Patent Grant
11925748
Not applicable.
Not applicable.
Not applicable.
The present disclosure relates to the field of mesh nebulizers, and more specifically to the field of mesh nebulizers for administering medications.
A mesh nebulizer, also known as a vibrating mesh nebulizer, is a type of device used to deliver medication in a fine mist or aerosol form, which makes it easier for patients to inhale the medication directly into their lungs. This is particularly useful for the treatment of respiratory diseases like asthma, COPD (chronic obstructive pulmonary disease), or cystic fibrosis. The “mesh” in the name refers to a key component of the nebulizer: a small plate with multiple tiny holes, or a “mesh”. This mesh vibrates at high frequencies, causing the liquid medication to be pushed through the tiny holes in the mesh, creating a fine mist or aerosol that can be inhaled. Mesh nebulizers are generally more efficient and portable than traditional jet nebulizers. They tend to be quiet, lightweight, and capable of nebulizing a wide range of medications. However, they can be more expensive, and the mesh plate can become blocked over time, requiring replacement. Proper cleaning and maintenance are important to keep the device functioning properly.
Inhalers are another form of medical devices that are used to deliver medication directly into the lungs. They are commonly used to treat conditions like asthma and chronic obstructive pulmonary disease (COPD). There are two main types of inhalers: metered-dose inhalers (MDIs) and dry powder inhalers (DPIs). MDIs use a chemical propellant to push the medication out of the inhaler. The user pushes down on the top of the inhaler and inhales at the same time to ensure the medication reaches the lungs. MDIs also can be used with a spacer, a tube-like device which provides a space for the medication to mix with air before reaching the lungs. This makes it easier for the medication to be inhaled and is especially helpful for children or people who have difficulty coordinating their breath with the release of the medication. DPIs do not use a chemical propellant. Instead, the medication is in a powder form, which the user inhales. Because they require a strong, quick inhalation to get the medication into the lungs, DPIs can be harder for some people to use than MDIs. Inhalers can deliver a variety of medications. However, the effectiveness of inhalers depends significantly on correct usage. Mistakes in technique can result in less medication reaching the lungs. These mistakes could include breathing too quickly or not deeply enough, not shaking the inhaler before use, or not using a spacer if needed. Some inhalers, especially newer or brand-name inhalers, can be quite expensive, potentially posing a financial burden.
Despite the various advancements in the field of medication delivery via capsules, there exist several challenges that continue to impact both patient compliance and the overall effectiveness of the treatment. One major challenge is the management of precise dosage control. In many instances, the ability to ensure a patient receives the exact dose of medication prescribed is crucial for the treatment's efficacy. However, it is a common problem that current capsule systems might not always deliver the accurate dose due to the limitations in the mechanism of action or variability in user technique. Further, many capsule systems for medication delivery require intricate instructions for use, which can lead to user errors. This is particularly relevant in instances where capsules need to be loaded into a device, such as an inhaler, where improper loading could result in suboptimal medication delivery. User-friendliness and ease of use are paramount in designing such systems, and any complexity can lead to misuse or non-compliance.
The potential for contamination is another issue that is often encountered in these systems. This can occur during the loading of the capsule into the delivery device or during the process of administering the medication itself. Both scenarios can compromise the sterility of the medication, leading to potential health risks. Another concern with these systems is the difficulty of integrating modern technologies such as sensors and connectivity features. The inclusion of these technologies could enhance the performance and functionality of the capsule systems by enabling real-time monitoring, improving dosage control, or allowing for personalized treatments. However, the integration of such features in a compact and user-friendly form remains a significant challenge. Regarding the specific use of medicine vials, while their adoption has provided a convenient way to store and administer liquid medication, issues arise in terms of potential wastage and the need for preservatives. Many vials are single-use to maintain sterility, but this can lead to medication wastage if the full vial content is not used. Additionally, the need for preservatives in multi-dose vials to prevent microbial contamination can lead to potential allergic reactions or side effects.
A common challenge observed in prior art pertaining to medication delivery via capsules revolves around the lack of interchangeability. A significant number of the pre-existing capsule systems are designed for a specific medication or a particular type of medication. This can be due to the unique physical or chemical properties of the medication, such as particle size in case of inhaled medication, or stability considerations for certain biologics. The lack of a standardized, universal system restricts the ability to switch between different medications using the same delivery device, limiting the versatility of the treatment options. Moreover, the ease of transportation is another aspect that remains wanting in many prior art capsule systems. Certain systems, particularly those requiring intricate loading or handling procedures, can prove cumbersome to transport, and potentially fragile. This is a critical consideration for patients who need to carry their medication for use throughout the day, or during travel. Ideally, medication delivery systems should be robust, compact, and portable, making them convenient for users to carry and use as required. Non-invasive administration of medication is an essential aspect of patient compliance and comfort. In the prior art, many delivery systems, particularly for certain conditions, might require invasive procedures such as injections, which can cause discomfort or distress to patients. These methods also raise potential issues of sterility and can increase the risk of infection. Therefore, there is a persistent need for delivery systems that can efficiently administer medication in a non-invasive manner, such as inhalation or oral administration, without compromising on the medication's efficacy.
The problems with medication delivery do not only exist in the context of human medicine; rather, similar problems and further complications exist in the practice of veterinary medicine. Administering medication to animals is a complex task routinely undertaken by veterinary professionals in both clinical settings and in the field. Oral administration, though often straightforward, can be fraught with challenges as animals may refuse or only partially consume the dose, leading to stress or injury.
Injections, while allowing more control over dosing, require restraint, which can also lead to stress or harm. Intravenous injections, in particular, demand careful placement and maintenance of an IV line, posing difficulties with restless or uncooperative animals. Inhalation, a non-invasive option, requires specialized equipment and can be less effective in delivering precise dosages, with the fitting of masks or apparatus potentially causing stress. Intubation, effective for delivering medication directly to the respiratory system or providing ventilatory support, carries risks such as misplacement of the tube, aspiration, physical trauma, and stress to the animal.
Topical methods, used for various treatments, can be problematic if the animal removes the medication by licking or scratching and may lack precision in dosage. Field administration adds complexities due to the lack of specialized equipment, environmental factors, and the behavior of free-ranging or non-domesticated animals. Different species require different approaches, demanding a broad knowledge base from veterinary professionals, and a variety of equipment and medications. Costs associated with specialized tools, medications, and training can be prohibitive, especially in rural or underserved areas. Furthermore, the ethical need to balance effective treatment with the welfare and comfort of the animal is a constant consideration in veterinary medicine. Whether in a clinic or the field, the current practices of administering medication to animals present a diverse and multifaceted landscape, fraught with challenges and limitations.
The issues of administering medication to animals are further complicated by variations in size, breed, age, and temperament. Managing the unique anatomical and physiological differences among diverse animal species can result in an even greater demand for specialized equipment and expertise. For instance, administering medication to a small, delicate bird requires vastly different techniques and tools than treating a large mammal such as a horse or cow. The difficulty in accurately gauging an animal's response to pain or discomfort further complicates the process, as noticeable signs may be subtle or entirely absent. This can lead to challenges in both diagnosing the need for medication and monitoring its effects.
In the field, the challenges can be amplified due to unpredictable environmental conditions, such as weather, noise, and other animals. The need to provide care swiftly in emergencies may necessitate improvisation with available resources, leading to less-than-optimal treatment. Managing chronic conditions in the field, such as ongoing pain management or treatment of chronic illnesses, may be further complicated by the lack of regular access to the animal and adherence to a medication regimen.
Additionally, the problems of resistance to antibiotics and other medications add another layer of complexity to veterinary care. Incorrect dosing, partial treatment, or use of inappropriate medications may lead to resistance, reducing the efficacy of those treatments over time. The consequence of such resistance can ripple through an ecosystem, affecting not only the individual animal but potentially impacting entire populations. Furthermore, regulations regarding the use of certain medications, particularly controlled substances, create legal and practical challenges. Compliance with laws and guidelines requires detailed record-keeping and adherence to specific procedures, adding time and complexity to an already demanding process.
The inherent limitations in prior art related to interchangeability, transportability, and non-invasive administration pose significant barriers to optimal patient care. The need for more adaptable, easily transportable, and less invasive delivery systems persists, driving the continuous pursuit for innovation in this field. As a result, there exists a need for improvements over the prior art and more particularly for improved, user-friendly, and reliable capsule systems that can provide accurate dosing, maintain sterility, and integrate modem technologies for enhanced monitoring and control.
An apparatus, method, and system for administering at least one medication to a patient is disclosed. This Summary is provided to introduce a selection of disclosed concepts in a simplified form that are further described below in the Detailed Description including the drawings provided. This Summary is not intended to identify key features or essential features of the claimed subject matter. Nor is this Summary intended to be used to limit the claimed subject matter's scope.
In one embodiment, a method of administering at least one medication to a patient into the patient's mouth is disclosed. The method includes dispensing, using an atomizer, the at least one medication from a capsule in fluid communication with a tubular chamber, into the tubular chamber; and causing, air within a resilient air bladder in fluid communication with the tubular chamber to be conveyed from the resilient air bladder and into the tubular chamber such that the air conveyed from the resilient air bladder and the at least one medication dispensed from the capsule is administered to the patient. The method also includes, prior to dispensing the at least one medication from the capsule, disposing device on the patient's face and or a mouthpiece defining a tubular shaped body to be inserted into the patient's mouth. The device includes a mask defining a mask chamber within the mask that is surrounded by a rim on the periphery of the mask. The mask is to be positioned over the patient's mouth and nose, and by applying force with a hand of a rescuer to the mask to obtain a substantially air-tight seal against the patient's face. While applying the force with the hand of the rescuer to the mask, engaging with a second hand of the rescuer, a user interface on the device to cause the atomizer to atomize and to dispense the at least one medication from the capsule. While applying the force to the mask with the hand of the rescuer, and either during or after engaging with the user interface to cause the dispensing of the at least one medication from the capsule, the method further includes applying a second force with the second hand of the rescuer, to the resilient air bladder so that the air within the resilient air bladder is conveyed from the resilient air bladder and into the tubular chamber such that the air conveyed from the resilient air bladder and the at least one medication dispensed from the capsule is administered to the patient. One inventive aspect of this device is that only a single rescuer may be needed to easily administer medication to a patient.
