SWALLOWING TEST APPARATUS

专利摘要:
swallowing tester. The present invention relates to apparatus and methods for diagnosing swallowing dysfunction. the devices may include a multi-parameter dysphagia analysis system on a plastic sheet. analysis systems can be intelligent detection systems that are flexible, light in weight, and based on substrates (12) that have low-cost electronic component technologies printed on them. methods may include measurement and classification of non-invasive parameters that may be indicative of swallowing dysfunction or the likelihood of it. in a general embodiment, the methods include placing a sensor (10) on a patient to measure at least one parameter associated with the patient's swallowing profile. the measured parameter is then analyzed and compared with various dysphagic and normal swallowing profiles to provide an indication of the likelihood of an underlying swallowing dysfunction.
公开号:BR112013018842B1
申请号:R112013018842-1
申请日:2012-01-27
公开日:2021-07-27
发明作者:Michael Rueben Jedwab；Adam Stewart Burbidge；Jan Engehmann；Andreas Henning Busch
申请人:Société des Produits Nestlé S.A.；
IPC主号:

专利说明:

Background
[0001] The present invention relates generally to health and nutrition. More specifically, this description refers to the diagnosis of a swallowing disorder based on the analysis of several parameters related to swallowing that may be indicative of it.
[0002] Dysphagia is the medical term for the symptom of difficulty in swallowing and refers to any swallowing disorder, which may include, for example, abnormalities within the oral, pharyngeal and esophageal phases of swallowing. Many complications can occur as a result of swallowing disorders including, for example, dehydration, malnutrition, airway obstruction, dysfunctional immune response, etc. as a result, it is not only critical to detect and diagnose dysphagia and aspiration, but it is important to detect these conditions as early as possible. Unfortunately, it is estimated that approximately 80% of patients with dysphagia remain undiagnosed, which is believed to be due, at least in part, to the fact that general practitioners and nursing homes are relatively ill-equipped to diagnose these conditions. Although several diagnostic tools exist to diagnose dysphagia and aspiration, many of these tools are expensive, time-consuming, invasive, are only available in specialized centers and can expose the patient to ionizing radiation.
[0003] Therefore, it would be beneficial to provide devices and methods for diagnosing a swallowing disorder that are convenient, easy to use, economical, provide quick results, and are widely available. summary
[0004] The present description provides devices for diagnosing a swallowing disorder or dysfunction. The devices include, for example, a flexible substrate with printed electronic components selected from the group consisting of a microcontroller, at least one printed sensor, an antenna or combinations thereof. Flexible substrate and printed electronic components can be wrapped in a plastic sheet.
[0005] In one embodiment, the flexible substrate comprises a flexible polymer. The flexible polymer can be selected from the group consisting of polyethylene naphthalate ("PET"), polyethylene terephthalate ("PET") or combinations thereof. The sensor can be disposable.
[0006] In one embodiment, the sensor's printed electronics include a plurality of printed sensors. Sensors can be configured to sense sound, acoustics, acceleration, velocity, distance, electromyography, mechanical myography, electrical myography, videofluoroscopy, thermography, temperature, or combinations thereof. The antenna can be configured to receive and/or transmit data.
[0007] In one embodiment, the sensor additionally includes an adhesive. The adhesive must be safe for use on the skin and be readily removable from the skin.
[0008] In another embodiment, a method for diagnosing a disorder is provided. The method includes placing a sensor on a patient to be evaluated, with the sensor communicating with a device that accepts a sensor output; evaluate the sensor output to get a first result; and issue the first assessment result. The method may further include evaluating the first result to obtain a second result; and output the second result. The first and second results can be output on a display.
[0009] In one modality, the sensor communicates via wiring or via a wireless connection. The connection can also take place via Bluetooth, radio waves or a cell phone network.
[00010] In one modality, the assessment takes place in a patient database. The patient database can be in the same building as the patient. The assessment can take place within 10 minutes of the sensor communicating with the device or substantially instantaneously. The assessment can take place in a cost-effective, validated, sensitive and reliable manner. The assessment can also occur without variability with specificity for the clinician and in a simplified manner for non-specialist use. Assessment may include comparing sensor output to known disturbances/dysfunctions in a patient database. In one modality, the evaluation uses an algorithm to interpret the sensor output.
[00011] The patient database can be updated. The database can be updated by entering a result of a new test into the database. The patient database can be updated by subscription. Patient database updates can be received by at least one of the internet, media and the internet and media. The physical medium can be at least one of a compact disc, a DVD, a pen drive, tape, other physical data storage devices, or combinations thereof. The patient database may contain statistically significant data. The patient database can contain about 5,000 test results and can be used by a plurality of patient test sites.
[00012] In one modality, the evaluation takes place in a central database. The central database can be updated and can be updated by subscription. Central database updates can be received by at least one of the internet, media and the internet and physical media. The physical medium can be at least one of a compact disc, a DVD, a pen drive, tape, other physical data storage devices, or combinations thereof. The central database may contain statistically significant data. The central database can contain about 5,000 test results and can be used by a plurality of patient testing sites.
[00013] In one embodiment, the central database can be configured to gather data from a user site. The central database can be configured to gather data for learning, where the learning comprises variants of normal or a composite normal. The central database can be configured to gather data for advanced science and to continuously improve assessment. The central database can be located in a hospital or a specialty clinic.
[00014] In one modality, the additional assessment is to compare the assessment output to known treatments and/or standard interventions. Further evaluation may include using an algorithm to interpret the second output and determine one or more appropriate treatments. Additional evaluation can take place on a patient database. The patient database may have the same characteristics as the patient database described above.
