, healthy development of children's teeth and jaw.

**Myobrace: A No-Braces Approach**

The Myobrace System offers a no-braces approach to orthodontic treatment, focusing on addressing the underlying causes of malocclusion rather than just its symptoms. This method is designed for children aged 3 to 15 and aims to correct poor oral habits, promote jaw development, and align teeth naturally without the need for invasive procedures like braces or extractions.


The treatment is structured into several stages, each addressing different areas of oral health. The first stage involves correcting habits such as mouth breathing, improper tongue posture, and incorrect swallowing patterns. By promoting nasal breathing and proper tongue positioning, Myobrace encourages healthy jaw growth and development.

Innovative Approaches to Shorten Treatment Time - ceramic

  1. adolescence
  2. American Association of Orthodontists
  3. sedation
This stage is crucial as it sets the foundation for the rest of the treatment by ensuring there is enough space for all teeth to emerge naturally straight.


The following stages focus on arch development and dental alignment. For children with underdeveloped jaws, additional appliances may be used to expand the upper jaw, creating sufficient room for teeth and the tongue. As permanent teeth emerge, Myobrace appliances guide them into their ideal positions, often eliminating the need for fixed braces. The final stage involves retention, where the corrected habits and alignment are maintained long-term, typically through the use of Myobrace retainers.


Myobrace not only improves dental alignment but also offers numerous health benefits. It promotes better breathing habits, which can reduce the risk of respiratory issues such as sleep apnea. It also supports balanced facial growth and can alleviate jaw tension by correcting functional habits. The treatment includes a nutrition program that educates children on healthy dietary choices, essential for strong teeth and jaw bones.


In addition to its health benefits, Myobrace is non-invasive and comfortable, making it an appealing option for parents and children. By focusing on early correction of poor oral habits, Myobrace can reduce the need for braces and extractions, leading to a healthier smile without the discomfort or appearance of fixed appliances. Overall, Myobrace provides a comprehensive approach to orthodontic treatment by addressing the root causes of malocclusion and promoting natural growth and development, making it an innovation in shortening treatment time and improving overall oral health.

Myobrace offers a brace-free solution that corrects poor oral habits, guiding jaw and teeth alignment development in children, promoting natural growth and oral health.

In the innovative approach to orthodontics, Myobrace offers a revolutionary brace-free solution that addresses the root causes of misaligned teeth in children. By focusing on correcting poor oral habits, Myobrace effectively guides the development of jaw and teeth alignment, promoting natural growth and oral health. This comprehensive treatment is designed to straighten teeth, enhance facial development, and improve overall health by teaching children to breathe through their nose, rest their tongue correctly, swallow properly, and keep their lips together.


Myobrace consists of a series of removable dental appliances that are worn for a short period during the day and overnight. This approach not only aligns teeth but also helps develop and align the jaws, which can often eliminate the need for braces later in life. By correcting myofunctional habits early, Myobrace can reduce the severity of malocclusion and improve facial growth, making it a preventive pre-orthodontic treatment ideal for children aged three to 15.


The treatment stages of Myobrace include habit correction, arch development, dental alignment, and retention. By retraining the muscles of the mouth and promoting healthy habits, Myobrace offers a unique and less intervention approach to traditional orthodontics. This method not only shortens the treatment period but also aims to reduce the need for more advanced orthodontic treatments in the future, providing children with a healthy and well-aligned smile from an early age.

**Comprehensive Orthodontic Solutions**

In the journey to achieving a straight and beautiful smile, traditional orthodontic treatments often seem lengthy and time-consuming. However, recent advancements in orthodontic technology have paved the way for innovative approaches that significantly reduce treatment time without compromising effectiveness. These comprehensive orthodontic solutions are designed to expedite tooth movement and facilitate the alignment process, providing adults with a more efficient path to their desired smiles.


One of the most effective methods is photobiomodulation (PBM), which has been shown to significantly reduce the duration of orthodontic treatment. PBM, often performed using near-infrared light, accelerates tooth movement by improving the rate of alignment. For example, the Orthopulse device, which generates continuous beams of near-infrared light, has been demonstrated to increase the alignment rate and reduce total treatment time by as much as 57.5 weeks compared to traditional methods[1].


In addition to PBM, self-ligating braces like Damon braces offer another innovative approach. These braces do not require ligatures, allowing the wire to move through the brackets more precisely and reducing the need for adjustments. This results in faster tooth movement and fewer visits to the orthodontist, reducing treatment time by up to 12 months compared to traditional metal braces[5].


These accelerated techniques not only provide faster results but also increase patient compliance and access to orthodontic treatment. By offering more efficient and less time-consuming solutions, adults are more able to align their orthodontic goals with other life commitments, making comprehensive orthodontic solutions a significant step in the future of orthodontic treatment[3].

Innovative Approaches to Shorten Treatment Time in Orthodontics


Orthodontic treatment has become more personalized and effective with the development of innovative systems tailored to individual needs. The traditional one-size approach is now replaced by a comprehensive suite of solutions that include cutting-edge methods like HealthyStart and Myobrace, in addition to conventional treatments. This blend of modern and traditional orthodontics allows for a more tailored approach, addressing the unique dental needs of each child.


The HealthyStart System is a groundbreaking approach in early orthodontic treatment. It focuses on the natural development of children's teeth and jaw, using soft, comfortable dental appliances to address dental issues from an early age. This non-invasive method promotes healthier sleep patterns and breathing, guiding the growth of dental structures to reduce the need for more invasive treatments later on.


Myobrace offers a brace-free solution to teeth straightening by addressing the underlying causes of misaligned teeth, such as poor oral habits. It utilizes a series of removable dental appliances that are worn daily and overnight to correct these habits, align the jaws, and straighten the teeth. This preventive pre-orthodontic treatment is best suited for children aged 3 to 15 and aims to promote natural growth and development, often reducing the need for braces.


Innovative systems like HealthyStart and Myobrace not only provide a more comfortable and less invasive treatment experience but also help in shortening the overall treatment time. By addressing dental issues early and correcting poor oral habits, these methods can significantly reduce the need for more comprehensive orthodontic treatments later in a child's development. This approach aligns with the modern demand for discreet, effective, and time- and compliance-revasive treatments that enhance patient outcomes while promoting overall health and well-being.


Innovations in orthodontics are not just about new systems; they also include technological advancements like digital impressions and treatment planning, which enhance the efficiency and convenience of orthodontic care. These advancements enable precise treatment planning and monitoring, further reducing treatment timeframes and ensuring optimal results.


Innovative orthodontic solutions are revolutionizing the way dental care is provided, offering a range of options that can be tailored to meet the unique needs of each child. By providing early, effective, and less invasive treatments, these modern methods not only improve dental health but also enhance overall well-being, ensuring that every child can grow up with a healthy, beautiful smile.