Prior to dispensing the at least one medication from the capsule, the method further includes receiving, with a processor, a signal to start the atomizer to atomize the at least one medication, determining, using the processor based on the signal, a maximum volume of the at least one medication to atomize and/or a maximum amount of time to atomize the at least one medication. Next, the process sends, to the atomizer, a signal to cause the atomizer to atomize the maximum volume of the at least one medication and/or the at least one medication for the maximum amount of time. After the maximum volume or time has been attained, the process the receives, a third signal from a sensor that monitors an atomized volume of the at least one medication within the capsule or a first amount of time the atomizer atomizes the at least one medication. The signal is received from at least one of a remote computing device and the capsule. The method includes, after the processor determines that the atomized volume is at least as much as the maximum volume based on the third signal received and/or the first amount of time is at least as much as the maximum amount of time, then stopping the atomizer from continuing to atomize the at least one medication within the capsule. The processor is configured to send a fourth signal to stop the atomizer from continuing to atomize the at least one medication within the capsule after the processor determines that the atomized volume is at least as much as the maximum volume based on the third signal received.
In another embodiment, a system for administering at least one medication to a patient is disclosed. The system includes a resilient air bladder in fluid communication with a tubular chamber of a base unit, a capsule in fluid communication with the tubular chamber configured for carrying the at least one medication, and an atomizer disposed at least proximate to the capsule and in fluid communication with the tubular chamber. The atomizer is configured to atomize the at least one medication that is disposed within the capsule. The system further includes an air inlet and a first one-way valve in fluid communication with the resilient air bladder configured to allow fresh air to enter the resilient air bladder. The system includes an air outlet and a second one-way value in fluid communication the resilient air bladder and the tubular chamber. Fresh air is drawn into the resilient air bladder when it inflates.
Fresh air is forced through the second one-way valve and to the tubular chamber when the resilient air bladder deflates. Fresh air and the at least one medication atomized by the atomizer to mix together within the tubular chamber. The system further includes a mask defining a mask chamber within the mask. The mask is positioned over the patient's mouth and nose, a rim extending about a periphery of the mask to form a seal with the patient's face. In another embodiment, the system may include a mouthpiece defining a tubular shaped body. The capsule includes a capsule chamber for housing the at least one medication, a rubber section covering an open side of the capsule, the atomizer proximate to a second side of the capsule, and a sensor for detecting an amount of the at least one medication in the capsule.
In one embodiment, the mask attachment for the described capsule system is a specially designed piece that can be retrofit, sized, and shaped to substantially cover an animal's nose and/or mouth. Serving as the interface between the device and the animal, it facilitates the delivery of atomized medication. This mask attachment works in conjunction with the capsule system to direct the atomized medication to the desired area of the animal's respiratory system. By being adjustable in size and shape, it ensures that the mask can effectively conform to various animal anatomies, creating a seal that optimizes medication delivery. The mask attachment may be made of medical-grade silicone, rubber, or other flexible and non-reactive materials, allowing for easy cleaning, sterilization, and customization to different sizes and shapes. The customizability and retrofitting ability of the mask attachment represent a significant advancement over previous designs, overcoming prior limitations by providing more effective, comfortable, and controlled administration of atomized medication, thus offering more versatile and humane treatment options for animals in a medical setting.
The system further includes a housing and a first channel spanning from a first side of the housing to a second side of the housing. The system further includes a first longitudinal axis of the first channel, a first end portion of the first channel configured to receive a portion of a conduit that is in fluid communication with the air outlet of the resilient air bladder, and a second end portion of the first channel configured to receive a portion of either the mouthpiece or the mask. The system further includes a second channel disposed on the housing configured to receive a portion of the capsule and a second longitudinal axis defined by the second channel. The second longitudinal axis defines at most a 90-degree angle relative to the first longitudinal axis of the first channel. However, other angles, such as a 45-degree angle may be used and is within the spirit and scope of the present invention.
The system further includes a processor housed by the housing. The housing houses the user interface housed by the housing. The user interface is configured to be acted on by a rescuer to start the atomizer to atomize the at least one medication. The user interface, may include control for being manipulated by the hands of a user, a graphical display, an audio sensor for receiving audio signals from the user to control the device. The processor is configured for receiving a signal to start the atomizer to atomize the at least one medication, sending a second signal to the atomizer to cause the atomizer to atomize the at least one medication within the capsule and convey the atomized at least one medication into the second channel, receiving a third signal from the sensor when the sensor detects that the at least one medication within the capsule is less than a minimum threshold, and sending a fourth signal to turn off the atomizer after the third signal is received.
In another embodiment, a method for administering at least one medication to a patient when the patient is unconscious and when the patient is consciousness is disclosed. The method includes inserting a capsule containing the at least one medication into a device in fluid communication with a tubular chamber, wherein the at least one medication is a liquid formulation. The method further includes activating an atomizer to atomize the at least one medication to generate at least one atomized medication comprising a plurality of particles, wherein each particle of said plurality of particles is at most four microns in diameter. The method further includes dispensing the at least one atomized medication from the capsule in fluid communication with the tubular chamber, into the tubular chamber and administering the at least one atomized medication to the patient using the device. If the patient is unconsciousness, then administering the at least one atomized medication comprises at least partially deflating a resilient air bladder in fluid communication with the tubular chamber causing air within the resilient air bladder to be conveyed from the resilient air bladder into the tubular chamber. Prior to administering the at least one atomized medication to the patient using the device, the method includes applying a force to a mask, positioned over the patient's nose and the patient's mouth and in fluid communication with the tubular chamber. The resilient air bladder is removable.
The method further includes removing the resilient air bladder from a receiving section and attaching a cap to cover an opening of the receiving section. If the patient is consciousness, then the method includes administering the at least one atomized medication to the patient using the device comprises conveying the at least one atomized medication from the tubular chamber though at least one of a mouthpiece that is in fluid communication with the tubular chamber and a mask, positioned over the patient's nose and the patient's mouth and in fluid communication with the tubular chamber. The capsule includes a first chamber comprising the liquid formulation, a second chamber below and separate from the first chamber, and the atomizer disposed at least proximate to a portion of the second chamber that is distal to the first chamber. The method further includes causing the liquid formulation to move from the first chamber to the second chamber. Prior to causing the liquid formulation to move from the first chamber to the second chamber, the method further includes removing a stop on the capsule that inhibits the first chamber from translating relative to the second chamber. After removing the stop of the capsule, the method includes applying a second force to the first chamber causing the first chamber to translate relative to the second chamber rupturing a membrane disposed between the first chamber and the second chamber thus providing fluid communication between the first chamber and the second chamber. Prior to activating the atomizer, the method includes providing power to the atomizer by removing an insulator that prevents electrical communication between the atomizer and a power source. The method further includes conveying the at least one atomized medication through a second tubular chamber that is disposed between the patient's face and the tubular chamber thereby causing the at least one atomized medication to form a substantially stable and uniform aerosol. The at least one medication comprises a narcotic antagonist.
If the patient is in an intubated state, the method further includes removing the resilient air bladder from a receiving section of the device, attaching a conduit in fluid communication with a ventilator air outlet to the receiving section. and attaching an endotracheal tube to the device so that endotracheal tube is in fluid communication with the tubular chamber and the conduit. The receiving section is a first end portion of a first channel of the device configured to receive a portion of a conduit that is in fluid communication with an air outlet of the resilient air bladder. The tubular chamber is a removable modular tubular extension including a first extension tubular chamber and a second extension tubular chamber. The first extension tubular chamber includes a first extension receiving section and a second extension chamber receiving section and defines the first channel. The second extension tubular chamber is substantially in fluid communication with the first extension tubular chamber. The method further includes inserting the second extension tubular chamber into a device receiving section such that the second extension tubular chamber is in fluid communication with the second channel of the device and such that the second extension tubular chamber defines at least a portion of the second channel. The tubular chamber of the device comprises a first channel having a first end portion, a second end portion, and a first longitudinal axis.
The second extension tubular chamber includes a first portion substantially perpendicular to the first extension tubular chamber and a second portion disposed at a first angle relative to a longitudinal axis of the first portion and which corresponds to the first longitudinal axis of the first channel. An angle between the first extension tubular chamber and the second extension tubular chamber is adjustable. The method further includes adjusting the angle between the first extension tubular chamber and the second extension tubular chamber to a predetermined angle and locking the angle between the first extension tubular chamber and the second extension tubular chamber at the predetermined angle. The method includes linking the capsule to the device such that the capsule further includes a transponder. The method includes administering the at least one atomized medication to the patient using the device further includes the at least one atomized medication breaking the patient's blood brain barrier.
In another embodiment, a capsule system for use with a medical device for administering at least one atomized medication to a patient is disclosed. The capsule system comprises at least one chamber, at least one medication disposed within the at least one chamber, and an atomizer at a lower end portion of the capsule system. The capsule system further includes at least one electrical contact and at least one sensor. The at least one sensor is a fluid sensor. The at least one electrical contact is in electrical communication with a power source.
The capsule system also comprises a housing that substantially encloses the at least one chamber, the housing comprising an asymmetrical transverse cross-sectional shape. The atomizer is disposed proximate to a bottom portion of the at least one chamber. The at least one chamber comprises at least one tapered wall section to direct the at least one medication toward the atomizer. The capsule system further includes a stopper in fluid communication with the at least one chamber.
The capsule system further comprises an electrical conductor connecting the capsule to the medical device such that the capsule comprises a port. The medical device comprises at least one of a display, a processor, and a power source. The capsule comprises a capsule width and the at least one chamber comprises a chamber width such that the chamber width substantially spans the capsule width. The at least one chamber is in fluid communication with an external container via an elongated tube, the external container having the at least one medication.
The capsule comprises a plug disposed at the lower end portion of the capsule system. The at least one chamber comprises a first chamber disposed above a second chamber; wherein the first chamber comprises the at least one medication and the second chamber comprises the atomizer. A membrane preventing fluid communication is disposed between the first chamber from the second chamber. A stop is disposed between the first chamber and the second chamber inhibiting the first chamber from translating relative to the second chamber. At least one rupturing element is in attachment with the first chamber configured to engage the membrane when a first force is applied to translate the first chamber relative to the second chamber.
Additional aspects of the disclosed embodiment will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the disclosed embodiments. The aspects of the disclosed embodiments will be realized and attained by means of the elements and combinations particularly pointed out in the appended claims. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosed embodiments, as claimed.
The accompanying drawings, which are incorporated in and constitute part of this specification, illustrate embodiments of the disclosure and together with the description, explain the principles of the disclosed embodiments. The embodiments illustrated herein are presently preferred, it being understood, however, that the disclosure is not limited to the precise arrangements and instrumentalities shown, wherein:
Like reference numerals refer to like parts throughout the various views of the drawings.