[00015] In one modality, the evaluation of the first result to obtain a second result takes place in the central database. The first and/or second results may be visual, audible, in Braille, at least one electronic signal, a diagnosis of a disorder or a dysfunction, at least a qualitative measurement of the disorder or dysfunction, at least a quantitative measurement of the disorder or dysfunction, "does the patient have a disorder/dysfunction ", mechanical dysfunction, at least one qualitative measure of mechanical dysfunction, at least one quantitative measure of mechanical dysfunction, biomechanical dysfunction, at least one qualitative measure of biomechanical dysfunction, at least a quantitative measure of biomechanical dysfunction, neurological dysfunction, at least a qualitative measure of neurological dysfunction, at least a quantitative measure of neurological dysfunction, a qualitative measure of dysphagia, swallowing defect, poor swallowing, safety and/or efficacy, a quantitative measure of dysphagia, defect in swallowing, poor swallowing, safety and/or efficacy, a classification of dysfunction of and swallowing, at least one qualitative measure of the dysfunction, at least one quantitative measure of the dysfunction, a classification of a disorder, at least one qualitative measure of the disorder, at least one quantitative measure of the disorder, a classification of a type of dysphagia, a diagnosis of anatomical structures that do not function within normal parameters, a quantitative measurement of multiple parameters of one or more functions of one or more anatomical structures, a quantitative measurement of multiple parameters of one or more functions of one or more anatomical structures, a risk of sequelae from a disorder.
[00016] In one modality, the sequel is selected from the group consisting of aspiration pneumonia, chronic obstructive pulmonary disorder ("COPD"), malnutrition, sarcopenia, dehydration, orthostatic hypotension, functional decline, falls, pressure ulcers, urinary tract infections, skin infection, specific nutrient deficiency conditions, choking, coughing, anxiety, depression or combinations thereof. Sequelae may require immediate care or at least one of a hospital visit, a visit to the doctor's office, medical treatment or medication. The sequelae can be dehydration and associated problems and health care burdens.
[00017] In one modality, the disorder is dysphagia. The first and/or second outcome may be a risk of aspiration pneumonia from dysphagia.
[00018] In one embodiment, the sensor device is at a location remote to a patient database. In one modality, the remote location is at least one of the health professional's office, a skilled nursing facility, and a long-term care facility. The healthcare professional's office can be a doctor's office, a hospital, a clinic. The remote location can also be a mobile location. Mobile location can be a home health care provider. Mobile location can Mobile location can clinic on wheels or a flying care unit.
[00019] In one modality, an assessment issues an outcome that includes a recommended therapy. The recommended therapy can be at least one of products, tools, and services tailored to the patient based on a patient's illness or dysfunction. Recommended therapy may be a therapy plan that includes at least two of: physical therapy, occupational therapy, speech therapy, nutritional formulation, dietary modification, improved oral health, electrical stimulation, biological feedback, and pharmacological treatment. Diet modification may include at least one of: Increased cohesiveness, increased thickness, trigeminal stimulants, swallow stimulants, food temperature modification, food texture modification, and food sensory modification. Improving oral health may include using at least one of mouthwash, toothpaste, probiotics, saliva stimulants, toothbrush, floss, and tongue scraping.
[00020] In an embodiment, the first outcome is a disorder selected from the group consisting of any pathologies, syndromes, diseases that can be diagnosed or classified using that disorder or combinations thereof. The first result may be a disorder that is at least one arthropathy, temporal mandibular dysfunction, colic, irritable bowel syndrome ("IBS"), irritable bowel disorder ("IBD"), at least one bowel disorder, a disorder that is at least one pathology, syndrome or disease that can manifest dysphagia.
[00021] In one embodiment, the methods include diagnosing a disorder or dysfunction. Diagnosis can be made at an early stage of the disorder or dysfunction. The methods can additionally include treating the patient at an early stage in relation to the disorder or dysfunction. As a result, early-stage patient diagnosis and treatment reduces at least one of healthcare costs, emergency room visits, hospitalization, visits to a doctor, or medical treatment.
[00022] In one embodiment, the reduced healthcare costs are due to the reduced sequelae of the disorder or dysfunction. The sequelae can be selected from the group consisting of aspiration pneumonia, chronic obstructive pulmonary disorder ("COPD"), malnutrition, sarcopenia, dehydration, orthostatic hypotension, functional decline, falls, pressure ulcers, urinary tract infections, infection of skin, specific nutrient deficiency conditions, choking, coughing, anxiety, depression or combinations thereof.
[00023] In one modality, reduced healthcare costs are due to reduced need for at least one of healthcare, medical treatment, and institutionalization.
[00024] In one embodiment, reduced healthcare costs are due to at least one of slowing the progression of the disorder/dysfunction, optimizing quality of life, reducing depression, reducing pain, and reducing anxiety.
[00025] In one modality, diagnosing and treating the patient at an early stage leads to reduced risk of at least one of malnutrition, dehydration and associated problems. Diagnosing and treating the patient at an early stage can lead to early treatment of dehydration, which can strengthen the patient's immune system, lead to decreased occurrence of sarcopenia and associated problems, lead to decreased occurrence of muscle dystonia and lead to decreased symptoms of the disorder or dysfunction.
[00026] In yet another modality, methods to reduce health care expenditure costs are provided. Methods include placing a sensor on a patient, gathering data related to a patient's swallowing profile using the sensor, comparing a sensor output to a database containing a plurality of swallowing profiles, diagnosing a swallowing dysfunction and treat swallowing disorders or symptoms thereof. The reduction in healthcare expense costs may be due to reduced length of stay in a hospital, reduced length of stay in a healthcare facility, decreased complications or symptoms associated with swallowing dysfunction, and decreased occurrences of visits from the patient to a health care center selected from the group consisting of a hospital, a clinic, a doctor's office, or combinations thereof. The reduction in healthcare expenses costs may also be due to an early diagnosis of swallowing dysfunction and an early treatment of swallowing dysfunction.
[00027] Early treatment of a swallowing disorder may include a therapy plan that includes at least one of products, tools, or services known to be effective in treating the swallowing disorder. Early treatment may also include a therapy plan that includes at least two of physical therapy, occupational therapy, speech therapy, nutritional formulation, dietary modification, improved oral health, electrical stimulation, biological feedback, and pharmacological treatment. Diet modification can include at least one of increased cohesiveness, increased thickness, trigeminal stimulants, swallow stimulants, food temperature modification, food texture modification, and food sensory modification. Improved oral health can include at least one of mouthwash, toothpaste, probiotics, saliva stimulants, toothbrush, floss, and tongue scraping.