The use of technology to reduce treatment time has become a significant focus in both medical and orthodontic care, leading to more efficient and effective treatment processes. In orthodontics, for example, advancements in clear aligners have significantly reduced the duration of treatment. These aligners are designed using advanced 3D imaging technology, allowing for precise and targeted movement of teeth. Patients wear these aligners for most of the day, ensuring consistent pressure and quicker alignment compared to traditional methods like metal braces[1]. The customization of these aligners for each patient further enhances their efficiency by ensuring a snug fit and more effective alignment.


In the medical context, particularly in radiation therapy, new technologies have also been crucial in shortening treatment times. The Halcyon system, for example, offers advanced automation, resulting in about 20% faster treatment times. This technology not only reduces the time patients are under radiation but also improves accuracy by using a device called a "multileaf collimator" to shape the radiation beam precisely to the tumor's size and shape[3]. This approach enhances patient comfort and reduces the possibility of tumor movement during treatment.


In healthcare clinics, reducing treatment times can also significantly improve efficiency. By shortening sessions to as little as 5-10 minutes, clinics can increase patient throughput, optimize scheduling, and minimize idle periods. This not only allows for more patients to be effectively and efficiently care for but also enhances patient satisfaction by reducing wait times and improving overall clinic operations[5]. The integration of technology to streamline workflows and minimize administrative tasks further boosts clinic efficiency, allowing clinicians to focus more on patient care.


In summary, technology plays a vital role in shortening treatment times by enhancing efficiency, improving accuracy, and optimizing resource utilization. Whether in orthodontics, radiation therapy, or general healthcare, these innovations are crucial for delivering quicker and more effective care without sacrificing quality.

Innovations in orthodontic technology have significantly transformed the way treatment plans are designed and executed, leading to more efficient and effective care. Innovative technologies such as iTero and ClinCheck software have emerged as key tools in this evolution, enabling precise adjustments and predictive results that streamline the treatment process.


Digital Orthodontics and Advanced Planning: A Revolution in Treatment Time and Personalization


Digital orthodontics, including tools like iTero intraoral scanners, have revolutionized the initial stages of treatment by replacing traditional impression-taking methods with precise digital scans. These scans provide detailed 3D models of a patient's teeth and jaw structure, allowing orthodontists to assess and plan treatment with unprecedented accuracy. This level of detail ensures that treatment plans are highly personalized, tailored to each patient's unique dental anatomy and alignment issues.


The Role of ClinCheck and iTero in Treatment Planning


The ClinCheck software, used in the Invisalign system, is a powerful tool for creating and visualizing orthodontic treatment plans. It allows doctors to simulate tooth movements and predict treatment outcomes, enabling them to make informed decisions about the most effective treatment approach. ClinCheck's real-time modifications feature, such as ClinCheck Live Update, significantly enhance practice productivity by allowing doctors to make adjustments to treatment plans in real-time, reducing the need for back-and-forth interactions with designers.


The iTero intraoral scanners, on the other end, provide the high-quality digital impressions necessary for creating these personalized plans. By integrating these technologies, orthodontists can design and monitor treatment with greater precision, ensuring that adjustments are made promptly to achieve optimal results.


The Future of Orthodontic Treatment: Shorter Treatment Time and Personalized Approaches


The integration of these innovative technologies not only improves treatment outcomes but also shortening treatment times.

Innovative Approaches to Shorten Treatment Time - natural rubber

  1. ceramic
  2. retainer
  3. natural rubber
By leveraging advanced imaging, simulation, and predictive analysis, orthodontists can anticipate and adapt to changes in treatment progress more effectively. This predictive capability allows for real-time adjustments, ensuring that treatment stays on track and is optimized for each patient's needs.


Furthermore, the use of AI in treatment planning is becoming more significant, as it enhances the precision and efficiency of orthodontic care. AI algorithms can process vast amounts of patient data, refining treatment protocols and optimizing results over time. This iterative process empowers orthodontists to deliver highly personalized care, achieving superior clinical outcomes and improving patient satisfaction.


Innovations like iTero and ClinCheck software are at the cutting-edge of orthodontic technology, transforming the field by providing efficient, effective, and personalized treatment plans. These advancements have not only improved treatment outcomes but have also significantly enhanced the overall patient experience, setting the future of orthodontics on a track of precision, efficiency, and patient-centric care.

In the journey of orthodontic treatment, one of the most critical factors that can impact the duration and success of the process is patient compliance. Innovative strategies to enhance compliance are not only beneficial for short-term results but also for long-term success. This essay will highlight how compliance can be optimized to reduce treatment time while ensuring effective outcomes.


Compliance in orthodontic treatment involves a range of practices, from wearing appliances like Invisalign aligners or braces as per the orthodontist's instructions, to maintaining good oral hygiene and using retainers post-treatment. Each of these practices plays a vital role in ensuring that the treatment is completed efficiently and that the results are long-term. For instance, consistent wear of aligners or elastics can help in aligning teeth more accurately and in less time, while regular brushing and use of an orthodontic toothbrush prevent tooth decay and maintain appliance health.


Motivating patients to comply with their treatment plans is crucial. This can be achieved through strategies such as habit stacking, where new habits are built into existing daily routine, and positive reinforcement, where patients are celebrated for their progress. For example, placing retainers next to toothbrushes can remind patients to wear them consistently. Technology also plays a significant role in improving compliance. Orthodontists can use mobile apps to send reminders for appointments and maintenance, and digital tracking can provide real-time feedback on treatment progress.


In addition to these strategies, accountability is essential. Patients should be aware of the importance of their role in the treatment process and the consequences of poor compliance. This includes understanding that missing appointments or not following instructions can extend treatment duration. By leveraging technology for remote monitoring and using compliance reports to reinforce good habits, patients can be more accountable for their treatment outcomes.


In the end, the success of orthodontic treatment is a collaborative effort between the patient and the orthodontist. By encouraging patient compliance through education, motivation, and technology, treatment times can be reduced, and outcomes can be more effective. This not only short-term results but also long-term success in maintaining a beautiful and healthful dental condition.

In the field of orthodontics, innovative approaches to shorten treatment time have become a significant topic of research and technological advancements. One crucial, often less technological but critical, approach to ensuring timely treatment is comprehensive compliance with treatment guidelines. For treatments like Invisalign, wearing aligners for at least 22 hours a day is essential to achieve the desired results within the prescribed timeline. This adherence is not just a simple rule but a critical part of the treatment plan, as it applies constant pressure on the teeth, gradually moving them into optimal positions.


Invisalign's effectiveness is directly based on the patient's ability to comply with the recommended wear time. If aligners are not worn for the prescribed duration, the teeth and jaw do not receive the necessary pressure to move as planned. This can result in extended treatment times, additional orthodontic checkups, and potentially less optimal outcomes. For example, if a patient fails to wear their aligners for the recommended time, they might not be ready to progress to the next set of aligners at the two-week mark, leading to a more extended treatment period.


In recent years, there have been significant advancements in orthodontic technology designed to accelerate treatment times. These include innovative techniques such as self-ligating braces, AcceleDent, and Propel Orthodontics, which use advanced methods like vibrations and clips to expedite tooth movement. However, even with these cutting-edge methods, patient compliance is still a key success factors. For treatments to be successful and efficient, it is essential for patients to follow the guidelines set by their orthodontists, ensuring that they achieve their desired smile in a timely and efficient manner.