The following detailed description refers to the accompanying drawings. Whenever possible, the same reference numbers are used in the drawings and the following description to refer to the same or similar elements. While disclosed embodiments may be described, modifications, adaptations, and other implementations are possible. For example, substitutions, additions, or modifications may be made to the elements illustrated in the drawings, and the methods described herein may be modified by substituting reordering or adding additional stages or components to the disclosed methods and devices. Accordingly, the following detailed description does not limit the disclosed embodiments. Instead, the proper scope of the disclosed embodiments is defined by the appended claims.
The disclosed embodiments improve upon the problems with the prior art by providing an apparatus, system, and method that allows for controlled and measured doses of medication that need to be administered to a patient via inhalation, such as in the treatment of respiratory conditions or overdoses. The method allows for precise administration of the medication because it ensures the system administers the medication in the capsule depending on the needs of certain medical situations. The system includes modular components such that the apparatus can be utilized in different scenarios. For example, depending on the type of modular cardiopulmonary device, the system may be used on a patient that is laying down, positioned upright, conscious, or unconscious. The system may allow a patient to treat themselves or may require an authorized user to treat the patient using the system. The system is configured to only require one rescuer having two hands to operate the system.
Additionally, the system is more convenient than the prior art because the attachment for the modular cardiopulmonary device includes integrated medication monitoring and an adjustably automated dispensing of medication. The attachment also allows for more adaptability and portability because it has modular fittings that can allow for attachment with commonly used cardiopulmonary devices, such as resuscitation bags and breathing masks.
The system also improves over the prior art because the medication is held in capsules that includes an atomizer that abuts the medication. Gravity forces the medication to be pressed against the medication to allow for efficient atomization. The capsule is compatible with the attachment because both include electrical contacts that, when paired up, provide electrical communication between the capsule and the attachment.
The disclosed system and methods described herein represents a significant improvement over prior art by incorporating a sophisticated capsule system for administering atomized medication. Specifically, the system comprises at least one chamber housing the medication, an atomizer to convert the medication into a fine mist, and various additional components such as sensors and electrical contacts. This design allows for a more controlled and precise delivery of medication, enabling targeted treatment with reduced risk of overdose or underdose.
The operation of the system within the context of veterinary practice is highly beneficial. The atomized medication can be administered with less physical contact, reducing stress for both the animal and the administering veterinary professional. The modular nature of the system provides flexibility in adjusting to the needs of different species and sizes of animals, and the precise control over medication dosage contributes to better therapeutic outcomes. The addition of features like sensors and asymmetrical transverse cross-sectional shapes enhances usability and efficiency in various animal care scenarios.
The materials and construction of the invention, as disclosed, have been designed with veterinary applications in mind. The system's adaptability to different forms of medications, its compatibility with various animal anatomies, and its potential integration with existing veterinary equipment make it a versatile tool in animal healthcare. The innovation thus offers not only improvements in the effectiveness and safety of medication administration but also potential cost savings and efficiency enhancements in veterinary practice.
In the general practice of medicine for humans, the disclosed invention offers significant improvements over prior art, particularly addressing concerns around modularity, interchangeability, and speed in administration. Modularity enables customization of medical devices to suit individual patient needs and particular medical conditions, allowing for a more targeted and efficient approach. With the invention's design, various components can be added or removed with ease, thereby adapting the device to different scenarios and patient requirements. The interchangeability feature ensures that parts can be substituted without compromising the integrity or functionality of the device, thus increasing its utility and flexibility. This adaptability not only reduces costs by allowing components to be reused across different applications but also facilitates quick adjustments in emergency situations. Finally, the invention's design emphasizes rapid administration of medication, significantly reducing the time required to prepare and deliver treatments. This is particularly crucial in critical care situations, where every second can make a difference in patient outcomes. By addressing these key areas, the invention enhances the efficiency, adaptability, and responsiveness of medical treatment, setting a new standard in patient care.
Referring now to the Figures,
The base unit is the attachment 106 that including receiving sections 107 and 109 that provides modular fittings such that commonly used medical components, such as medical face masks or medical mouthpieces, and modular cardiopulmonary devices may be attached. The base unit may also be described herein as a device or medical device. Each of the receiving sections includes an opening into the first channel. The first channel may have a cross-sectional shape defining a circle, but other shapes may be used and are within the spirit and scope of the present invention and as such the openings of the receiving sections 107 and 109 may also be a circular shaped opening. The attachment is configured for connecting to a modular cardiopulmonary device. The modular cardiopulmonary device is defined by the resilient air bladder and at least a mask 142 or mouthpiece (205 in
A capsule 108 is in fluid communication with the tubular chamber and is configured for carrying the medication. In some embodiments, the capsule may include a sensor (220 in
The atomizer produces particles that are atomized droplets of the medication. Particles that are larger than 5 micrometers are unable to penetrate into the alveoli of the lungs and are thus of reduced efficiency in being rapidly absorbed by the circulatory system and/or body tissues. The ability of particles to penetrate into the lungs and be absorbed by the depends on the size of the particles. Inhalable particles, ranging in size from 1.5 micrometers to about 6 micrometers, penetrate into the lungs as far as the bronchi because the cilia of the lungs filter the inhalable particles from further travel into the lung volume. Particles ranging in size from 1.5 micrometers to about 5 micrometers are able to penetrate into the alveoli in the lungs and are readily absorbed through the alveoli into the circulatory system and body tissues.
The medication in the capsule is a fluid solution configured to treat patients for different situations. The solution includes an aqueous solution that includes an active ingredient and sodium chloride. When atomized by the atomizer in the capsule, the atomized medication is configured to break a patient's blood brain barrier. The active ingredient includes at least one of nicotine, caffeine, a plurality of vitamins, kratom, Vitamin B12, cotinine, adalimumab, cannabidiol (“CBD”), tetrahydrocannabinol (“THC”), psilocybin, cannabis, ketamine and any combination thereof. The active ingredient may also include exosomes, analgesics, antifungals, Benzodiazepines, Antiarrhythmic agents, anti-aging agents, rapamycin, metformin, calcium channel blockers, antibiotics, anti-inflammatory, anti-gout, alpha-beta-adrenergic agonists, Nitroglycerin, adrenergic bronchodilators, cardiovascular agents, central nervous system stimulants and/or depressants, diabetic agents, diuretics, immunologic agents, gastrointestinal agents, common biologics like Humira, Lantus, Remicade, Enbrel, vaccines, psychotherapeutic agents, opiate partial antagonists, opioids, pulmonary agents, hormonal agents, weight loss agents, vitamins/minerals/supplements, Antihyperlipidemics, PCSK9 Inhibitors, Evolocumab, Alirocumab, Inclisiran, Diuretics, Furosemide, Bumetanide, Torsemide, Beta-2 Adrenergic Agonists, Salmeterol, Long-Acting Beta Agonist, Vilanterol, Formoterol, Anticholinergics, Umeclidinium, Glycopyrrolate, Corticosteroid: Budesonide, Fluticasone, Bronchodilators, Tiotropium, Over-active Bladder Medications, Anticholinergics, Ditropan (oxybutynin), Tolterodine, Darifenacin, Muscarinic Antagonists, narcotic antagonists, Trospium, Fesoterodine, Migraine Therapyies, CGRP Receptor Blockers (gepants and monoclonal antibodies ((mAb)), Ubrelvy, Triptans, Ergots, Antiemetics, antagonists of the serotonin, histamine, muscarinic and neurokinin systems, Selective Serotonin 5-HT3 Antagonists, Zofran (ondansetron), Diabetic and Weight loss agents, GLP-1, Semaglutide, GIP+GLP-1, Mounjaro™ (Tirzepatide), Anticonvulsants, Pulmonary medications, Hormones, Biologics, Regenerative Drugs, all essential drugs and medicine as defined by World Health Organization, vitamins, caffeine and energy medications, all emergency medicine medications, integrative therapeutics, peptides, ozone, o2, white curcumin, exosomes, gene therapy vectors, erectile dysfunction medications, such as sildenafil citrate, tadalafil, Cialis®, Viagra®, future classes of therapeutics, Yohimbine, and Haloperidol. The active ingredient may also include preservatives, such as Sodium benzoate, and/or anti-yeast agents, such as potassium sorbate. Other preservatives for medication may be used and are within the spirit and scope of the present invention.
The solution further includes a buffer and/or stabilizer. The buffer helps stabilize and maintain the pH level of the solution. The active ingredient includes approximately up to 10% of the solution. Sodium chloride includes approximately between 10% to 90% of the solution. The buffer includes approximately between 1% to 5% of the total solution. The solution has a pH of approximately between 4 pH and 7.5 pH. The pH range is critical to decrease the effects that the active ingredient may have on the body when inhaled, e.g., an increased amount of acute toxicity which may be present in unprotonated active ingredients above a certain pH.
In a first example solution, the solution is for at least decreasing withdrawal symptoms of a person addicted to nicotine. Said solution includes cotinine being the active ingredient in the solution including approximately between 0.5% and 8% of the solution and a sugar alcohol including approximately between 0.5% to 3% of the solution. The solution further includes a buffer including ethyl alcohol and citric acid. The ethyl alcohol includes approximately between 0.1% to 3% of the solution, and the citric acid comprising approximately between 0.1% to 3% of the solution. Cotinine helps reduce symptoms of nicotine withdrawal. The sugar alcohol and citric acid act as sweeteners to counter the bitterness of cotinine when inhaled. In another embodiment, the solution of the first embodiment may be mixed with a small dose of nicotine.
In a second example solution, the solution is a pulmonary irrigation solution. The solution includes adalimumab being the active ingredient including approximately between 1% to 10% of the solution and a sugar alcohol including approximately between 0.1% to 1% of the solution. Adalimumab helps treat a variety of diseases by fighting infections or bacteria within the lungs. The solution further includes a stabilizer including polyol including approximately between 0.1% to 5% of the solution and surfactant comprising approximately between 0.1% to 5% of the solution. The solution may also include at least one of preservative (at 0.1% of the solution) and anti-mold and anti-yeast agent at (0.1% of the solution), The polyol is at least one of sucrose, histidine, and succinate. The surfactant is polyetherimide. At least one of the buffer and the stabilizer includes at least one buffer selected from the group consisting of histidine, succinate, phosphate, citrate, acetate, sodium bicarbonate, maleate, and tartrate buffers. The buffer does not include a combination of a citrate buffer and a phosphate buffer. This solution is intended for use in the induction of sputum production where sputum production is indicated, such as with Rheumatoid Arthritis, Ankylosing Spondylitis, ulcerative Colitis, Psoriasis, Psoriatic Arthritis, Cystic Fibrosis patients and Bronchoalveolar lavage procedures.