[00028] In one modality, the reduction in health care expenditure costs is due to the reduced sequelae of dysphagia. The sequelae can be selected from the group consisting of aspiration pneumonia, chronic obstructive pulmonary disorder ("COPD"), malnutrition, sarcopenia, dehydration, orthostatic hypotension, functional decline, falls, pressure ulcers, urinary tract infections, infection of skin, specific nutrient deficiency conditions, choking, coughing, anxiety, depression or combinations thereof.
[00029] In one embodiment, the reduction in health care expense costs is due to at least one of slowing the progression of dysfunction, optimizing quality of life, reducing depression, reducing pain, and reducing anxiety.
[00030] In yet another embodiment, methods for diagnosing a dysfunction are provided. Methods include placing a sensor on a patient; measure a level of function of an anatomical structure involved in swallowing, with the sensor communicating with a device that accepts a sensor output representative of the level of function, evaluating the sensor output to obtain a result; and issue the assessment result.
[00031] In one embodiment, the sensor can have a flexible substrate, printed electronic component, an antenna and a microprocessor. The sensor can be a known sensing device selected from the group consisting of videofluoroscopy, electromyography, mechanical myography, thermography or combinations thereof.
[00032] In one modality, the anatomical structure is selected from the group consisting of a jaw, lips, a soft palate, a tongue, a hyoid, an epiglottis, a larynx, a pharynx, an upper esophageal sphincter or combinations of the same.
[00033] In a mode, the function level is selected from the group consisting of low, normal, high, or combinations thereof. The function level can also be selected from the group consisting of poor, normal, excellent or combinations thereof. The level of function may refer to at least one of lip closure, jaw closure, tongue fixation, tongue elevation, tongue control, tongue extension, tongue seal, soft palate seal, mouth breathing, nose breathing, lingual thrust, tongue pressure, laryngeal elevation, hyoid movement, hyolaryngeal excursion, upper esophageal sphincter opening, epiglottis movement, laryngeal opening, vocal cord closure, laryngeal sensation, pharyngeal contraction, pharyngeal fatigue, laryngeal adductor reflex, laryngeal fatigue, stopped breathing, resumption of breathing and sensation of the pharynx.
[00034] In one embodiment, the device is an electronic device that has a processor. The electronic device can be selected from the group consisting of a computer, iPod, iPhone, iPad, cell phone, personal digital assistant ("PDA"), pager, short message service system (" SMS"), a Blackberry or combinations thereof.
[00035] In one embodiment, the evaluation includes comparing the sensor output to a database that contains a plurality of swallow profiles. The plurality of swallow profiles can include both healthy patient swallow profiles and dysphagia patient swallow profiles. The plurality of swallow profiles comprise a specifically significant amount of data.
[00036] In one modality, the result is delivered in a form that is easily understood by the patient. The result produced can be in a form selected from the group consisting of visible, audible, textural and combinations thereof. For example, the output produced is visible and is selected from the group consisting of a printout, an electronic display, a flashing light-emitting diode ("LED"), a light-encoded LED, or combinations thereof. The result produced can also be in Braille. The result produced can be audible and is output from a speaker.
[00037] In another embodiment, a method of treating a swallowing disorder is provided. The method includes measuring a swallow profile of a patient using a sensor, sending a sensor output to a device having a processor and a swallow profile database, comparing the sensor output with the profile database of swallowing to obtain a first result, compare the first result to a database of recommended therapy to obtain a second result and treat the patient in accordance with the second result.
[00038] In one modality, the comparison is performed using the device's processor.
[00039] In one modality, the first result is indicative of a swallowing dysfunction. The first result could be an electronic signal.
[00040] In one embodiment, the recommended therapy database is on the same device as the swallow profile database.
[00041] In one embodiment, the method further includes sending the first result to a second device.
[00042] In one modality, the second outcome is a recommended therapy.
[00043] In one embodiment, the sensor includes a flexible substrate, printed electronic component, an antenna and a microprocessor. The sensor may also include a known sensing device selected from the group consisting of videofluoroscopy, electromyography, mechanical myography, thermography or combinations thereof.
[00044] In one embodiment, the device is selected from the group consisting of a computer, iPod, iPhone, iPad, cell phone, personal digital assistant ("PDA"), a pager, a service system message ("SMS"), a Blackberry, or combinations thereof.
[00045] In one modality, the swallowing profiles database includes both healthy patient swallowing profiles and dysphagia patient swallowing profiles. The swallow profile database can additionally include a statistically significant amount of data.
[00046] In one modality, results are output in a form that is easily understood by the patient. Results can be output in a form selected from the group consisting of visible, audible, textural and combinations thereof. Results can also be output in a visible form and are selected from the group consisting of a printout, an electronic display, a flashing light-emitting diode ("LED"), a light-encoded LED and combinations thereof. Results issued can be in Braille. Output results can be an audible signal emitted from a speaker.
[00047] Additional features and advantages are described in this document and will be apparent from the Detailed Description and figures. Brief Description of Figures
[00048] Figure 1 illustrates a sensor device in accordance with an embodiment of the present description.
[00049] Figure 2 illustrates a sensor device in accordance with an embodiment of the present description.
[00050] Figure 3 illustrates a schematic of a process for manufacturing a sensor device in accordance with an embodiment of the present description. Detailed Description
[00051] The present description is directed to apparatus and methods for diagnosing a swallowing disorder by measuring and classifying non-invasive parameters associated with a patient's swallowing profile that may be indicative of the probability of an underlying swallowing disorder. The devices include, for example, a multi-parameter dysphagia analysis system on a plastic sheet. The analysis system can be a sensing system that is a flexible, lightweight sensor that is based on a polymer substrate that has cost-effective electronic component technologies printed on it. In another embodiment, the sensor is a known sensing device such as, for example, a videofluoroscope ("VF"). Methods can include placing a sensor on a patient to measure at least one parameter associated with swallowing. Measured parameters are evaluated and compared to known swallowing dysfunction data and the assessment provides an indication of the likelihood of an underlying swallowing dysfunction.