In the end, while technological innovations continue to shorten orthodontic treatment times, the importance of patient compliance should not be over- or mis-enters. It is a critical part of the treatment process that complements the use of advanced techniques, ensuring that patients achieve the best results in the least amount of time.

In the modern orthodontic treatment of children, Invisalign has emerges as a game-changing solution, offering a range of benefits that not only improve dental health but also significantly contribute to a child's overall well-being. One of the most innovative aspects of Invisalign is its ability to effectively address various dental issues, such as overcrowding, spacing, and misalignments, without the need for traditional metal braces. This approach is especially appealing to children and teens who are often self-conscious about their appearance during orthodontic treatment.


The aesthetic appeal of Invisalign is a significant advantage. The clear aligners are virtually invisible, providing a discreet option that allows children to feel more confident during their treatment. Unlike traditional braces, which can be a visible and sometimes uncomfortable addition to a child's smile, Invisalign aligners are designed to be as unobtrusive as they are effective. This discreet nature of Invisalign helps children feel more at ease in their daily activities, from school to sports and other activities where self-esteem can be crucial.


Another key benefit of Invisalign for kids is its comfort. The aligners are crafted from smooth, BPA-free plastic, which significantly enhances comfort by reducing irritation and soreness often associated with traditional braces. This comfort aspect is crucial for children, who may be more adaptable to wearing orthodontic appliances but can also be more easily discomforted by sharp edges or metal components.


Invisalign also promotes better oral hygiene. The aligners are removable, allowing children to brush and floss their teeth without any restrictions. This feature is especially important for maintaining good dental health, as it ensures that children can clean their teeth and gums effectively, reducing the risk of cavities and gum issues. In addition, the ability to remove the aligners during meals means that children can enjoy their favorite foods without restrictions, unlike with traditional braces, which often have specific food restrictions to prevent damage to the metal components.


In terms of treatment time, Invisalign can provide results in a timeframe comparable to traditional braces. This efficient treatment time, along with the flexibility of removable aligners, makes Invisalign an appealing choice for families seeking to minimize the duration of orthodontic treatment. The use of advanced digital technology, such as 3D imaging and computer-aided design, ensures that treatment plans are personalized and tailored to address each child's unique dental needs, contributing to more effective outcomes.


In innovative terms, Invisalign's approach to shortening treatment time involves the use of advanced materials and technology. The SmartTrack material used in Invisalign aligners is designed for comfort and predictable results, ensuring that teeth are straightening effectively throughout the treatment process. This, along with the customized treatment plans, helps in ensuring that the treatment is both efficient and effective.


Invisalign's benefits for kids are not just about the treatment process; they also include long term advantages. For example, after treatment, maintaining a healthy smile is easier with Invisalign, as the aligners do not leave any metal components that can sometimes result in dental issues like white spots on the teeth or root resorption.


In short, Invisalign offers a modern, innovative approach to orthodontic treatment for children, providing a comfortable, discreet, and effective solution that not only enhances dental health but also promotes confidence and well-being.

Invisalign has become a popular choice for orthodontic treatment, not just for adults but also for children, thanks to several innovative features that offer improved comfort, convenience, hygiene, and aesthetics compared to traditional metal braces. While the term "Invisalign offers improved comfort, convenience, hygiene, and aesthetics compared to traditional metal braces, making it a popular choice for children's orthodontic treatment " is not directly supported by the search results, the benefits of Invisalign are well-enters in the adult and teenager orthodontic treatment. Here's a short essay on innovative methods that Invisalign has developed to potentially offer these benefits and to significantly shortening treatment times:


Invisalign has significantly advanced the orthodontic treatment process by offering several benefits that traditional metal braces often can't match. For children, the nearly invisible appearance of Invisalign aligners can be especially appealing, as it allows them to maintain a more discreet smile during treatment. The removability of Invisalign aligners also makes oral hygiene routines much simpler, as they can be easily removed for regular dental hygiene and during special occasions.


One of the most innovative features of Invisalign is the use of advanced materials and technology to speed up treatment times. The introduction of weekly aligner changes for suitable candidates has accelerated treatment progress, reducing overall treatment time compared to traditional methods. Innovations in materials and design are leading to faster treatment times, sometimes achieving results in as little as six months. This quick turnaround is a game-changer for those looking for immediate results without compromising quality.


Furthermore, Invisalign's use of advanced 3D imaging technology allows for precise digital treatment planning. This precision means that treatment can be tailored to each individual's needs, delivering better results in a shorter time frame. The controlled process of gradually aligning teeth with a series of aligners also means there is less need for in-office adjustments, which adds to the convenience of the treatment.


Innovations in comfort are also a key focus for Invisalign. Future aligners will feature smoother edges and lighter materials, making them more comfortable to wear. This focus on user experience will encourage more people to choose Invisalign over traditional braces, potentially making it a more appealing choice for children's orthodontic treatment as well.


Overall, Invisalign's innovative design and technology have significantly improved the efficiency and comfort of orthodontic treatment, making it a popular choice for those looking for a more discreet, comfortable, and efficient solution. While specific benefits for children may not be detailed in the search results, the overall benefits of Invisalign align well with what many patients, both adults and children, are looking for in orthodontic treatment.

This article is about the anatomical part. For the mountain, see The Jaw. For other uses, see Jaws (disambiguation) and Jawbone (disambiguation).
Human lower jaw viewed from the left

The jaws are a pair of opposable articulated structures at the entrance of the mouth, typically used for grasping and manipulating food. The term jaws is also broadly applied to the whole of the structures constituting the vault of the mouth and serving to open and close it and is part of the body plan of humans and most animals.

Arthropods

[edit]
Further information: Mandible (arthropod mouthpart) and Mandible (insect mouthpart)
The mandibles of a bull ant

In arthropods, the jaws are chitinous and oppose laterally, and may consist of mandibles or chelicerae. These jaws are often composed of numerous mouthparts. Their function is fundamentally for food acquisition, conveyance to the mouth, and/or initial processing (mastication or chewing). Many mouthparts and associate structures (such as pedipalps) are modified legs.

Vertebrates

[edit]

In most vertebrates, the jaws are bony or cartilaginous and oppose vertically, comprising an upper jaw and a lower jaw. The vertebrate jaw is derived from the most anterior two pharyngeal arches supporting the gills, and usually bears numerous teeth.

Jaws of a great white shark

Fish

[edit]
Moray eels have two sets of jaws: the oral jaws that capture prey and the pharyngeal jaws that advance into the mouth and move prey from the oral jaws to the esophagus for swallowing.
Main article: Fish jaw

The vertebrate jaw probably originally evolved in the Silurian period and appeared in the Placoderm fish which further diversified in the Devonian. The two most anterior pharyngeal arches are thought to have become the jaw itself and the hyoid arch, respectively. The hyoid system suspends the jaw from the braincase of the skull, permitting great mobility of the jaws. While there is no fossil evidence directly to support this theory, it makes sense in light of the numbers of pharyngeal arches that are visible in extant jawed vertebrates (the Gnathostomes), which have seven arches, and primitive jawless vertebrates (the Agnatha), which have nine.