In a third example solution, the active ingredient is naloxone, also known as NARCAN®. Naloxone rapidly counters and/or reverses the effects of opioids. Naloxone is the standard treatment to counter opioid overdoses. Inhalation of naloxone through a portable AVI could quickly save the life of opioid users who overdose.
In a fourth example solution, the active ingredient is colloidal silver. Colloidal silver is a liquid solution including a plurality of silver particles. Colloidal silver treatment can heal a variety of infections, such as the common cold or respiratory infections.
In a fifth example solution, the active ingredient is glucagon. Glucagon is a hormone that raises blood glucose levels and the concentration of fatty acids in the bloodstream. Glucagon treatment helps people who suffer from hypoglycemia. Hypoglycemia occurs when the blood glucose levels are lower than the standard range.
An air inlet 112 and a first one-way valve 114 is in fluid communication with the resilient air bladder configured to allow fresh air to enter the resilient air bladder. The air inlet incudes an opening on which first one-way valve 114 is mounted. An air outlet 116 and a second one-way value 118 is in fluid communication the resilient air bladder and the tubular chamber. The first one-way valve 114 allows fresh air outside the bladder to move into the air bladder through that valve and prevents air from moving out of the first one-way valve 114 when the first one-way valve moves between the deflated state to the fully inflated state.
Fresh air is forced in direction A1 through the second one-way valve and to the tubular chamber when the resilient air bladder deflates. The second one-way valve may be a check valve. The air bladder deflates when opposing forces in directions H2 and I2 are applied via squeezing the air bladder. When the resilient air bladder deflates, fresh air is expelled out of the air outlet 116 in direction A1, and the first one-way valve 114 prevents air from being pushed out from the resilient air bladder through the air inlet. Because the resilient air bladder must return to its original shape, the air bladder automatically inflates in directions H1 and I1 when the forces stop squeezing it. Shown in
In one embodiment, the medical device is equipped with at least one sensor 132 (also shown in
For instance, pressure sensors may be used within the chambers to ensure that the fluid, such as a medication, is at the appropriate pressure for atomization. Additionally, the device may include sensors designed to measure fluid parameters, including the oxygen (O2) and carbon dioxide (CO2) content during inhalation and exhalation. These may encompass specific gas sensors like oxygen sensors, used to measure O2 content, and nondispersive infrared (NDIR) sensors for CO2 content. Such a configuration allows the device to adapt to the patient's respiratory needs and tailor the delivery of the medication, thereby optimizing treatment efficacy and patient comfort. These enhancements in sensor technology contribute to a more personalized and efficient means of administering medication compared to conventional methods.
These sensors can measure the viscosity, indicating the flow characteristics, and density, which helps in calculating the exact concentration of medication. The pH level of the fluid can be monitored to ensure its compatibility with the patient's needs. Electrical conductivity provides insights into the fluid's composition and purity, while turbidity sensors assess the clarity and potential contamination. The salt concentration or salinity is measured for certain medication types, and dissolved gases such as oxygen or nitrogen are monitored to ensure proper formulation. The particle size and distribution within the fluid are measured for determining how the medication may be absorbed by the body. Standard measurements of temperature and pressure are also undertaken, given their direct impact on fluid behavior, and thus the delivery and effectiveness of the medication.
For example, at least one of the sensors may be used to measure O2 inhaled by the patient and the CO2 exhaled by the patient over a period of time. Additionally, the data measured may be used to establish a metabolic signature or profile of the patient over time that can be used to create a baseline metabolic profile of the patient. The metabolic signature may be used to compare a with a second metabolic signature of the patient at a second period of time for the same patient or for other patients. In certain embodiments the second metabolic profile may be taken from different patients with certain known conditions, such as COVID, influenza, tuberculosis, heart disease. However, other conditions may be used to create the second metabolic profile for which is to be compared with other metabolic signatures of the patient taken over other periods of time. The periods of time, we be longer periods so that certain patterns and anomalies may be identified.
When the device is used with a resilient air bladder 102 to manually control the inhalation and exhalation of the patient, the sensors may be used for monitoring and regulating the pressure within the air bladder, assessing the flow rate of the inhalation and exhalation, detecting any abnormalities in the respiratory pattern, and ensuring that the prescribed dosage of atomized medication is delivered in synchronization with the patient's breathing cycle. Additionally, the sensors can provide feedback on various fluid parameters such as oxygen content, carbon dioxide content, and humidity, thus enhancing the efficiency and safety of the delivery system, and allowing for timely adjustments to the medication delivery or respiratory support as required by the patient's condition.
The base unit further includes a housing 120 and a first channel 122 spanning from a first side 124 of the housing to a second side 126 of the housing. The housing may be comprised of metallic material such as carbon steel, stainless steel, aluminum, Titanium, other metals or alloys, composites, ceramics, polymeric materials such as polycarbonates, such as Acrylonitrile butadiene styrene (ABS plastic), Lexan™, and Makrolon™. other materials having waterproof type properties. The housing may be made of other materials and is within the spirit and the disclosure. The housing may be formed from a single piece or from several individual pieces joined or coupled together. The components of the housing may be manufactured from a variety of different processes including an extrusion process, a mold, casting, welding, shearing, punching, folding, 3D printing, CNC machining, etc. However, other types of processes may also be used and are within the spirit and scope of the present invention.
The system further includes a first longitudinal axis 128 of the first channel. A first end portion 130 of the first channel is configured to receive a portion of a conduit 132 that is in fluid communication with the air outlet of the resilient air bladder, and a second end portion 134 of the first channel configured to receive a portion of the mouthpiece or the mask 142. The first end portion and second end portion include openings configured to receive the conduit and mask, respectively. The channel may have walls that have smooth surfaces so that air and medication may easily move toward the user or provide a path for air and medication to be in fluid communication with the mouthpiece of the mask. The system further includes a second channel 138 disposed on the housing configured to receive a portion of the capsule 108 and a second longitudinal axis 140 defined by the second channel. In one embodiment, the second channel may be circular in shape, however other shapes may be used and are within the spirit and scope of the present invention. The base unit includes an opening 141 of the second channel that receives a portion of the capsule. The second longitudinal axis defines at most a 90-degree angle relative to the first longitudinal axis of the first channel. In the present embodiment, the angle 143 between the second longitudinal axis and first longitudinal axis is at a 45 degree angle. However, other angles that allow the medication to easily flow into the second channel may be used and are within the spirit and scope of the present invention.
The fresh air then moves through tubular chamber in direction B while the atomized medication moves through base unit in direction C such that the fresh air and the medication atomized by the atomizer mix together within the tubular chamber to create a mixture 170. The system further includes a mask 142 defining a mask chamber 144 within the mask. The mask is configured to be positioned over the patient's mouth and nose. The mask has a rim 146 extending about a periphery of the mask for forming a seal with the patient's face and a mouthpiece defining a tubular shaped body. The mixture 170 of the fresh air and the atomized medication flows towards the mask in direction D.
The system further includes a processor 148 housed by the housing of the base unit. Two electrical contacts 152 are positioned within the second channel. The capsule also includes two electrical contacts (shown in
The base unit may also include a sensor 156 that detects whether a capsule is inserted into the second channel or not. The housing also houses a user interface 150. The user interface is configured to be acted on by a rescuer to start the atomizer to atomize the medication. The user interface may include controls to set or adjust the rate of medication to administer, to start or stop the atomizer, and/or to gain authorization to the base unit. The user interface may also include a graphical display configured to receive gestures such as touches, swipes, etc. to control the device. The user interface may also be controlled by receiving sound commands that are received by an audio sensor and then processed by the processor. The processor is configured for receiving a signal to start the atomizer to atomize the medication, sending a second signal to the atomizer to cause the atomizer to atomize the medication within the capsule and convey the atomized medication into the second channel, receiving a third signal from the sensor when the sensor detects that the medication within the capsule is less than a minimum threshold, and sending a fourth signal to turn off the atomizer after the third signal is received. For example, the minimum threshold may be an amount of fluid that is left in the container is less than 1/12 the total of medication in the capsule. For example, the sensor may detect that minimum threshold amount of medication is within the capsule, send the signal to the processer, then the processer may send a signal to stop the atomizer.
In some embodiments, the system may include a storage case such as, but not limited to, a briefcase. The storage may be able to hold multiple attachments, or base unit(s) 106, that can be charged by a power source within the storage case. The briefcase may require security measures to be unlocked. For example, unique codes or a fingerprint scanner may be used as a security measure. The storage case may include slots to hold a capsule that may be prefilled or non-prefilled with medication. The storage case would be very useful in medical emergencies.
Referring now to
The system 200 also includes electrical contacts 152 exposed on the inner surface of the second channel 138 that pair with electrical contacts 215 exposed on the outer surface of the capsule. When electrical contacts 152 and 215 are touching each other, the sensor 156 sends a signal to the processor 148, which sends a signal to turn on the power source 154. The power source then provides electrical power to the capsule 108 such that the atomizer begins atomizing the medication if there is electrical communication between contacts 152 and 215. The main difference between the first embodiment and the second embodiment is that they have different medical components (mask vs. mouthpiece) in attachment with the receiving sections 107 and 109 of the base unit. The system also includes an interface 150 on the second side of the base unit and is configured to allow the user to send signals to the processor to control the atomizer. The second embodiment allows a rescuer, medical professional, or in certain cases the patient to use the system on a patient that is positioned upright and is conscious, unlike the first embodiment, wherein the patient is laying down and may be unconscious. Upright means that the patient's body is substantially vertical so the patient's head 160 is substantially vertical.
Referring now to
As shown in
It is understood that the device may include at least one sensor, or a plurality of sensors, consistent with this disclosure. These sensors may be implemented in various locations and configurations within the device to monitor and measure vital parameters, fluid dynamics, and operational states, thereby contributing to the precise control and safety of the medication administration. While specific examples of sensor types and their applications have been described, these are not meant to be limiting. The incorporation of sensors within the device can be adapted to suit various needs and may extend beyond the examples provided herein. Such variations and adaptations are contemplated to be within the spirit and scope of the present invention, highlighting the flexibility and comprehensiveness of the system's design in catering to a wide range of requirements and scenarios in administering medication to patients.