[00052] As used in this description and the appended claims, the singular forms "a", "an", "the" and "a" include plural referents unless the context clearly dictates otherwise. Thus, for example, reference to "an amino acid" includes a mixture of two or more amino acids and the like.
[00053] As used herein, "about" is understood to refer to numbers in a range of numerals. Furthermore, it is understood that all numerical ranges in this document include all whole numbers, integers or fractions, within the range. All dosage ranges contained within this application must include all numbers, integers or fractions, contained within said range.
[00054] As used herein, "animal" includes, but is not limited to, mammals, which includes, but is not limited to, rodents, aquatic mammals, domestic animals such as dogs and cats, farm animals such as sheep, pigs, cows and horses and humans. Where the terms "animal" or "mammal" or their plurals are used, it is contemplated that they also apply to any animals that are capable of the effect exhibited or intended to be exhibited by the context of the passage.
[00055] As used herein, "effective amount" is an amount that prevents a deficiency, treats a disease or medical condition in an individual, or more generally reduces symptoms, manages disease progression, or provides a nutritional benefit, physiological or medical for the individual. A treatment can be patient- or physician-related.
[00056] As used herein, "elderly" means a human who is sixty-five years of age or older or at least seventy-five years of age or older.
[00057] Although the terms "individual" and "patient" are often used herein to refer to a human, the present description is not so limited. Accordingly, the terms "subject" and "patient" refer to any animal, mammal or human that has or is at risk of a medical condition that may benefit from treatment.
[00058] As used herein, "food grade microorganisms" means microorganisms that are used and generally considered safe for use in food.
[00059] As used herein, "mammal" includes, but is not limited to, rodents, aquatic mammals, domestic animals such as dogs and cats, farm animals such as sheep, pigs, cows and horses, and humans. Where the term "mammal" is used, it is contemplated that the same applies to other animals that are capable of the effect exhibited or intended to be exhibited by the mammal.
[00060] The term "microorganism" is intended to include bacteria, yeast and/or fungus, a cell growth medium with the microorganism or a cell growth medium in which the microorganism was cultured.
[00061] It is understood that "nutritional compositions", as used herein, include any amount of optional additional ingredients, including conventional food additives, e.g., one or more, additional acidulants, thickeners, buffers or agents for the adjustment of pH, chelating agents, colorants, emulsifiers, excipient, flavoring, mineral, osmotic agents, a pharmaceutically acceptable carrier, preservatives, stabilizers, sugar, sweeteners, texturizers and/or vitamins. Optional ingredients can be added in any suitable amount.
[00062] As used herein, probiotic microorganisms (hereinafter "probiotics") are food grade microorganisms (live, including semi-viable or weakened and/or non-replicating), metabolites, cell preparations microbial or microbial cell components that could confer health benefits on the host when administered in adequate amounts, more specifically, that beneficially affect a host by improving its intestinal microbial balance, leading to effects on the health or well-being of the host. See, Salminen S, Ouwehand A. Benno Y. et al. , Probiotics: how should they be defined , Trends Food Sci. Technol. 1999: 10, 107-10. In general, these microorganisms are believed to inhibit or influence the growth and/or metabolism of pathogenic bacteria in the intestinal tract. Probiotics can also activate the host's immune function. For that reason, there have been many different approaches to including probiotics in food products. Non-limiting examples of probiotics include Aerococcus, Aspergillus, Bacillus, Bacteroides, Bifidobacterium, Candida, Clostridium, Debaromyces, Enterococcus, Fusobacterium, Lactobacillus, Lactococcus, Leuconostoc, Melissococcus, Micrococcus, Mucor, Oenopiococcus, Penchiacoccus, Pedicoccus, Pedicoccus , Pseudocatenulatum, Rhizopus, Saccharomyces, Staphylococcus, Streptococcus, Torulopsis, Weissella or combinations thereof.
[00063] As used herein, the terms "treatment", "treat" and "alleviating" include both prophylactic or preventive treatment (which prevents and/or delays the development of a targeted pathological condition or disorder) and curative treatment , therapeutic or disease modifier, including therapeutic measures that cure, delay, lessen the symptoms of and/or stop the progression of a diagnosed condition or pathological disorder; and treating patients at risk of contracting a disease or suspected of having contracted a disease, as well as patients who are ill or have been diagnosed as suffering from a disease or medical condition. The term does not necessarily imply that a subject is treated until full recovery. The terms "treatment" and "treating" also refer to the maintenance and/or promotion of health in an individual who does not suffer from a disease but who may be susceptible to the development of an unhealthy condition, such as nitrogen imbalance, muscle loss. . The terms "treatment", "treat" and "alleviating" are also intended to include the potentiation or otherwise enhancement of one or more primary therapeutic and prophylactic measures. The terms "treatment", "treating" and "alleviating" are intended to further include dietary management of a disease or condition or dietary management for the prophylaxis or prevention of a disease or condition. Dysphagia and Aspiration
[00064] Dysphagia is the medical term for the symptom of difficulty in swallowing and refers to any disorder of swallowing (swallowing), which may include, for example, abnormalities within the oral, pharyngeal and esophageal phases of swallowing. Dysphagia is common in individuals who have neurological impairment due to cerebral palsy, cerebrovascular accident, Parkinson's disease, brain damage, stroke, and multiple sclerosis. Dysphagia is also common in individuals who have surgical treatment for a pre-existing condition such as throat cancer, tongue and/or mouth cancer, or other conditions that require oral surgery for treatment.
[00065] Oesophageal dysphagia affects a large number of individuals of all ages, but is generally treatable with medications and is considered a less serious form of dysphagia. Esophageal dysphagia is often a consequence of mucosal, mediastinal or neuromuscular diseases.
[00066] Oral pharyngeal dysphagia, on the other hand, is a very serious condition and is generally not treatable with medication. Oral pharyngeal dysphagia also affects individuals of all ages, but is more prevalent in older individuals. Oral pharyngeal dysphagia is often a consequence of an acute event, such as a stroke, brain injury, or surgery for oral or throat cancer. Additionally, radiotherapy and chemotherapy can weaken muscles and degrade nerves associated with nerve and physiological innervations of the swallowing reflex. It is also common for individuals with progressive neuromuscular diseases, such as Parkinson's disease, to experience increasing difficulty in initiating swallowing.