The original selective advantage offered by the jaw may not be related to feeding, but rather to increased respiration efficiency.[1] The jaws were used in the buccal pump (observable in modern fish and amphibians) that pumps water across the gills of fish or air into the lungs in the case of amphibians. Over evolutionary time the more familiar use of jaws (to humans), in feeding, was selected for and became a very important function in vertebrates. Many teleost fish have substantially modified jaws for suction feeding and jaw protrusion, resulting in highly complex jaws with dozens of bones involved.[2]

Amphibians, reptiles, and birds

[edit]

The jaw in tetrapods is substantially simplified compared to fish. Most of the upper jaw bones (premaxilla, maxilla, jugal, quadratojugal, and quadrate) have been fused to the braincase, while the lower jaw bones (dentary, splenial, angular, surangular, and articular) have been fused together into a unit called the mandible. The jaw articulates via a hinge joint between the quadrate and articular. The jaws of tetrapods exhibit varying degrees of mobility between jaw bones. Some species have jaw bones completely fused, while others may have joints allowing for mobility of the dentary, quadrate, or maxilla. The snake skull shows the greatest degree of cranial kinesis, which allows the snake to swallow large prey items.

Mammals

[edit]

In mammals, the jaws are made up of the mandible (lower jaw) and the maxilla (upper jaw). In the ape, there is a reinforcement to the lower jaw bone called the simian shelf. In the evolution of the mammalian jaw, two of the bones of the jaw structure (the articular bone of the lower jaw, and quadrate) were reduced in size and incorporated into the ear, while many others have been fused together.[3] As a result, mammals show little or no cranial kinesis, and the mandible is attached to the temporal bone by the temporomandibular joints. Temporomandibular joint dysfunction is a common disorder of these joints, characterized by pain, clicking and limitation of mandibular movement.[4] Especially in the therian mammal, the premaxilla that constituted the anterior tip of the upper jaw in reptiles has reduced in size; and most of the mesenchyme at the ancestral upper jaw tip has become a protruded mammalian nose.[5]

Sea urchins

[edit]

Sea urchins possess unique jaws which display five-part symmetry, termed the Aristotle's lantern. Each unit of the jaw holds a single, perpetually growing tooth composed of crystalline calcium carbonate.

See also

[edit]
  • Muscles of mastication
  • Otofacial syndrome
  • Predentary
  • Prognathism
  • Rostral bone

References

[edit]
  1. ^ Smith, M.M.; Coates, M.I. (2000). "10. Evolutionary origins of teeth and jaws: developmental models and phylogenetic patterns". In Teaford, Mark F.; Smith, Moya Meredith; Ferguson, Mark W.J. (eds.). Development, function and evolution of teeth. Cambridge: Cambridge University Press. p. 145. ISBN 978-0-521-57011-4.
  2. ^ Anderson, Philip S.L; Westneat, Mark (28 November 2006). "Feeding mechanics and bite force modelling of the skull of Dunkleosteus terrelli, an ancient apex predator". Biology Letters. pp. 77–80. doi:10.1098/rsbl.2006.0569. PMC 2373817. PMID 17443970. cite web: Missing or empty |url= (help)
  3. ^ Allin EF (December 1975). "Evolution of the mammalian middle ear". J. Morphol. 147 (4): 403–37. doi:10.1002/jmor.1051470404. PMID 1202224. S2CID 25886311.
  4. ^ Wright, Edward F. (2010). Manual of temporomandibular disorders (2nd ed.). Ames, Iowa: Wiley-Blackwell. ISBN 978-0-8138-1324-0.
  5. ^ Higashiyama, Hiroki; Koyabu, Daisuke; Hirasawa, Tatsuya; Werneburg, Ingmar; Kuratani, Shigeru; Kurihara, Hiroki (November 2, 2021). "Mammalian face as an evolutionary novelty". PNAS. 118 (44): e2111876118. Bibcode:2021PNAS..11811876H. doi:10.1073/pnas.2111876118. PMC 8673075. PMID 34716275.
[edit]
  • Media related to Jaw bones at Wikimedia Commons
Look up jaw in Wiktionary, the free dictionary.
  • Jaw at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
 
 

 

This article is about the branch of medicine. For the journal, see Pediatrics (journal). For the branch of dentistry, see Pedodontics.

 

Pediatrics
A pediatrician examines a neonate.
Focus Infants, Children, Adolescents, and Young Adults
Subdivisions Paediatric cardiology, neonatology, critical care, pediatric oncology, hospital medicine, primary care, others (see below)
Significant diseases Congenital diseases, Infectious diseases, Childhood cancer, Mental disorders
Significant tests World Health Organization Child Growth Standards
Specialist Pediatrician
Glossary Glossary of medicine

Pediatrics (American English) also spelled paediatrics (British English), is the branch of medicine that involves the medical care of infants, children, adolescents, and young adults. In the United Kingdom, pediatrics covers many of their youth until the age of 18.[1] The American Academy of Pediatrics recommends people seek pediatric care through the age of 21, but some pediatric subspecialists continue to care for adults up to 25.[2][3] Worldwide age limits of pediatrics have been trending upward year after year.[4] A medical doctor who specializes in this area is known as a pediatrician, or paediatrician. The word pediatrics and its cognates mean "healer of children", derived from the two Greek words: παá¿–ς (pais "child") and á¼°ατρÏŒς (iatros "doctor, healer"). Pediatricians work in clinics, research centers, universities, general hospitals and children's hospitals, including those who practice pediatric subspecialties (e.g. neonatology requires resources available in a NICU).

History

[edit]
Part of Great Ormond Street Hospital in London, United Kingdom, which was the first pediatric hospital in the English-speaking world.