Referring back to
A patient can push down or apply a force on the engaging element in direction E such that the engaging element moves towards the housing. When force in of line E is applied to overcome the expansion force of the spring, the engaging element 310 moves toward the housing to a certain extent so that the electrical contacts 312 of the housing and the electrical contacts 315 of the capsule contact each other to provide electrical communication between the power source and the atomizer in the capsule. The patient must provide enough force downward to hold down to allow the electrical contacts to remain in contact such that the atomizer continues to atomize the medication in the capsule. This causes the medication to be dispensed into the tubular chamber 104 for as long as electrical contacts of the housing are in contact with the electrical contacts of the capsule. The atomized medication then moves in direction B towards the end portion 320 of the base unit where a mouthpiece or mask may be attached to. The end portion 320 is similar to the first end portion 130 and the second end portion 134 such that it includes a receiving section with modular fittings. Referring back to
Referring to
Referring now to
The capsule includes a capsule chamber 505 for housing the medication 510 and a rubber section 515 covering an open side 520 of the capsule. In the present embodiment, the capsule chamber can hold up to 20 milliliters of fluid. In other embodiments, the capsule chamber may hold other volumes of fluid, which are within the spirit and scope of the present invention. The rubber section allows for medication to be inserted into the capsule. A user of the capsule may add medication by inserting a syringe through the rubber section and using the syringe to dispense the medication into the capsule chamber 505. The capsule further includes the atomizer 525 proximate to a second side 530 of the capsule and a sensor 535 for detecting the amount of the medication in the capsule. In operation, the capsule chamber is above the atomizer and abuts the atomizer such that gravity allows the medication to go through the atomizer. Gravity forces the medication down such that the medication presses down against the atomizer. The sensor 535 may be a float sensor that measures the level of liquid in the capsule chamber. However, other sensors may be used and are within the spirit and scope of the present invention. After all the medication in the capsule chamber is dispensed through the atomizer, a maximum amount of the medication has been dispensed, or the maximum amount of time has passed, sensor 535 sends a signal to the processor to stop the atomizer. The float sensor is a continuous level sensor featuring a magnetic float that rises and falls as liquid levels change. The movement of the magnetic float creates a magnetic field that actuates a hermetically sealed reed switch located in the stem of the level sensor, triggering the switch to open or close. Other types of sensors configured to detect the amount of liquid in the capsule chamber may be used and are within the spirit and scope of the present invention. Additionally, the maximum amount of medication or time may be adjusted depending on the patient, medication and variety of other factors.
The capsule may also include a removeable covering 550, such as, but not limited to, a cap or seal, in attachment with the second side 530 of the capsule to preserve the medication and/or prevent the medication from leaking. The removeable covering allows users of the system to store capsules for emergency use or long-term use, depending on the type of removeable covering. In some embodiments, the capsule may be color-coded for emergency medication or may include labels that identify the medication within the capsule. The capsule may also include a locking element that prevents the capsule from atomizing the medication unless an access code is provided. The access code may be provided via the remote computing device (708 in
The capsule may also include a processor 540 and a power source 545. In some embodiments, the method for atomizing the medication described herein may be performed by the processor 540 of the capsule. The power source may be a battery power source. In the present embodiment, the battery power source may be a battery power source, such as a standard dry cell battery commonly used in low-drain portable electronic devices (i.e., AAA batteries, AA batteries, etc.). Other types of batteries may be used including rechargeable batteries, aluminum air batteries, lithium batteries, paper batteries, lithium-ion polymer batteries, lithium iron phosphate batteries, magnesium iron batteries etc. Additionally, other types of battery applications may be used and are within the spirit and scope of the present invention. For example, a battery stripper pack may also be used. Additionally, other types of power sources may also be used and are within the spirit and scope of the present invention. In other embodiments, the power source may be an external power source. For example, the system may include a power cable that can connect to an electrical wall outlet. Other types of external power sources may be used and are within the spirit and scope of the present invention. The capsule may also include electrical contacts 1605 that pair with the electrical contacts in the second channel of the base unit.
Referring now to
Referring now to
When a user of the capsule pulls the tab out from between the electrical contacts, the electrical contacts can contact each other and provide electrical communication between the power source and the atomizer. In this embodiment, the amount of energy within the power source is configured to run out after all of the medication within the capsule is atomized. This is useful for medical emergencies because the rescuer can quickly pull out the tab and quickly insert the capsule into the base unit.
Referring now to
Server 702 also includes program logic comprising computer source code, scripting language code or interpreted language code that is compiled to produce executable file or computer instructions that perform various functions of the present invention. In another embodiment, the program logic may be distributed among more than one server 702, computing devices 708 and 712, or any combination of the above.
Note that although server 702 is shown as a single and independent entity, in one embodiment of the present invention, the functions of server 702 may be integrated with another entity, such as each of computing devices 708 and 712. Further, server 702 and its functionality, according to a preferred embodiment of the present invention, can be realized in a centralized fashion in one computer system or in a distributed fashion wherein different elements are spread across several interconnected computer systems.
The process of administering medication to the patient will now be described with reference to
In step 835, the system causes fresh air 168 within a resilient air bladder in fluid communication with the tubular chamber to be conveyed from the resilient air bladder 102 through the conduit 132. The fresh air then flows into the tubular chamber to mix with the atomized medication. In step 840, the air conveyed from the resilient air bladder and the medication dispensed from the capsule is administered to the patient. In step 845, the resilient air bladder 102 returns to its original shape such that the rescuer may squeeze it again to supply more fresh air into the system.
It is understood that this method is a continuous cycle and that each step of method 800 may operate concurrently with another step of method 800 to provide efficient administration of medication within the system. In other embodiments, the method may further include additional steps to promote efficient administration of medication consistent with the systems disclosed herein.
With reference to
In step 910, the attachment device determines, based on the signal, a maximum volume of the medication to atomize or a maximum amount of time to atomize the medication. The maximum amount of time can be set to a certain amount of time and can be adjusted during operation. For example, the maximum amount of time may be 2-10 seconds, 1 minute, etc. The maximum volume can be set to a certain volume and adjusted during operation. For example, the maximum volume may be 1, 2 or 4 milliliters. However, other embodiments may be used and are within the spirit and scope of the present invention. In step 915, the attachment device sends, to the atomizer, a second signal to cause the atomizer to atomize the maximum volume of the medication and/or the medication for the maximum amount of time. The maximum volume and the maximum amount of time depends on the signal sent by the remote computing device. In step 920, the attachment receives, from the atomizer, a third signal from the sensor that monitors an atomized volume of the medication within the capsule and/or a first amount of time the atomizer atomizes the medication. In step 925, the processor of the attachment device determines if the atomized volume is at least as much as the maximum volume based on the third signal received and/or the first amount of time is least as much as the maximum amount of time. In step 930, if the attachment device determines the atomized volume is not at least as much as the maximum volume based on the third signal received and/or the first amount of time is not at least as much as the maximum amount of time, the attachment device allows the atomizer to continue atomizing the medication. In step 935, after the attachment device determines the atomized volume is at least as much as the maximum volume based on the third signal received and/or the first amount of time is least as much as the maximum amount of time, the attachment device sends a fourth signal to stop the atomizer from continuing to atomize the medication within the capsule. In step 940, the attachment device stops the atomizer from continuing to atomize the medication within the capsule.
It is understood that this method is a continuous cycle and that each step of method 900 may operate concurrently with another step of method 900 to provide efficient atomization of medication within the system. In other embodiments, the method may further include additional steps to promote efficient atomization of medication consistent with the systems disclosed herein. In some embodiments, the steps of method 900 may be performed by a processor within the capsule.
Referring now to
With reference to
Computing device 1000 may have additional features or functionality. For example, computing device 1000 may also include additional data storage devices (removable and/or non-removable) such as, for example, magnetic disks, optical disks, or tape. Such additional storage is illustrated in
Computing device 1000 may also contain a communication connection 1016 that may allow device 1000 to communicate with other computing devices 1018, such as over a network in a distributed computing environment, for example, an intranet or the Internet. Communication connection 1016 is one example of communication media. Communication media may typically be embodied by computer readable instructions, data structures, program modules, or other data in a modulated data signal, such as a carrier wave or other transport mechanism, and includes any information delivery media. The term “modulated data signal” may describe a signal that has one or more characteristics set or changed in such a manner as to encode information in the signal. By way of example, and not limitation, communication media may include wired media such as a wired network or direct-wired connection, and wireless media such as acoustic, radio frequency (RF), infrared, and other wireless media. The term computer readable media as used herein may include both computer storage media and communication media.
As stated above, a number of program modules and data files may be stored in system memory 1004, including operating system 1005. While executing on processing unit 1002, programming modules 1006 (e.g., program module 1007) may perform processes including, for example, one or more of the stages of the methods 800, 900 as described above. The aforementioned processes are examples, and processing unit 1002 may perform other processes. Other programming modules that may be used in accordance with embodiments of the present invention may include electronic mail and contacts applications, word processing applications, spreadsheet applications, database applications, slide presentation applications, drawing or computer-aided application programs, etc.
Generally, consistent with embodiments of the invention, program modules may include routines, programs, components, data structures, and other types of structures that may perform particular tasks or that may implement particular abstract data types. Moreover, embodiments of the invention may be practiced with other computer system configurations, including hand-held devices, multiprocessor systems, microprocessor-based or programmable user electronics, minicomputers, mainframe computers, and the like. Embodiments of the invention may also be practiced in distributed computing environments where tasks are performed by remote processing devices that are linked through a communications network. In a distributed computing environment, program modules may be located in both local and remote memory storage devices.
Furthermore, embodiments of the invention may be practiced in an electrical circuit comprising discrete electronic elements, packaged or integrated electronic chips containing logic gates, a circuit utilizing a microprocessor, or on a single chip (such as a System on Chip) containing electronic elements or microprocessors. Embodiments of the invention may also be practiced using other technologies capable of performing logical operations such as, for example, AND, OR, and NOT, including but not limited to mechanical, optical, fluidic, and quantum technologies. In addition, embodiments of the invention may be practiced within a general-purpose computer or in any other circuits or systems.
Embodiments of the present invention, for example, are described above with reference to block diagrams and/or operational illustrations of methods, systems, and computer program products according to embodiments of the invention. It is understood that, in certain embodiments, the functions/acts noted in the blocks may occur out of order as shown in any flowchart. For example, two blocks shown in succession may in fact be executed substantially concurrently or the blocks may sometimes be executed in the reverse order, depending upon the functionality/acts involved.