[00067] The consequences of untreated or poorly managed oral pharyngeal dysphagia can be severe, including dehydration, malnutrition leading to a dysfunctional immune response and reduced functionality, and airway obstruction with solid food (asphyxia). Severe oral pharyngeal dysphagia may require that nutrition be provided by tube feeding. Dysphagia can be dangerous as it can often lead to aspiration.
[00068] Aspiration refers to the entry of foreign material into the airway during inspiration and can manifest in many ways. For example, the individual may start to sweat and the face may become flushed. Alternatively, the individual may cough subsequent to swallowing. In "silent" aspiration, there is no easily recognizable clinical sign of bolus inhalation. Aspiration can cause serious health problems including chronic lung disease, aspiration pneumonia, dehydration and malnutrition. As such, dysphagia and aspiration can reduce the quality of life for people of all ages, including not only medical, but also social, emotional and physical well-being. Anatomical Structures Associated with Dysphagia
[00069] There are several anatomical structures that are more likely to be associated with impaired swallowing safety and are indicators of a patient's risk of aspiration. Some of these anatomical structures include, for example, breathing, the jaw, lips, soft palate, tongue, hyoid, epiglottis, larynx, pharynx, and upper esophageal sphincter ("UES"). To determine the sufficiency of swallowing parameters, several parameters can be investigated including, but not limited to, lip closure, jaw closure, tongue fixation, tongue elevation, tongue control, tongue extension, tongue seal, palate seal soft, mouth breathing, nasal breathing, tongue thrust, tongue pressure, laryngeal elevation, hyoid movement, hyolaryngeal excursion, upper esophageal sphincter opening, epiglottis movement, laryngeal opening, vocal cord closure, laryngeal sensation, pharyngeal contraction, pharyngeal fatigue, laryngeal adductor reflex, laryngeal fatigue, stopped breathing, resumption of breathing and sensation of the pharynx. A safe and effective swallowing system requires a bolus to pass quickly and efficiently through the oral cavity and pharynx into the esophagus while bypassing the airway. Breathing
[00070] The respiratory system is not, strictly speaking, part of the swallowing system. However, the interrelationship between the respiratory and swallowing systems is critical to determine an individual's risk for aspiration. There is a preferential coupling of swallowing with the expiratory phase of breathing, both before and after swallowing. Due to the biomechanics of the infrahyoid muscles that connect the base of the tongue and jaw to the hyoid and the hyoid, in turn, to the larynx, these muscles are best placed to work effectively during swallowing when the body is in an exhalation phase. In addition to the biomechanical "assistance" provided to the infrahyoid muscles, exhalation after swallowing also allows any potential debris in the pharynx to be drawn upward toward the mouth and pharynx and away from the airway. Any abnormality of resting breathing such as high and rapid respiratory rate or velocity or chaotic patterns will increase the chance of aspiration.
[00071] Inhalation after swallowing is rarely seen in healthy individuals, except in circumstances involving large volumes of swallowing (eg 100 ml). Inhalation is, however, seen in individuals with dysphagia. Swallows that are not connected on either side by exhalation are generally more likely to exhibit abnormality. Inconsistency in the swallowing-respiratory pattern between swallows within the same individual is also considered irregular.
[00072] Lung volume plays a little-known but still important role in swallowing efficacy. In this regard, pharyngeal transit time is impaired if lung volume is low. Lung volume will be affected by the phase of breathing (inhalation or exhalation) in which swallowing takes place.
[00073] Breathing stops ("apnea") during the act of swallowing as the bolus passes through the pharynx. The duration of apnea increases with age is a common condition among the elderly and is not a consequence of closing the vocal cords. Individuals who have had their larynx removed and their airway separated from the pharynx, making aspiration impossible, continue to exhibit apnea during swallowing. Apnea occurs before vocal cord closure and is highly dependent on vocal cord closure or epiglottic deflection. Most individuals can swallow a 20 ml bolus of food in one motion and maintain apnea throughout that swallow. Segmenting a 20 ml bolus in multiple swallows may indicate an abnormality of function.
[00074] It is a combination of lung function, lung volumes, swallowing respiratory phase coupling abnormality, duration in which the food bolus remains in the pharynx at any point during the swallowing process, and apnea duration variability that best predicts the aspiration of that domain.
[00075] Respiratory function measurements fall into two categories: (a) chest wall function measurements (strain gauges around the rib cage and abdomen); and (b) nasal airflow measurements. Chest wall measurements can be difficult with people who are very ill or those with muscle weakness preventing upright positioning (such as after a stroke). Two different types of nasal cannula have been reported. One variety uses micromanometers to measure changes in air flow direction, while the other (thermistor) detects changes in temperature during inhalation and exhalation. Exhaled air is warmer than inhaled air. The thermistor emerges as the better of the two devices. Patients who are habitual mouth breathers or those with nasal defects will provide unusual data. Patients who require supplemental oxygen through nasal tubes will also be a challenge to use this type of technology. Some investigators have recommended the concomitant use of measurements of nasal airflow and respiratory effort (chest wall). Acoustic analysis of breath sounds and swallowing sounds was also reported. The use of signal processing that can differentiate between the two types of signals may prove beneficial as a screening method to determine the respiratory phase (eg, end-expiratory, inspiratory/expiratory, end-breath, etc.). lip and jaw
[00076] The maxilla (or mandible) facilitates the approximation of the teeth and lips during chewing and swallowing. The lips play a role in removing food from a utensil and channeling a liquid into the oral cavity. Lips are active participants during swallowing, not passively closed during oral propulsion and restraint. There is wide inter-individual variation in the range and duration of lip movement. Conditions where the lips remain open, (eg, muscle weakness of the jaw as seen in cerebral palsy), co-occur with increases in the occurrence of a high arched palate, tongue thrust, and mouth breathing.