The earliest mentions of child-specific medical problems appear in the Hippocratic Corpus, published in the fifth century B.C., and the famous Sacred Disease. These publications discussed topics such as childhood epilepsy and premature births. From the first to fourth centuries A.D., Greek philosophers and physicians Celsus, Soranus of Ephesus, Aretaeus, Galen, and Oribasius, also discussed specific illnesses affecting children in their works, such as rashes, epilepsy, and meningitis.[5] Already Hippocrates, Aristotle, Celsus, Soranus, and Galen[6] understood the differences in growing and maturing organisms that necessitated different treatment: Ex toto non sic pueri ut viri curari debent ("In general, boys should not be treated in the same way as men").[7] Some of the oldest traces of pediatrics can be discovered in Ancient India where children's doctors were called kumara bhrtya.[6]

Even though some pediatric works existed during this time, they were scarce and rarely published due to a lack of knowledge in pediatric medicine. Sushruta Samhita, an ayurvedic text composed during the sixth century BCE, contains the text about pediatrics.[8] Another ayurvedic text from this period is Kashyapa Samhita.[9][10] A second century AD manuscript by the Greek physician and gynecologist Soranus of Ephesus dealt with neonatal pediatrics.[11] Byzantine physicians Oribasius, Aëtius of Amida, Alexander Trallianus, and Paulus Aegineta contributed to the field.[6] The Byzantines also built brephotrophia (crêches).[6] Islamic Golden Age writers served as a bridge for Greco-Roman and Byzantine medicine and added ideas of their own, especially Haly Abbas, Yahya Serapion, Abulcasis, Avicenna, and Averroes. The Persian philosopher and physician al-Razi (865–925), sometimes called the father of pediatrics, published a monograph on pediatrics titled Diseases in Children.[12][13] Also among the first books about pediatrics was Libellus [Opusculum] de aegritudinibus et remediis infantium 1472 ("Little Book on Children Diseases and Treatment"), by the Italian pediatrician Paolo Bagellardo.[14][5] In sequence came Bartholomäus Metlinger's Ein Regiment der Jungerkinder 1473, Cornelius Roelans (1450–1525) no title Buchlein, or Latin compendium, 1483, and Heinrich von Louffenburg (1391–1460) Versehung des Leibs written in 1429 (published 1491), together form the Pediatric Incunabula, four great medical treatises on children's physiology and pathology.[6]

While more information about childhood diseases became available, there was little evidence that children received the same kind of medical care that adults did.[15] It was during the seventeenth and eighteenth centuries that medical experts started offering specialized care for children.[5] The Swedish physician Nils Rosén von Rosenstein (1706–1773) is considered to be the founder of modern pediatrics as a medical specialty,[16][17] while his work The diseases of children, and their remedies (1764) is considered to be "the first modern textbook on the subject".[18] However, it was not until the nineteenth century that medical professionals acknowledged pediatrics as a separate field of medicine. The first pediatric-specific publications appeared between the 1790s and the 1920s.[19]

Etymology

[edit]

The term pediatrics was first introduced in English in 1859 by Abraham Jacobi. In 1860, he became "the first dedicated professor of pediatrics in the world."[20] Jacobi is known as the father of American pediatrics because of his many contributions to the field.[21][22] He received his medical training in Germany and later practiced in New York City.[23]

The first generally accepted pediatric hospital is the Hôpital des Enfants Malades (French: Hospital for Sick Children), which opened in Paris in June 1802 on the site of a previous orphanage.[24] From its beginning, this famous hospital accepted patients up to the age of fifteen years,[25] and it continues to this day as the pediatric division of the Necker-Enfants Malades Hospital, created in 1920 by merging with the nearby Necker Hospital, founded in 1778.[26]

In other European countries, the Charité (a hospital founded in 1710) in Berlin established a separate Pediatric Pavilion in 1830, followed by similar institutions at Saint Petersburg in 1834, and at Vienna and Breslau (now WrocÅ‚aw), both in 1837. In 1852 Britain's first pediatric hospital, the Hospital for Sick Children, Great Ormond Street was founded by Charles West.[24] The first Children's hospital in Scotland opened in 1860 in Edinburgh.[27] In the US, the first similar institutions were the Children's Hospital of Philadelphia, which opened in 1855, and then Boston Children's Hospital (1869).[28] Subspecialties in pediatrics were created at the Harriet Lane Home at Johns Hopkins by Edwards A. Park.[29]

Differences between adult and pediatric medicine

[edit]

The body size differences are paralleled by maturation changes. The smaller body of an infant or neonate is substantially different physiologically from that of an adult. Congenital defects, genetic variance, and developmental issues are of greater concern to pediatricians than they often are to adult physicians. A common adage is that children are not simply "little adults". The clinician must take into account the immature physiology of the infant or child when considering symptoms, prescribing medications, and diagnosing illnesses.[30]

Pediatric physiology directly impacts the pharmacokinetic properties of drugs that enter the body. The absorption, distribution, metabolism, and elimination of medications differ between developing children and grown adults.[30][31][32] Despite completed studies and reviews, continual research is needed to better understand how these factors should affect the decisions of healthcare providers when prescribing and administering medications to the pediatric population.[30]

Absorption

[edit]

Many drug absorption differences between pediatric and adult populations revolve around the stomach. Neonates and young infants have increased stomach pH due to decreased acid secretion, thereby creating a more basic environment for drugs that are taken by mouth.[31][30][32] Acid is essential to degrading certain oral drugs before systemic absorption. Therefore, the absorption of these drugs in children is greater than in adults due to decreased breakdown and increased preservation in a less acidic gastric space.[31]

Children also have an extended rate of gastric emptying, which slows the rate of drug absorption.[31][32]

Drug absorption also depends on specific enzymes that come in contact with the oral drug as it travels through the body. Supply of these enzymes increase as children continue to develop their gastrointestinal tract.[31][32] Pediatric patients have underdeveloped proteins, which leads to decreased metabolism and increased serum concentrations of specific drugs. However, prodrugs experience the opposite effect because enzymes are necessary for allowing their active form to enter systemic circulation.[31]

Distribution

[edit]

Percentage of total body water and extracellular fluid volume both decrease as children grow and develop with time. Pediatric patients thus have a larger volume of distribution than adults, which directly affects the dosing of hydrophilic drugs such as beta-lactam antibiotics like ampicillin.[31] Thus, these drugs are administered at greater weight-based doses or with adjusted dosing intervals in children to account for this key difference in body composition.[31][30]

Infants and neonates also have fewer plasma proteins. Thus, highly protein-bound drugs have fewer opportunities for protein binding, leading to increased distribution.[30]

Metabolism

[edit]

Drug metabolism primarily occurs via enzymes in the liver and can vary according to which specific enzymes are affected in a specific stage of development.[31] Phase I and Phase II enzymes have different rates of maturation and development, depending on their specific mechanism of action (i.e. oxidation, hydrolysis, acetylation, methylation, etc.). Enzyme capacity, clearance, and half-life are all factors that contribute to metabolism differences between children and adults.[31][32] Drug metabolism can even differ within the pediatric population, separating neonates and infants from young children.[30]

Elimination

[edit]

Drug elimination is primarily facilitated via the liver and kidneys.[31] In infants and young children, the larger relative size of their kidneys leads to increased renal clearance of medications that are eliminated through urine.[32] In preterm neonates and infants, their kidneys are slower to mature and thus are unable to clear as much drug as fully developed kidneys. This can cause unwanted drug build-up, which is why it is important to consider lower doses and greater dosing intervals for this population.[30][31] Diseases that negatively affect kidney function can also have the same effect and thus warrant similar considerations.[31]

Pediatric autonomy in healthcare

[edit]

A major difference between the practice of pediatric and adult medicine is that children, in most jurisdictions and with certain exceptions, cannot make decisions for themselves. The issues of guardianship, privacy, legal responsibility, and informed consent must always be considered in every pediatric procedure. Pediatricians often have to treat the parents and sometimes, the family, rather than just the child. Adolescents are in their own legal class, having rights to their own health care decisions in certain circumstances. The concept of legal consent combined with the non-legal consent (assent) of the child when considering treatment options, especially in the face of conditions with poor prognosis or complicated and painful procedures/surgeries, means the pediatrician must take into account the desires of many people, in addition to those of the patient.[citation needed]