While certain embodiments of the invention have been described, other embodiments may exist. Furthermore, although embodiments of the present invention have been described as being associated with data stored in memory and other storage mediums, data can also be stored on or read from other types of computer-readable media, such as secondary storage devices, like hard disks, floppy disks, or a CD-ROM, or other forms of RAM or ROM. Further, the disclosed methods' stages may be modified in any manner, including by reordering stages and/or inserting or deleting stages, without departing from the invention.
Referring now to
When the membrane is ruptured, the gravity causes the liquid formulation to flow from the first chamber into the second chamber. An atomizer is disposed proximate to a portion 1740 or lower end of the second chamber that is distal to the first chamber. The second chamber abuts the atomizer such that gravity pushes the medication into the atomizer.
The use of a two-chamber capsule provides distinct advantages for shipping and transport of medications by enabling a controlled release mechanism. The first chamber serves as a storage compartment where the medication is securely held until activated, while the second chamber allows fluid communication with the medication after activation.
During shipping and transport, the medication remains confined within the first chamber of the two-chamber capsule, providing a stable and secure environment. This configuration prevents unintended exposure or premature mixing of the medication with any accompanying fluids or substances, ensuring the integrity and potency of the medication during transit. Upon activation, typically through a user-initiated action, the capsule's design allows for controlled fluid communication between the first and second chambers. This enables the release of the medication into the second chamber, where it becomes available for administration or further processing.
By separating the storage and activation stages, the two-chamber capsule minimizes the risk of premature degradation or alteration of the medication during shipping. This feature enhances the stability and shelf life of the medication, preserving its efficacy and therapeutic properties until it is ready for use. Moreover, the controlled release mechanism provided by the two-chamber design allows for precise dosing and administration. Activation at the desired time ensures that the medication is mixed with the accompanying fluid or solvent in the second chamber when it is most appropriate for administration. This feature is particularly beneficial for medications requiring reconstitution or those with specific timing requirements for optimal effectiveness. Overall, the two-chamber capsule's ability to store the medication separately from the accompanying fluid or solvent during shipping and transport provides advantages in terms of stability, potency, and controlled release. This design ensures that the medication remains protected until activation, allowing for safe and effective administration while maintaining the desired therapeutic outcomes.
Referring now to
Rubberized seal 1810 is specifically designed to receive medication within capsule 1800. Composed of elastomeric materials, such as natural or synthetic rubber, this seal creates an airtight and secure enclosure for the medication, preventing leakage or contamination. The rubberized seal's resilience and deformable properties enable it to adapt to the medication's shape and size, ensuring a snug fit. The rubberized seal is an elastomeric component designed to facilitate the secure and airtight reception of medication boluses acting as a refillable container within the capsule. The seal exhibits resilient and deformable characteristics, allowing it to effectively enclose and retain the boluses while ensuring the integrity of the container's contents. The rubberized seal comprises a resilient material, typically composed of natural or synthetic rubber, or other suitable elastomers. This material possesses desirable properties such as flexibility, elasticity, and compression resistance, rendering it able to be pierced by a needle to inject medication within the seal and/or container. In its preferred embodiment, the rubberized seal is integrated into a refillable container, forming a tight and hermetic seal when engaged. The capsule may feature an opening or orifice in the crimp specially designed to receive the medication boluses or provide access to the rubberized seal to allow a user to inject medication into the rubberized seal by way of manual insertion or automated dispensing.
Capsule 1800 incorporates at least one chamber 1815 to hold the medication securely. These chambers are designed to accommodate the desired amount and formulation of medication, ensuring proper storage and controlled release. The number of chambers may vary based on the specific application and intended use of the capsule, such as
Mesh 1830 is specifically designed to facilitate the atomization or aerosolization of the medication contained within the capsule. The atomizing mesh is composed of a fine material with micro-sized openings that allow for the breakup of the liquid medication into tiny droplets or particles, creating an inhalable or respirable mist. During the activation process, when the medication is intended for administration, the liquid medication is transferred or directed towards the atomizing mesh. As the medication flows through the mesh, it encounters the fine openings, which disrupt the liquid into a spray or mist-like form. The atomized medication, consisting of smaller droplets or particles, becomes suitable for inhalation or respiratory delivery. This mechanism allows for efficient and targeted delivery of the medication to the desired site within the respiratory system, maximizing its effectiveness and bioavailability.
Housing 1835 forms the outer structure of capsule 1800, providing a protective enclosure for the internal components. The housing may be composed of various materials, such as plastic, metal, or composite materials, offering durability and shielding the internal elements from external influences or damage. The housing may include a plurality of cutouts for the electrical components, namely, the sensor and the electrical contacts. Additionally, the housing may include a cutout which may be an opening 1840 allowing the user to see or visualize the level of medication within the at least one chamber 1815. The at least one chamber may be transparent and/or have a transparent section that corresponds to the opening or window 1840 and/or may include alphanumeric fluid level indicators.
In certain embodiments, as shown in
Additionally, the protruding wedge or dovetail shape contributes to the overall stability and secure engagement of the capsule within the device. By creating a locking or interlocking mechanism between the capsule and the device, the asymmetrical shape enhances the overall robustness and reliability of the system. The incorporation of a protruding wedge or dovetail as an asymmetrical shape within the housing of the capsule represents an innovative aspect of the invention. It allows for intuitive and foolproof orientation and alignment, ensuring seamless operation and optimal performance of the device.
The inclusion of a refillable capsule in the disclosed invention represents a significant advancement over the prior art, offering a range of advantages and improvements. The refillable capsule introduces enhanced convenience, cost savings, and environmental benefits to the field of medication administration. By enabling multiple uses, the refillable capsule eliminates the need for single-use disposable capsules, leading to substantial cost savings for users. This economic advantage is further complemented by the reduction of waste, promoting sustainability and environmental stewardship. Moreover, the refillable nature of the capsule allows for personalized medication administration, as users can easily refill it with the specific medication and dosage required for their individual needs. This flexibility not only optimizes therapeutic outcomes but also simplifies medication management by eliminating the need for multiple specialized devices or capsules. Additionally, the user-friendly design facilitates a straightforward refilling process, ensuring ease of use and minimizing the likelihood of errors or confusion. Overall, the inclusion of a refillable capsule in the invention provides users with improved convenience, cost savings, and a more sustainable approach to medication administration.
Referring now to
In some cases, the weight of the attachment device may be an issue when the user must put down the attachment device during usage. Therefore, in some embodiments, the capsule may be configured to be received directly by the modular tubular extension. The capsule and the attachment device may include a Universal Serial Bus (“USB”) port such that a USB cord can provide electrical communication between the attachment device and the capsule. This allows the capsule and the modular tubular extension to rest on the patient without the weight of the device, which can be placed elsewhere.
Referring now to
In one example embodiment, as shown in
In certain embodiments, each press of the button may release a predetermined bolus of atomized medication. This function ensures exact control, allowing for the administration of a specific dose of atomized medication into the patient's respiratory system. The button may be intricately connected to the medication chamber, atomizer, and other system components, coordinating to atomize and meter the correct volume of medication for each press.
Referring now to
The mouthpiece 2616 is in fluid communication with the first channel 2620 and second channel 2625 that are configured to guide the flow of atomized medication from the capsule 2630. In some embodiments, as shown in
In some embodiments, the mouthpiece 2616 may be flexible and configured to be attached to the modular tubular extension. This allows device 2600 to be used as the attachment device shown in
Referring now to
The case may be comprised of metallic material such as carbon steel, stainless steel, aluminum, Titanium, other metals or alloys, composites, ceramics, polymeric materials such as polycarbonates, such as Acrylonitrile butadiene styrene (ABS plastic), Lexan™ and Makrolon™. other materials having waterproof type properties. The case may be made of other materials and is within the spirit and the disclosure. The case may be formed from a single piece or from several individual pieces joined or coupled together. The components of the case may be manufactured from a variety of different processes including an extrusion process, a mold, casting, welding, shearing, punching, folding, 3D printing, CNC machining, etc. However, other types of processes may also be used and are within the spirit and scope of the present invention.
Referring specifically to
Method 2900 begins with step 2902, wherein a user determines that the patient is in the unconscious state. Method 2900 includes removing and inserting the second extension tubular chamber of the removable modular tubular extension into a device receiving section depending on the state of the patient. For example, in most unconscious states or conscious states, the device will be in attachment with the first embodiment of the removable modular tubular extension 2000 shown in
Referring to
In certain embodiments, the receiving section may further include a cross section corresponding to the cross-sectional shape of the capsule to facilitate the insertion of the capsule into the device. In certain embodiments, the receiving section may also include electrical contacts on the interior surface of the receiving section to align with the electrical contacts on the capsule. Extension 2000 may further include a button 3450 being the button disclosed in the embodiment of
The removable modular tubular extension may be comprised of metallic material such as carbon steel, stainless steel, aluminum, Titanium, other metals or alloys, composites, ceramics, polymeric materials such as polycarbonates, such as Acrylonitrile butadiene styrene (ABS plastic), Lexan™, and Makrolon™. other materials having waterproof type properties. The removable modular tubular extension may be made of other materials and is within the spirit and the disclosure. The removable modular tubular extension may be formed from a single piece or from several individual pieces joined or coupled together. The components of the removable modular tubular extension may be manufactured from a variety of different processes including an extrusion process, a mold, casting, welding, shearing, punching, folding, 3D printing, CNC machining, etc. However, other types of processes may also be used and are within the spirit and scope of the present invention. The modular tubular extension, as an integral component of the medical device, can also be constructed from a variety of materials that conform to the stringent requirements of medical device applications. Examples of suitable materials include medical-grade plastics such as polyethylene (PE), polypropylene (PP), polyvinyl chloride (PVC), and thermoplastic elastomers (TPE). These plastics offer a combination of biocompatibility, flexibility, and ease of manufacturing, making them well-suited for medical device tubing. Silicone, known for its excellent biocompatibility, high-temperature resistance, and flexibility, is commonly utilized in medical tubing and catheters. For applications requiring strength and durability, stainless steel may be employed due to its corrosion resistance. Titanium and titanium alloys, renowned for their strength, low density, and biocompatibility, find utility in medical implants. Nitinol, a shape memory alloy, is employed in devices necessitating dynamic shape changes. Biodegradable polymers like polylactic acid (PLA) and polyglycolic acid (PGA) are used for temporary medical devices that degrade over time. The choice of material for the modular tubular extension depends on factors such as the intended use, desired properties, biocompatibility, sterilization compatibility, and regulatory compliance, all of which ensure patient safety and device performance within the confines of medical device regulations.