[00077] When the lips remain open, the jaw muscles should be evaluated because closing the jaw facilitates closing the lip. Prosthetic devices that artificially lower the palate and improve tongue-to-palate contact have also been shown to improve lip closure, as well as swallowing efficacy and safety. The presence and "fit" of dentures can increase oral transit time, with the muscles of the lips and lower face being recruited to stabilize the dentures. As muscles engage in stabilizing activities, their role in food processing and swallowing is made more complicated and therefore the oral stage is delayed. Increased oral transit time should be anticipated with elderly people who have dentures and particularly those with poor-fitting dentures.
[00078] Closing the jaw brings the tongue into the vicinity of the palate, a biological position necessary for swallowing. The jaw acts as a platform from which the tongue can move independently. During swallowing, the movement of the jaw is minimal, acting as a stabilizer for the tongue. Poor jaw stability will have an effect on the effectiveness and accuracy of the tongue. During mastication and liquid swallowing, tongue and jaw movements are linked, but not necessarily in exact phase.
[00079] During chewing, the presence of teeth provides biomechanical stability for the jaw. Sensory input from teeth and periodontal receptors either promotes or inhibits chewing. For solid chewing, it appears that it is the volume of the particles rather than the particle size that determines the chewing response.
[00080] The jaw has complex connections to the rest of the swallowing mechanism. An open mouth posture (eg, 5 to 6 mm) increases the respiratory rate. The infrahyoid muscles above and below the hyoid bone (supra and infrahyoid) are affected by jaw movement.
[00081] The labial muscles have been investigated using surface electromyography or similar devices at a constructor's level to measure the degree of placement away from the midline. Maxillary function was assessed by electromyography of the muscles used to move the jaw, multiple camera views of jaw merchants, and videofluoroscopy. Of course, the simple observation of open mouth posture and soft facial features suggestive of weakened muscles should not be discounted. soft palate
[00082] The soft palate has a triple role in swallowing: (a) it provides a physical barrier between the nasal and oral cavities; (b) forms a pressurized seal that facilitates a downward pressure gradient during propulsion of food bolus by the tongue; and (c) provides a nasal route to an airway during chewing and during lip and jaw closure during swallowing. The patient's preference for mouth breathing over nasal breathing may indicate some level of breathing disorder involving the nasal passage. It may also indicate a physiological need to decrease "the work of breathing." The open mouth posture helps to reduce the work of breathing. For example, with the increased cardiac load that occurs for healthy people during running, it is easier to breathe through the mouth, lips slightly apart, than nasal breathing with the lips closed. Similarly, with heart conditions, patients can revert to mouth breathing to reduce their breathing work.
[00083] The soft palate houses both fast and slow twitch muscle fibers. Swallowing preferentially activates fast-fatigue and fast-twitch fibers, while speech preferentially activates resistant slow-twitch fatigue fibers. Methods to assess soft palate function for speech are inappropriate for predicting soft palate function during swallowing.
[00084] The palatoglossus muscle is critical for generating a closed pressure system required for effective suction. The palatoglossus muscle has its origin in the subsurface of the soft palate and its insertion on the sides of the tongue. It is responsible for the constriction of the passage between the soft palate and the base of the tongue (glossopalatal or gullet junction). The muscular connections between the soft palate and the tongue confirm the central importance of the tongue function for the safety and efficacy of swallowing. The main role of the soft palate in swallowing is to close the nasal trajectory and, in doing so, assist in the creation of a pressurized region that will preferentially direct the bolus downwards towards the pharynx. Failure to lift and close the soft palate allows for nasal regurgitation and decreases swallowing efficiency. It puts more demand on the tongue to propel the food bolus and on the pharyngeal constrictors to clean the tail without leaving residue.
[00085] Soft palate function can be visualized using, for example, videofluoroscopy and has been most invasively investigated using hook-shaped wire electrodes. The function during speech, such as during the production of the "ahhh" sound does not provide a valid indication of the function during swallowing due to the different activation of fast fatigue fibers (running) and fast contraction for swallowing and slow fatigue fibers ( long distance) and slow contraction for speech. Tongue
[00086] Tongue plays a crucial role in both the oral and pharyngeal phases of swallowing. For liquids, during the oral phase, the tip of the tongue (or blade) is described to rest either behind the mandibular teeth in a "diving" position or more commonly behind the maxillary teeth, contacting the alveolar crest, in the so-called "diving" position. "tilt". Both of these positions occur in healthy individuals, although it has recently been recognized that using a "swallow command" is more likely to activate a tilting posture. The back of the tongue is also raised towards the palate, creating a sphincter-like high pressure zone. A pocket-style chamber is created in the midline along the tongue cleft to house the liquid bolus. In order to transfer liquid food bolus back toward the pharynx, the body and back (back of the tongue) of the tongue move forward along the palate, bending toward the tongue blade. This action acts as a conveyor belt to squeeze the liquid food bolus posteriorly between the dorsal surface of the tongue and the palate.
[00087] The tongue helps in positioning the bolus on the occlusal surface of the molar teeth and in collecting processed food particles and bringing them back to the midline. During chewing, the tongue and jaw cycle in an anti-phase relationship that prevents trauma to the tongue. This mechanical action of a piston-like structure (the tongue) that projects and returns in a cyclic pattern between the opening and closing of the jaw serves to "retreat" the chewed particles in the upper pharynx, where they gather in the valecular space . Liquids also appear to gather in the valecular space if they have been chewed, rather than being squeezed back by the tongue, and also appear to gather in the pharynx by infants during bottle-feeding or breastfeeding and in adults during a continuous sequential swallow, to each swallow after the initial swallow in the series and during the act of drinking through a straw.
[00088] It has been argued that as laryngeal elevation is maintained throughout a series of sequential swallows, there is a reduced risk of aspiration and therefore no biological need to avoid pharyngeal fluid collection. Similarly, in the act of drinking through a straw, the maintenance of apnea during several swallows may mean that there is less risk of aspiration if a liquid food bolus gathers in the pharynx. It is important to note whether single or continuous swallows are being investigated, as the physiology of each is slightly different. Failure to differentiate the distinction from continuous food buns can cause a normal event to be labeled something pathological.