History of pediatric autonomy

[edit]

The term autonomy is traceable to ethical theory and law, where it states that autonomous individuals can make decisions based on their own logic.[33] Hippocrates was the first to use the term in a medical setting. He created a code of ethics for doctors called the Hippocratic Oath that highlighted the importance of putting patients' interests first, making autonomy for patients a top priority in health care.[34]  

In ancient times, society did not view pediatric medicine as essential or scientific.[35] Experts considered professional medicine unsuitable for treating children. Children also had no rights. Fathers regarded their children as property, so their children's health decisions were entrusted to them.[5] As a result, mothers, midwives, "wise women", and general practitioners treated the children instead of doctors.[35] Since mothers could not rely on professional medicine to take care of their children, they developed their own methods, such as using alkaline soda ash to remove the vernix at birth and treating teething pain with opium or wine. The absence of proper pediatric care, rights, and laws in health care to prioritize children's health led to many of their deaths. Ancient Greeks and Romans sometimes even killed healthy female babies and infants with deformities since they had no adequate medical treatment and no laws prohibiting infanticide.[5]

In the twentieth century, medical experts began to put more emphasis on children's rights. In 1989, in the United Nations Rights of the Child Convention, medical experts developed the Best Interest Standard of Child to prioritize children's rights and best interests. This event marked the onset of pediatric autonomy. In 1995, the American Academy of Pediatrics (AAP) finally acknowledged the Best Interest Standard of a Child as an ethical principle for pediatric decision-making, and it is still being used today.[34]

Parental authority and current medical issues

[edit]

The majority of the time, parents have the authority to decide what happens to their child. Philosopher John Locke argued that it is the responsibility of parents to raise their children and that God gave them this authority. In modern society, Jeffrey Blustein, modern philosopher and author of the book Parents and Children: The Ethics of Family, argues that parental authority is granted because the child requires parents to satisfy their needs. He believes that parental autonomy is more about parents providing good care for their children and treating them with respect than parents having rights.[36] The researcher Kyriakos Martakis, MD, MSc, explains that research shows parental influence negatively affects children's ability to form autonomy. However, involving children in the decision-making process allows children to develop their cognitive skills and create their own opinions and, thus, decisions about their health. Parental authority affects the degree of autonomy the child patient has. As a result, in Argentina, the new National Civil and Commercial Code has enacted various changes to the healthcare system to encourage children and adolescents to develop autonomy. It has become more crucial to let children take accountability for their own health decisions.[37]

In most cases, the pediatrician, parent, and child work as a team to make the best possible medical decision. The pediatrician has the right to intervene for the child's welfare and seek advice from an ethics committee. However, in recent studies, authors have denied that complete autonomy is present in pediatric healthcare. The same moral standards should apply to children as they do to adults. In support of this idea is the concept of paternalism, which negates autonomy when it is in the patient's interests. This concept aims to keep the child's best interests in mind regarding autonomy. Pediatricians can interact with patients and help them make decisions that will benefit them, thus enhancing their autonomy. However, radical theories that question a child's moral worth continue to be debated today.[37] Authors often question whether the treatment and equality of a child and an adult should be the same. Author Tamar Schapiro notes that children need nurturing and cannot exercise the same level of authority as adults.[38] Hence, continuing the discussion on whether children are capable of making important health decisions until this day.

Modern advancements

[edit]

According to the Subcommittee of Clinical Ethics of the Argentinean Pediatric Society (SAP), children can understand moral feelings at all ages and can make reasonable decisions based on those feelings. Therefore, children and teens are deemed capable of making their own health decisions when they reach the age of 13. Recently, studies made on the decision-making of children have challenged that age to be 12.[37]

Technology has made several modern advancements that contribute to the future development of child autonomy, for example, unsolicited findings (U.F.s) of pediatric exome sequencing. They are findings based on pediatric exome sequencing that explain in greater detail the intellectual disability of a child and predict to what extent it will affect the child in the future. Genetic and intellectual disorders in children make them incapable of making moral decisions, so people look down upon this kind of testing because the child's future autonomy is at risk. It is still in question whether parents should request these types of testing for their children. Medical experts argue that it could endanger the autonomous rights the child will possess in the future. However, the parents contend that genetic testing would benefit the welfare of their children since it would allow them to make better health care decisions.[39] Exome sequencing for children and the decision to grant parents the right to request them is a medically ethical issue that many still debate today.

Education requirements

[edit]

Aspiring medical students will need 4 years of undergraduate courses at a college or university, which will get them a BS, BA or other bachelor's degree. After completing college, future pediatricians will need to attend 4 years of medical school (MD/DO/MBBS) and later do 3 more years of residency training, the first year of which is called "internship." After completing the 3 years of residency, physicians are eligible to become certified in pediatrics by passing a rigorous test that deals with medical conditions related to young children.[citation needed]

In high school, future pediatricians are required to take basic science classes such as biology, chemistry, physics, algebra, geometry, and calculus. It is also advisable to learn a foreign language (preferably Spanish in the United States) and be involved in high school organizations and extracurricular activities. After high school, college students simply need to fulfill the basic science course requirements that most medical schools recommend and will need to prepare to take the MCAT (Medical College Admission Test) in their junior or early senior year in college. Once attending medical school, student courses will focus on basic medical sciences like human anatomy, physiology, chemistry, etc., for the first three years, the second year of which is when medical students start to get hands-on experience with actual patients.[40]

Training of pediatricians

[edit]
Pediatrics
Occupation
Names
  • Pediatrician
  • Paediatrician
Occupation type
 Specialty
Activity sectors
 Medicine
Description
Education required
  • Doctor of Medicine
  • Doctor of Osteopathic Medicine
  • Bachelor of Medicine, Bachelor of Surgery (MBBS/MBChB)
Fields of
employment
 Hospitals, Clinics

The training of pediatricians varies considerably across the world. Depending on jurisdiction and university, a medical degree course may be either undergraduate-entry or graduate-entry. The former commonly takes five or six years and has been usual in the Commonwealth. Entrants to graduate-entry courses (as in the US), usually lasting four or five years, have previously completed a three- or four-year university degree, commonly but by no means always in sciences. Medical graduates hold a degree specific to the country and university in and from which they graduated. This degree qualifies that medical practitioner to become licensed or registered under the laws of that particular country, and sometimes of several countries, subject to requirements for "internship" or "conditional registration".

Pediatricians must undertake further training in their chosen field. This may take from four to eleven or more years depending on jurisdiction and the degree of specialization.