It should be noted that the device may be comprised of the same materials as the modular tubular extension. The utilization of the same materials for both the modular tubular extension and the medical device holds significant importance within the present invention. Consistency in material composition ensures compatibility and minimizes the risk of material interactions or incompatibilities that could compromise device performance or patient safety. This approach assures biocompatibility throughout the device, reducing the likelihood of adverse reactions or complications. Moreover, employing identical materials simplifies manufacturing and processing, eliminating the need for additional material compatibility testing and streamlining production processes. From a regulatory perspective, employing consistent materials facilitates the submission and approval process, as it provides a clear and well-documented rationale for material selection and ensures compliance with relevant standards. By maintaining material consistency, the device's structural integrity, durability, and performance characteristics remain consistent, fostering reliability and enhancing the overall quality of the medical device.
In the second embodiment of removable modular tubular extension 2100, the second extension tubular chamber includes a first section 2105 and a second section 2110. The first section is configured to be received by the device and has an angle 2115 relative to the second section. Angle 2115 is approximately 135 degrees. The second section 2110 is perpendicular to the first extension tubular chamber such that the angle between the second section and the first extension tubular chamber is at angle 2120, which is approximately 45 degrees. This allows the atomized medication to travel through the second channel into the first channel such that the flow of fresh air can push the atomized medication upwards in the first channel. Shown in
In one embodiment, the second extension tubular chamber may include a variable angle and/or partial composition from a flexible material, thereby enabling a variable angle within the conduit. By incorporating a variable angle within the conduit, the invention provides increased flexibility and adaptability in fluid communication with the first extension tubular chamber. The conduit can be adjusted to different angles or orientations, accommodating diverse system configurations or specific requirements. This adjustability allows for precise routing of fluids, optimizing flow dynamics and enhancing the overall performance of the system. Furthermore, the conduit's composition may be comprised of a flexible material in at least a portion of the conduit, namely the portion requiring the variable bend and/or angle, which contributes to the variable angle capability. The flexible nature of the material enables the conduit to bend or flex at the desired angle, facilitating seamless fluid communication with the first channel. This flexibility allows for smooth and uninterrupted flow, minimizing pressure losses or restrictions within the system. The incorporation of a conduit with a variable angle and flexibility within the invention presents numerous advantages. It enables the adaptation of fluid routing to specific needs, optimizing system performance and efficiency. The variable angle capability ensures accurate and targeted fluid delivery, promoting precise control and distribution within the system. Additionally, the flexibility of the conduit material enhances durability and resilience, mitigating the risk of damage or failure during operation.
Next, in step 2904, the user. inserts the capsule containing the medication into the device, or base unit, having the tubular chamber. In step 2906, the user removes the stop on the capsule that inhibits the first chamber from translating relative to the second chamber. In step 2908, the user applies a second force to the first chamber causing the first chamber to translate relative to the second chamber rupturing a membrane disposed between the first chamber and the second chamber thus providing fluid communication between the first chamber and the second chamber. In step 2910, the user provides power to the atomizer by removing an insulator that prevents electrical communication between the atomizer and a power source. In step 2912, the processor activates the atomizer to atomize the medication to generate at least one atomized medication comprising a plurality of particles. Each particle of said plurality of particles is at most four microns in diameter. In step 2914, gravity causes the liquid formulation to move from the first chamber to the second chamber. In step 2916, the device dispenses the atomized medication from the capsule into the tubular chamber. In step 2918, the user applies a force to a mask that is positioned over the patient's nose and the patient's mouth and in fluid communication with the tubular chamber. In step 2920, the user administers the atomized medication to the patient using the device by at least partially deflating a resilient air bladder in fluid communication with the tubular chamber causing air within the resilient air bladder to be conveyed from the resilient air bladder into the tubular chamber.
With reference to
With reference to
Referring now to
The second chamber includes tapered wall sections 1750 to direct the at least one medication toward the mesh of the atomizer. The tapered wall sections refer to a compartment or space featuring a sloping or gradually narrowing wall within its structure. This specific design is implemented to guide or direct the medication toward the atomizer. The tapered wall section serves to concentrate the medication flow towards the atomizer, thus enhancing the atomization process and ensuring that the medication is uniformly spread. This optimizes the flow path of the medication, thus potentially improving the consistency and efficiency of the atomization process, and thereby enhancing the overall effectiveness of the medication delivery.
The capsule system further includes a stopper 3020 in fluid communication with the second chamber. The stopper is a self-sealing rubber stopper that covers the open side of the first chamber. The materials for this self-sealing stopper may include, but are not limited to, elastomers, silicone rubber, or other flexible and resilient materials that provide a tight seal while allowing temporary access when needed. In a medical context, a self-sealing rubber stopper is used to seal containers like vials or chambers, and it can be punctured by a syringe or other device to access the contents without permanently compromising the seal. The stopper is self-sealing, meaning that it automatically returns to a closed or sealed position after being accessed or penetrated, such as during a refilling process. This ensures that the integrity of the chamber's contents is maintained without requiring manual resealing. The materials for this self-sealing stopper may include, but are not limited to, elastomers, silicone or butyl rubber, or other flexible and resilient materials that that have been carefully formulated to offer the right balance of elasticity, resilience, and chemical resistance. These materials provide a tight seal while allowing temporary access when needed. The material must be compliant with pharmaceutical or medical standards. The rubber stopper enhances the usability of the device, particularly in scenarios where repeated access to the chamber is required, such as for refilling. It ensures a consistent and secure seal, thereby maintaining sterility and preventing leaks, and it simplifies the handling of the device, reducing the potential for user error.
The capsule system also includes a housing 3025 that substantially encloses the chambers. The housing is a protective case or enclosure designed to contain and protect internal components. This provides a controlled environment for the medication contained within the chamber. The composition of the capsule and the chamber may include, but are not limited to, materials suitable for medical applications, such as medical-grade plastics or bio-compatible metals, ensuring safe and effective operation within the medical device environment.
The capsule includes a capsule width 3030 and the chambers includes a chamber width 3035 such that the chamber width substantially spans the capsule width. In some embodiments, the chamber width may span at least 50 percent of the capsule width. In other embodiments, the chamber width may span at least 50 percent of the capsule width. In this embodiment, the walls of the chambers are designed to abut the walls of the housing, thereby forming a connection that often provides stability, containment, and precise alignment within the system. This alignment may facilitate the controlled flow of medication, prevent leakage, and contribute to the correct orientation and functioning of other components, such as sensors, atomizers, or electrical contacts. The chambers substantially occupy a cavity with the capsule without any voids between a chamber wall of the chamber and a housing wall of a housing of the capsule. This means that the size of the chamber, as determined by its transverse dimension or diameter, is almost as large as that of the capsule system itself. Therefore, the chamber effectively maximizes the available internal space of the capsule, minimizing any wasted or unused space within the capsule system. This arrangement of the chamber width substantially spanning the capsule width represents an improvement over prior art in the field of medical devices. It allows for efficient use of space within the capsule system, potentially accommodating larger medication volumes or multiple functionalities within the same capsule size. This leads to increased utility of the medical device without necessitating a proportional increase in its physical size, thus improving the overall efficiency and user experience.
A membrane 1720 preventing fluid communication is disposed between the first chamber from the second chamber. The membrane is a thin, flexible layer or barrier that prevents the passage of liquid. The membrane may include, but is not limited to, a range of impermeable materials that are compatible with the medication and the atomizer, such as certain plastics, elastomers, or composite materials that are engineered to provide a secure yet breakable or penetrable barrier. The membrane allows precise control over the release and flow of medication into the atomizer. This can lead to reduced risk of contamination or spillage and the possibility of more sophisticated release mechanisms that can be tailored to specific medical needs or patient preferences.
At least one rupturing element 1755 is in attachment with the first chamber 1705 or the second chamber 1720 such that the at least one rupturing element configured to engage the membrane 1720 when a first force is applied to translate the first chamber relative to the second chamber 1710. This rupturing element is configured to engage with a membrane that separates two chambers. Engagement occurs when a predetermined force, termed a first force, is applied, translating the first chamber relative to the second. This relative movement prompts the rupturing element to come into contact with the membrane, puncturing or tearing it to allow fluid communication between the chambers. Such a mechanism can enable the flow of medication or another substance from one chamber to the other or activate specific functionalities within the medical device. Compared to previous designs, the careful configuration of the rupturing element for engagement with the membrane in response to a specific force represents a controlled, precise mechanism for regulating fluid communication within the system. It allows for more control over medication dosage, timing, or mixing of components and enhances safety by ensuring that the membrane is ruptured under controlled conditions.
When the first chamber is pushed towards the second chamber, the rupturing elements pierce and break the membrane such that the membrane becomes a ruptured membrane 3040 to allow the medication to flow out of the first chamber and into the second chamber. A stop 1725 is disposed between the first chamber and the second chamber inhibiting the first chamber from translating relative to the second chamber.
The rupturing element may be composed of materials that provide the necessary strength, sharpness, and resilience for the intended function. Materials such as stainless steel, hard plastics, or other biocompatible materials may be used to provide the necessary strength, sharpness, and resilience to ensure that the rupturing element performs effectively without compromising the integrity or sterility of the contents.
The capsule further includes a plug 3045 disposed at the lower end portion 3010 of the capsule system. The plug includes a plug receiver 3046 and a plug cap 3048. The plug's primary function is to provide a seal or barrier at the lower end portion. The plug cap includes a protruding section 3050 configured to be received by a dimple 3055 of the plug receiver. The diameter of the dimple is slightly smaller than the diameter of the protruding section 3050 such that the protruding section is tightly received by the plug dimple 3055. This provides a tight seal that prevents leakage of liquid solution. By being strategically positioned, the plug prevents the atomizer from leaking medication and contamination from external sources. Its role in the capsule system ensures that the contents of the chamber(s) are managed according to the device's operational requirements. The plug offers a targeted solution to potential issues related to leakage, flow control, and hygiene. Its presence thus contributes to the overall efficiency and effectiveness of the capsule system, marking an improvement over previous designs in the field. The plug may be constructed from, but is not limited to, various materials, such as rubber, silicone, or other elastomers, which offer properties like flexibility, resilience, and resistance to chemical interaction with the medication. The selection of materials would depend on the specific demands of the capsule system and its intended medical application.