[00089] With both liquid and solid stimuli, the pharyngeal phase of swallowing involves a backward and downward sweep of the tongue. With liquids, the compressed oral tongue again extends to its full length. The body and dorsum of the tongue run backwards and reach the cavity constriction against the posterior palate and then against the constricting pharyngeal walls behind the tail of the bolus. There is some evidence that pharyngeal lumen occlusion is a phenomenon that may involve variable and differential contributions from the base of the tongue and pharyngeal musculature, analogous to lip closure which involves variable contributions from the upper and lower lip, depending on the circumstances. In particular, it has been shown that when the front of the tongue is fixed in a forward position between the teeth, this restricts the degree of posterior movement that can be achieved by the base of the tongue and results in compensation by the posterior pharyngeal musculature in order to achieve the wall constriction from tongue to pharynx.
[00090] Regarding penetration-aspiration risk, there are two primary aspects of tongue function that need to be considered. The first is the ability of the tongue to contain the liquid food bolus in the mouth, preventing it from slipping into the pharynx in an uncontrolled manner. The second is the degree to which the bolus driving forces that are created through tongue-palate and tongue-pharynx-wall contact and pressure generation are adequate to propel the food bolus through the entire pharynx, without leaving post-swallow residues back. For these reasons, a particular interest in measuring the tongue-palate pressure generating capacity has emerged in the literature.
[00091] Tongue function measurement can be done with the use of somewhat invasive measurements. Transducers can be embedded in an acrylic palate with measurements occurring as the tongue sweeps across the transducers or pellets are glued to the tongue using a biomechanical adhesive and tracked using electromagnetic or microbeam X-ray methods. hyoid
[00092] The hyoid bone is an attachment point held in position above by the connection to the floor of the mouth and tongue, below by the larynx and major infrahyoid muscles of the neck, and posteriorly by the middle pharyngeal constrictor. The hyoid moves in an upward (upper) then forward (anterior) direction during swallowing. The previous move is particularly critical. It is linked to posterior tongue-palate pressures, geniohyoid muscle contraction, epiglottic deflection, UES opening and swallowing safety. The connection between the jaw, tongue, and hyoid requires the synchronous movement of this joint to build and stabilize the jaw and hyoid "platform" to allow the tongue "gymnast" to fulfill its role. The pulley-type connections from the hyoid to the larynx continue to facilitate opening the UES. Without hyolaryngeal excursion, UES opening is minimal and residues in the piriform sinus are often seen. When anterior hyoid movement is significantly reduced there is an increased risk of penetration-aspiration.
[00093] Surface electromyography ("sEMG") is a non-invasive way of measuring muscle activity associated with hyoid movement in swallowing. This signal provides a composite picture of muscle activity that is temporarily accurate. Amplitude measurements cannot be meaningfully extracted from these signals.
[00094] Dual axis swallow accelerometry holds promise as a non-invasive technology to capture accurate measurements of hyoid motion in both the temporal and magnitude domains. However, these measurements must be taken after proper filtering to remove motion artifact. Signal processing classifiers hold promise for discriminating aspiration using dual axis geometries. Epiglottis
[00095] The epiglottis is a sheet-like cartilaginous structure that separates the base of the tongue from the vestibule of the larynx. During swallowing, it drops from an upright position to a horizontal position and the tip of the epiglottic sheet bends over the entrance to the airway. However, it does not form an airtight seal. The epiglottis acts more like a stone in a stream, designed to direct the flow around it. Liquid bolus flow is more likely to be turbulent due to its thrust under pressure. In the pharynx, epiglottic deflection directs the bolus to flow around the larynx and into the piriform sinuses. Once the larynx is passed, it can then continue its passage through the UES. These epiglottic movements are most likely the passive results of other structural movements in swallowing, most notably base tongue, hyoid, and larynx movements. There is no non-invasive way to measure epiglottic movement during swallowing. Larynx
[00096] The larynx opens above the pharynx. It is connected to the lungs below through the trachea. The vocal cords, housed inside the larynx, were considered as a valve-type barrier during swallowing to prevent the material from entering the airway (aspiration). However, the vocal cords do not always form an entire seal along their length. In fact, the hyolaryngeal excursion is more important for swallowing safety than the closing of the vocal cords. At that point, poor anterior hyolaryngeal movement is more likely to result in pharyngeal penetration/aspiration and residue.
[00097] Perhaps due to technologies commonly used to assess swallowing such as videofluoroscopy, the assessment focuses largely on movement. In relation to the larynx, the sensation is equally important. Deficiency in both laryngeal sensation and pharyngeal contraction significantly increases the risk of aspiration and penetration for both liquids and pastes. Preserved laryngeal sensation plus poor pharyngeal contraction result in lower incidences of both penetration and aspiration. Thus, it appears that the sensation of the larynx is a critical factor for the risk of penetration/aspiration.
[00098] Penetration is not uncommon in healthy individuals and is more likely to be seen in individuals over the age of 50 and particularly the elderly. In healthy individuals, the penetrated bolus is often spontaneously ejected. The frequency and depth of penetration (proximity to the vocal cords) becomes important over the course of a meal where fatigue is a factor. Single-swallow aspiration does not predict aspiration frequency. For some individuals, only one aspiration in a series of six swallows was noted.
[00099] The hierarchy of laryngeal risk factors for aspiration include: (a) impaired pharyngeal contraction plus impaired laryngeal sensation; (b) impaired laryngeal sensation (laryngeal adductor reflex absent or diminished); (c) reduced closure of false vocal cords; (d) reduced closure of the true vocal cords; and (e) age (eg, over 50).
[000100] As for the assessment, although videofluoroscopy provides the best known method of documenting the penetration, aspiration and movement of the pharynx, the sensory test of the laryngeal region emerges as a necessary co-assessment in the literature. As noted above, reduced laryngeal sensation is a primary risk factor for laryngeal aspiration. Currently, technology such as endoscopic evaluation of endoscopic fiber optic evaluation of swallowing with sensory testing ("FEESST") is used for this purpose. However, even with experience in conducting the procedure, there is only moderate inter-rater reliability, projecting care in interpreting the results. Upper Esophageal Pharynx and Sphincter
[000101] The pharynx is a funnel-shaped tubular cavity, bordered anteriorly by the base tongue, the epiglottis and the posterior surface (arytenoid) of the larynx/trachea. The posterior and lateral walls of the pharynx are made of a basket-weave arrangement of muscles oriented vertically, horizontally, and obliquely. The pharyngeal constrictor muscles (upper, middle, and lower) wrap horizontally around the circular lumen of the pharynx.