In the United States, a medical school graduate wishing to specialize in pediatrics must undergo a three-year residency composed of outpatient, inpatient, and critical care rotations. Subspecialties within pediatrics require further training in the form of 3-year fellowships. Subspecialties include critical care, gastroenterology, neurology, infectious disease, hematology/oncology, rheumatology, pulmonology, child abuse, emergency medicine, endocrinology, neonatology, and others.[41]

In most jurisdictions, entry-level degrees are common to all branches of the medical profession, but in some jurisdictions, specialization in pediatrics may begin before completion of this degree. In some jurisdictions, pediatric training is begun immediately following the completion of entry-level training. In other jurisdictions, junior medical doctors must undertake generalist (unstreamed) training for a number of years before commencing pediatric (or any other) specialization. Specialist training is often largely under the control of 'pediatric organizations (see below) rather than universities and depends on the jurisdiction.

Subspecialties

[edit]

Subspecialties of pediatrics include:

(not an exhaustive list)

  • Addiction medicine (multidisciplinary)
  • Adolescent medicine
  • Child abuse pediatrics
  • Clinical genetics
  • Clinical informatics
  • Developmental-behavioral pediatrics
  • Headache medicine
  • Hospital medicine
  • Medical toxicology
  • Metabolic medicine
  • Neonatology/Perinatology
  • Pain medicine (multidisciplinary)
  • Palliative care (multidisciplinary)
  • Pediatric allergy and immunology
  • Pediatric cardiology
    • Pediatric cardiac critical care
  • Pediatric critical care
    • Neurocritical care
    • Pediatric cardiac critical care
  • Pediatric emergency medicine
  • Pediatric endocrinology
  • Pediatric gastroenterology
    • Transplant hepatology
  • Pediatric hematology
  • Pediatric infectious disease
  • Pediatric nephrology
  • Pediatric oncology
    • Pediatric neuro-oncology
  • Pediatric pulmonology
  • Primary care
  • Pediatric rheumatology
  • Sleep medicine (multidisciplinary)
  • Social pediatrics
  • Sports medicine

Other specialties that care for children

[edit]

(not an exhaustive list)

  • Child neurology
    • Addiction medicine (multidisciplinary)
    • Brain injury medicine
    • Clinical neurophysiology
    • Epilepsy
    • Headache medicine
    • Neurocritical care
    • Neuroimmunology
    • Neuromuscular medicine
    • Pain medicine (multidisciplinary)
    • Palliative care (multidisciplinary)
    • Pediatric neuro-oncology
    • Sleep medicine (multidisciplinary)
  • Child and adolescent psychiatry, subspecialty of psychiatry
  • Neurodevelopmental disabilities
  • Pediatric anesthesiology, subspecialty of anesthesiology
  • Pediatric dentistry, subspecialty of dentistry
  • Pediatric dermatology, subspecialty of dermatology
  • Pediatric gynecology
  • Pediatric neurosurgery, subspecialty of neurosurgery
  • Pediatric ophthalmology, subspecialty of ophthalmology
  • Pediatric orthopedic surgery, subspecialty of orthopedic surgery
  • Pediatric otolaryngology, subspecialty of otolaryngology
  • Pediatric plastic surgery, subspecialty of plastic surgery
  • Pediatric radiology, subspecialty of radiology
  • Pediatric rehabilitation medicine, subspecialty of physical medicine and rehabilitation
  • Pediatric surgery, subspecialty of general surgery
  • Pediatric urology, subspecialty of urology

See also

[edit]
  • American Academy of Pediatrics
  • American Osteopathic Board of Pediatrics
  • Center on Media and Child Health (CMCH)
  • Children's hospital
  • List of pediatric organizations
  • List of pediatrics journals
  • Medical specialty
  • Pediatric Oncall
  • Pain in babies
  • Royal College of Paediatrics and Child Health
  • Pediatric environmental health