Referring now to
The capsule system 3100 also includes a removable container 3115 including a removable container width. The removable container is a vial having a fluid volume of 10 milliliters. Other fluid volumes may be used and are within the spirit and scope of the present invention. A seal 3120 is on the removable container. A second chamber 3125 is positioned within the removable container. The medication 510 is disposed within the second chamber. The removable container is disposed within the first chamber 3105 through the open top side of the first chamber. The container width spans substantially the first chamber width. When a force is applied on the removable container towards the first chamber, the rupturing element penetrates the seal to provide fluid communication between the first chamber and the second chamber.
The removable container functions as a specialized chamber within the capsule system, allowing for specific medications or substances to be enclosed and protected. Its removable nature offers flexibility in handling, refilling, or changing the contents without altering other parts of the system. Users of the capsule may have multiple removable containers, each labeled and containing different medications similar to commonly used medical vials. Therefore, the removable containers allow for efficient replacement or replenishment of medication for the capsule. When inserted, it integrates seamlessly with other elements such as the rupturing element and first chamber, providing a cohesive function within the overall medical device. The removable container presents a significant advancement in managing and delivering medication in medical devices. By facilitating easy insertion and removal, the container enables efficient handling, customization, and maintenance of the system. The feature of being removable allows for easier cleaning, sterilization, or replacement, thereby enhancing usability and hygiene. Its precise construction to fit within the existing chambers ensures that the functionality and integration within the device remain consistent, thus overcoming limitations found in previous designs. The removable container may be comprised of materials suitable for medical applications, ensuring biocompatibility, strength, and resistance to contamination. This could include medical-grade plastics, glass, or other sterilizable materials that comply with relevant regulatory standards. However, other materials may be used and are within the spirit and scope of the present invention.
The capsule system 3101 further includes at least one electrical contact 1820 and at least one sensor. The sensor is a fluid sensor that can detect various properties related to the fluid, such as its level, flow rate, or presence. The fluid sensor is configured to detect and monitor the level or presence of medication within the first chamber and/or second chamber of the capsule system. The fluid sensor operates in coordination with other components to ensure proper dispensing of medication. By continually monitoring the fluid level, it provides real-time feedback, enabling precise control over the dosage and alerting the system if the medication reaches a critical level. The fluid sensor adds an additional layer of control and safety in the medication administration process, reducing the risk of administering incorrect dosages, and enhancing the ability to provide tailored treatment regimens. The capsule system 3101 may include a fluid sensor for the removable container 3115 and a second fluid sensor for the first chamber 3105. The electrical contacts are in electrical communication with a power source. The electrical contacts refer to the conductive interface designed to establish a connection within an electronic circuit. The electrical contacts may be composed of, but are not limited to, conductive materials such as copper, gold, or alloys, providing efficient energy transmission without significant loss. This provision for electrical communication with a power source offers improvements over prior art by allowing for consistent and controlled operations of the capsule system, enhancing both reliability and performance, particularly in comparison with manually operated or less sophisticated electronically controlled systems.
With reference to
The most common IV bags are typically made of polyvinyl chloride (PVC) or polyolefin, which are flexible, transparent, and resistant to chemical interactions with the fluids and medications inside. The elongated tube and connecting elements that facilitate this fluid communication may be constructed of biocompatible and inert materials, such as medical-grade silicone, polyurethane, or other suitable polymers. These materials ensure that the integrity and purity of the medication are maintained during transfer.
The elongated tube provides fluid communication between the first chamber and the external container. The fluid and/or the medication from the bag flows through tubing connected to the IV catheter. The elongated tube is in attachment with the first chamber of the capsule. In one embodiment, a medical needle 3215 is attached to the distal end of the elongated tube, and the needle is inserted into the self-sealing rubber stopper of the capsule and partially into the first chamber. The medication will continuously drip, at an adjustable flow rate, into the at least one chamber of the capsule.
The external container and elongated tube permit the medical device to access larger volumes of medication or other fluids stored externally, thus enabling longer or more complex treatment regimens without the need to refill the internal chamber frequently. The ability to connect with external containers also allows for versatility in medication types and concentrations, providing customization to individual patient needs. By maintaining a secure and sterile pathway for fluid transfer, this embodiment ensures safety and efficiency in delivering medication.
With reference to
An electrical conductor is any material or substance through which electric current can pass easily. It includes not only wires and cables but also components like metal bars, plates, or even certain liquids and gases. Conductors are characterized by their ability to carry electrical charges with minimal resistance. The capsule may include more than one conductor as well. The electrical conductor may be an electrical lead. An electrical lead is a conductor or wire that is used to connect an electrical device to a power source, such as a charger connecting a device to an outlet—or in the context of this invention, connect the capsule to the medical device. The electrical conductor may be made from, but are not limited to, materials such as copper, silver, or gold, known for their high electrical conductivity and reliability. The insulation surrounding the conductor would typically be made of materials resistant to medical environments, such as Teflon or other medical-grade polymers.
The port is a specific interface or receptacle on an electronic device or apparatus that facilitates the transfer of data, electrical signals, power, or other information between the device and external components, such as cables, connectors, or peripherals. The port typically comprises a well-defined physical and electrical structure designed to accommodate compatible connectors, ensuring secure and reliable connections. The structure of the port may correspond to the electrical lead such that the port is configured with a compatible shape, size, and electrical layout that matches the design of the electrical lead. The port typically includes male or female terminals, pins, or contacts, strategically positioned within the receptacle to match the corresponding connectors or plugs on the electrical lead. The electrical lead, in turn, features complementary male or female connectors designed to fit precisely into the corresponding terminals of the port. The port's structural design may also incorporate additional features such as locking mechanisms, shielding, or protective covers to enhance durability, prevent accidental disconnections, and safeguard against potential hazards. It is understood that the term “port” should be construed to encompass a broad range of configurations, including but not limited to, input/output (I/O) ports, charging ports, data transfer ports, audio ports, video ports, or any other interface specifically engineered to enable communication, interaction, or power exchange between the capsule and external entities or devices.
The electrical conductor and ports enhance the functionality, flexibility, and user experience of the medical device. Unlike previous designs that may rely solely on manual control or limited interface, this configuration allows for precise control, monitoring, and customization of the treatment. The integration with a remote-control device equipped with a display, processor, and power source enables a more sophisticated and tailored approach to medication administration, potentially improving treatment outcomes, patient compliance, and healthcare professionals' efficiency. This represents a significant advancement over prior art, adding value to the medical field by increasing the utility and effectiveness of the capsule system. For example, this embodiment allows the capsule and the modular tubular extension to rest on the patient without the weight of the remote-control device, which can be placed elsewhere.
The embodiments described in the context of the disclosed invention serve as examples and are non-limiting. While specific configurations, functionalities, and arrangements of elements like the button, atomizer, chambers, and sensors have been detailed, these descriptions are illustrative and not intended to restrict or confine the invention to these exact embodiments. The invention's underlying principles and concepts allow for various modifications, adaptations, and variations. Different designs and arrangements can be developed to meet particular needs or applications without departing from the scope and spirit of the invention. This flexibility ensures that the invention can be tailored to a broad array of medical devices, enhancing the application in diverse scenarios and providing improvements over the existing art in multiple contexts.
Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as example forms of implementing the claims.
This application is a continuation in part application of U.S. Non-Provisional application Ser. No. 18/224,502 titled “Apparatus, Methods, and Systems for Administering a Medication to a Patient” and filed Jul. 20, 2023, which is a continuation in part application of U.S. Non-Provisional application Ser. No. 18/207,242 titled “Apparatus, Methods, and Systems for Administering a Medication to a Patient” and filed Jun. 8, 2023, the subject matter of each of which is incorporated herein by reference.
| Number | Name | Date | Kind |
|---|---|---|---|
| 3802604 | Morane | Apr 1974 | A |
| 3809225 | Allet-Coche | May 1974 | A |
| 4174035 | Wiegner | Nov 1979 | A |
| 5529055 | Gueret | Jun 1996 | A |
| 8012136 | Collins, Jr. | Sep 2011 | B2 |
| 8376988 | Perovitch | Feb 2013 | B2 |
| 9352108 | Reed | May 2016 | B1 |
| 20020134374 | Loeffler | Sep 2002 | A1 |
| 20030140921 | Smith | Jul 2003 | A1 |
| 20030150445 | Power | Aug 2003 | A1 |
| 20090134235 | Ivri | May 2009 | A1 |
| 20090241948 | Clancy | Oct 2009 | A1 |
| 20100044460 | Sauzade | Feb 2010 | A1 |
| 20110146670 | Gallem | Jun 2011 | A1 |
| 20130119151 | Moran | May 2013 | A1 |
| 20140166776 | Fang | Jun 2014 | A1 |
| 20140224815 | Gallem | Aug 2014 | A1 |
| 20150097047 | Hu | Apr 2015 | A1 |
| 20150352297 | Stedman | Dec 2015 | A1 |
| 20170203055 | Chen | Jul 2017 | A1 |
| 20170232211 | Gallem | Aug 2017 | A1 |
| 20170304565 | Allosery | Oct 2017 | A1 |
| 20180021528 | Hsieh | Jan 2018 | A1 |
| 20180290157 | Gruenbacher | Oct 2018 | A1 |
| 20190143053 | Chen | May 2019 | A1 |
| 20190240428 | Stenzler | Aug 2019 | A1 |
| 20190298939 | Shawver | Oct 2019 | A1 |
| 20190298980 | Besen | Oct 2019 | A1 |
| 20190388627 | Kern | Dec 2019 | A1 |
| 20200009600 | Tan | Jan 2020 | A1 |
| 20200138117 | Rosser | May 2020 | A1 |
| 20200390984 | Hua | Dec 2020 | A1 |
| 20210268533 | Lee | Sep 2021 | A1 |
| 20220211956 | Hsieh | Jul 2022 | A1 |
| 20220305216 | Chang | Sep 2022 | A1 |
| 20220314264 | Lee | Oct 2022 | A1 |
| Number | Date | Country |
|---|---|---|
| 111840715 | Oct 2020 | CN |
| 202010015263 | Apr 2012 | DE |
| 3323454 | May 2018 | EP |
| WO-2018040995 | Mar 2018 | WO |
| WO-2022192736 | Sep 2022 | WO |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 18224502 | Jul 2023 | US |
| Child | 18449838 | US | |
| Parent | 18207242 | Jun 2023 | US |
| Child | 18224502 | US |