References

[edit]
  1. ^ "Paediatrics" (PDF). nhs.uk. Archived (PDF) from the original on 13 July 2020. Retrieved 2 July 2020.
  2. ^ "Choosing a Pediatrician for Your New Baby (for Parents) - Nemours KidsHealth". kidshealth.org. Archived from the original on 14 July 2020. Retrieved 13 July 2020.
  3. ^ "Age limits of pediatrics". Pediatrics. 81 (5): 736. May 1988. doi:10.1542/peds.81.5.736. PMID 3357740. S2CID 245164191. Archived from the original on 19 April 2017. Retrieved 18 April 2017.
  4. ^ Sawyer, Susan M.; McNeil, Robyn; Francis, Kate L.; Matskarofski, Juliet Z.; Patton, George C.; Bhutta, Zulfiqar A.; Esangbedo, Dorothy O.; Klein, Jonathan D. (1 November 2019). "The age of paediatrics". The Lancet Child & Adolescent Health. 3 (11): 822–830. doi:10.1016/S2352-4642(19)30266-4. ISSN 2352-4642. PMID 31542355. S2CID 202732818.
  5. ^ a b c d e Duffin, Jacalyn (2010). History of Medicine, Second Edition: A Scandalously Short Introduction. University of Toronto Press.
  6. ^ a b c d e Colón, A. R.; Colón, P. A. (January 1999). Nurturing children: a history of pediatrics. Greenwood Press. ISBN 978-0-313-31080-5. Retrieved 20 October 2012.
  7. ^ Celsus, De Medicina, Book 3, Chapter 7, § 1.
  8. ^ John G. Raffensperger. Children's Surgery: A Worldwide History. McFarland. p. 21.
  9. ^ David Levinson; Karen Christensen. Encyclopedia of modern Asia. Vol. 4. Charles Scribner's Sons. p. 116.
  10. ^ Desai, A.B. Textbook Of Paediatrics. Orient blackswan. p. 1.
  11. ^ Dunn, P. M. (1995). "Soranus of Ephesus (Circa AD 98-138) and perinatal care in Roman times". Archives of Disease in Childhood. Fetal and Neonatal Edition. 73 (1): F51 – F52. doi:10.1136/fn.73.1.f51. PMC 2528358. PMID 7552600.
  12. ^ Elgood, Cyril (2010). A Medical History of Persia and The Eastern Caliphate (1st ed.). London: Cambridge. pp. 202–203. ISBN 978-1-108-01588-2. By writing a monograph on 'Diseases in Children' he may also be looked upon as the father of paediatrics.
  13. ^ U.S. National Library of Medicine, "Islamic Culture and the Medical Arts, Al-Razi, the Clinician" [1] Archived 5 January 2018 at the Wayback Machine
  14. ^ "Achar S Textbook Of Pediatrics (Third Edition)". A. B. Desai (ed.) (1989). p.1. ISBN 81-250-0440-8
  15. ^ Stern, Alexandra Minna; Markel, Howard (2002). Formative Years: Children's Health in the United States, 1880-2000. University of Michigan Press. pp. 23–24. doi:10.3998/mpub.17065. ISBN 978-0-472-02503-9. Archived from the original on 30 November 2021. Retrieved 30 November 2021.
  16. ^ Lock, Stephen; John M. Last; George Dunea (2001). The Oxford illustrated companion to medicine. Oxford University Press US. p. 173. ISBN 978-0-19-262950-0. Retrieved 9 July 2010. Rosen von Rosenstein.
  17. ^ Roberts, Michael (2003). The Age of Liberty: Sweden 1719–1772. Cambridge University Press. p. 216. ISBN 978-0-521-52707-1. Retrieved 9 July 2010.
  18. ^ Dallas, John. "Classics of Child Care". Royal College of Physicians of Edinburgh. Archived from the original on 27 July 2011. Retrieved 9 July 2010.
  19. ^ Duffin, Jacalyn (29 May 2010). History of Medicine, Second Edition: A Scandalously Short Introduction. University of Toronto Press.
  20. ^ Stern, Alexandra Minna; Markel, Howard (2002). Formative Years: Children's Health in the United States, 1880-2000. University of Michigan Press. pp. 23–24. doi:10.3998/mpub.17065. ISBN 978-0-472-02503-9. Archived from the original on 30 November 2021. Retrieved 30 November 2021.
  21. ^ "Broadribb's Introductory Pediatric Nursing". Nancy T. Hatfield (2007). p.4. ISBN 0-7817-7706-2
  22. ^ "Jacobi Medical Center - General Information". Archived from the original on 18 April 2006. Retrieved 6 April 2006.
  23. ^ Kutzsche, Stefan (8 April 2021). "Abraham Jacobi (1830–1919) and his transition from political to medical activist". Acta Paediatrica. 110 (8): 2303–2305. doi:10.1111/apa.15887. ISSN 0803-5253. PMID 33963612. S2CID 233998658. Archived from the original on 7 May 2023. Retrieved 7 May 2023.
  24. ^ a b Ballbriga, Angel (1991). "One century of pediatrics in Europe (section: development of pediatric hospitals in Europe)". In Nichols, Burford L.; et al. (eds.). History of Paediatrics 1850–1950. Nestlé Nutrition Workshop Series. Vol. 22. New York: Raven Press. pp. 6–8. ISBN 0-88167-695-0.
  25. ^ official history site (in French) of nineteenth century paediatric hospitals in Paris
  26. ^ "Introducing the Necker-Enfants Malades Hospital". Hôpital des Necker-Enfants Malades.
  27. ^ Young, D.G. (August 1999). "The Mason Brown Lecture: Scots and paediatric surgery". Journal of the Royal College of Surgeons Edinburgh. 44 (4): 211–5. PMID 10453141. Archived from the original on 14 July 2014.
  28. ^ Pearson, Howard A. (1991). "Pediatrics in the United States". In Nichols, Burford L.; et al. (eds.). History of Paediatrics 1850–1950. Nestlé Nutrition Workshop Series. Vol. 22. New York: Raven Press. pp. 55–63. ISBN 0-88167-695-0.
  29. ^ "Commentaries: Edwards A Park". Pediatrics. 44 (6). American Academy of Pediatrics: 897–901. 1969. doi:10.1542/peds.44.6.897. PMID 4903838. S2CID 43298798.
  30. ^ a b c d e f g h O'Hara, Kate (2016). "Paediatric pharmacokinetics and drug doses". Australian Prescriber. 39 (6): 208–210. doi:10.18773/austprescr.2016.071. ISSN 0312-8008. PMC 5155058. PMID 27990048.
  31. ^ a b c d e f g h i j k l m Wagner, Jonathan; Abdel-Rahman, Susan M. (2013). "Pediatric pharmacokinetics". Pediatrics in Review. 34 (6): 258–269. doi:10.1542/pir.34-6-258. ISSN 1526-3347. PMID 23729775.
  32. ^ a b c d e f Batchelor, Hannah Katharine; Marriott, John Francis (2015). "Paediatric pharmacokinetics: key considerations". British Journal of Clinical Pharmacology. 79 (3): 395–404. doi:10.1111/bcp.12267. ISSN 1365-2125. PMC 4345950. PMID 25855821.
  33. ^ Katz, Aviva L.; Webb, Sally A.; COMMITTEE ON BIOETHICS; Macauley, Robert C.; Mercurio, Mark R.; Moon, Margaret R.; Okun, Alexander L.; Opel, Douglas J.; Statter, Mindy B. (1 August 2016). "Informed Consent in Decision-Making in Pediatric Practice". Pediatrics. 138 (2): e20161485. doi:10.1542/peds.2016-1485. ISSN 0031-4005. PMID 27456510. S2CID 7951515.
  34. ^ a b Mazur, Kate A.; Berg, Stacey L., eds. (2020). Ethical Issues in Pediatric Hematology/Oncology. pp. 13–21. doi:10.1007/978-3-030-22684-8. ISBN 978-3-030-22683-1. S2CID 208302429.
  35. ^ a b Stern, Alexandra Minna; Markel, Howard (2002). Formative Years: Children's Health in the United States, 1880-2000. University of Michigan Press. pp. 23–24. doi:10.3998/mpub.17065. ISBN 978-0-472-02503-9. Archived from the original on 30 November 2021. Retrieved 30 November 2021.
  36. ^ Friedman, Lainie Ross (2004). Children, families, and health care decision making. Clarendon Press. ISBN 0-19-925154-1. OCLC 756393117.
  37. ^ a b c Martakis, K.; Schröder-Bäck, P.; Brand, H. (1 June 2018). "Developing child autonomy in pediatric healthcare: towards an ethical model". Archivos Argentinos de Pediatria. 116 (3): e401 – e408. doi:10.5546/aap.2018.eng.e401. ISSN 0325-0075. PMID 29756714. S2CID 46889502.
  38. ^ Schapiro, Tamar (1 July 1999). "What Is a Child?". Ethics. 109 (4): 715–738. doi:10.1086/233943. ISSN 0014-1704. S2CID 170129444. Archived from the original on 30 November 2021. Retrieved 30 November 2021.
  39. ^ Dondorp, W.; Bolt, I.; Tibben, A.; De Wert, G.; Van Summeren, M. (1 September 2021). "'We Should View Him as an Individual': The Role of the Child's Future Autonomy in Shared Decision-Making About Unsolicited Findings in Pediatric Exome Sequencing". Health Care Analysis. 29 (3): 249–261. doi:10.1007/s10728-020-00425-7. ISSN 1573-3394. PMID 33389383. S2CID 230112761.
  40. ^ "What Education Is Required to Be a Pediatrician?". Archived from the original on 7 June 2017. Retrieved 14 June 2017.
  41. ^ "CoPS". www.pedsubs.org. Archived from the original on 18 September 2013. Retrieved 14 August 2015.

Further reading

[edit]
  • BMC Pediatrics - open access
  • Clinical Pediatrics
  • Developmental Review - partial open access
  • JAMA Pediatrics
  • The Journal of Pediatrics - partial open access
[edit]
Wikimedia Commons has media related to Pediatrics.
 
Wikibooks has a book on the topic of: Pediatrics
 
Look up paediatrics or pediatrics in Wiktionary, the free dictionary.
  • Pediatrics Directory at Curlie
  • Pediatric Health Directory at OpenMD
 
 

 

Check our other pages :