[000102] Anatomically, it is important to note that the pharynx contains pockets that can collect bolus residues. The valecular space is a pocket along the anterior wall of the pharynx, between the base of the tongue and the epiglottis. The piriform breasts are pockets at the bottom of the pharynx, which sit on both sides, above the UES. The UES itself (or pharyngoesophageal segment) is a ring of muscle that incorporates the cricopharyngeal muscle that is typically contracted and closed at rest. In healthy swallowing, EMG studies show that cricopharyngeal muscle activity is inhibited just before opening the UES. This is primarily attributed to the biochemical effects of suprahyoid and infrahyoid muscle contraction on the front wall of the sphincter. Opening the UES creates a negative pressure zone, which can create a suction-like effect to facilitate movement of the bolus into the esophagus, although the literature is somewhat divided on whether a hypopharyngeal suction pump exists.
[000103] The transport of the bolus through the pharynx occurs primarily as a result of the tongue propulsion (drive forces) and the shortening of the pharynx, which occurs through the contraction of the suprahyoid, infrahyoid and vertically oriented pharyngeal muscles. Contraction of the pharyngeal constrictor muscles creates a peristaltic-type wave of lumen closure that travels down the tail of the bolus through pharynx x. Among these two actions (shortening and constriction), the shortening is more important for the efficient transport of bolus and for the safety of swallowing.
[000104] There do not appear to be currently any valid and reliable non-invasive measures of pharyngeal bolus release and transport. Hyoid and laryngeal motion measurements will provide reasonable proxy information regarding pharyngeal shortening while posterior lingual pressure measurements may provide reasonable information regarding the bolus driving forces that appear to be primary factors for pharyngeal bolus release. Dysphagia Detection
[000105] It is estimated that approximately 80% of patients with dysphagia remain undiagnosed. A primary reason for the large number of misdiagnoses is that general health professionals' offices and wards are relatively ill-equipped to diagnose these types of conditions. In many cases, the tests available at these sites are either expensive, time-consuming, invasive, only available in specialized centers, and/or expose the patient to ionizing radiation. For example, the current gold standard diagnosis for dysphagia and aspiration is videofluoroscopy, in which a patient ingests barium-coated material and a video sequence of radiographic images is obtained using x-rays. This test is not only invasive and costly in terms of time and labor, but it also exposes the patient to potentially harmful ionizing radiation.
[000106] Fiber optic endoscopy, pulse oximetry, cervical auscultation and swallowing accelerometry are just a few examples of additional tests used to detect dysphagia/aspiration. Fiberoptic endoscopy is another invasive technique in which a flexible endoscope is inserted transnasally into the hypopharynx. It is generally compared to modified barium swallowing in terms of sensitivity and specificity for identifying aspiration. Pulse oximetry is a non-invasive adjunct to bedside aspiration assessment, and cervical auscultation involves listening to breathing sounds near the larynx through a laryngeal microphone, stethoscope, or accelerometer placed in the neck. Cervical auscultation is generally recognized as a limited but valuable tool for detecting aspiration and assessing dysphagia in long-term care.
[000107] Swallowing accelerometry is similar to cervical auscultation, but has mandatory digital signal processing and artificial intelligence as discrimination tools, rather than trained clinicians. Accelerometry showed moderate agreement with videofluoroscopy in identifying the risk of aspiration, while signal magnitude was linked to the extent of laryngeal elevation. However, prior art swallow accelerometry only provides limited information on the normal classification of "dysphagic" swallows and does not provide broader information about the patient's clinical situation.
[000108] Technologies that target the tongue and respiratory function particularly are needed for the detection of dysphagia and/or related aspiration. Lung function can be assessed as part of routine medical appointments using validated technologies already found in the physician's office (eg, spirometer). Individuals who have abnormal spirometric results for total lung capacity and inspiratory capacity should be asked about their ability to swallow food, liquids, and medications (eg, with the use of EAT-10). Resting respiratory rate measurements can be made by observation, counting the number of breaths per one minute interval. This is a standard medical observation, but it has not been previously linked by physicians to swallow-breather coordination.
[000109] Dual axis accelerometry has been identified as a screening tool for further development to determine normal swallows from abnormals. This technology has been used for the assessment of children, young, middle-aged and healthy individuals. Both healthy and dysphagic individuals were evaluated. The technique has been validated against videofluoroscopy and endoscopy. This technique seems to be useful both for quantifying hyolaryngeal movement during swallowing and for detecting aspiration through the use of signal processing classifiers.
[000110] Technologies that provide information about language function are also needed. Tongue is identified as a critical element for effective swallowing. Devices that allow strain gauges to be placed on an acrylic palate (such as a mouthguard) provide valid information about tongue-to-palate contact and palate pressure timing. This type of device does not lend itself to use in medical surgery although due to the individuality of the palatal shape and the time and costs associated with acrylic palate production and sterilization requirements. Air-filled pressure bulbs provide an alternative, recording intraoral pressure timing and amplitude, similarly to pressures experienced by the bolus, even in the absence of contact between the tongue and the complete palate. However, the use of bolus-sized air-filled bulb systems to measure pressures should likely be restricted to the context of saliva swallows, as the combination of a bulb and bolus can exacerbate safety risks in individuals with dysphagia .
[000111] Surface electromyography ("sEMG") of the muscles under the chin and along the neck can provide information regarding the timing of muscle contraction and, by proxy, structural movement. However, this technology is not sensitive enough to provide information regarding the contraction of specific muscles responsible for anterior hyolaryngeal movement, which has been identified as a major risk factor for aspiration. Additionally, sEMG amplitudes cannot be easily interpreted due to a variety of signal positioning and signal dampening factors that exist across individuals. The time associated with electrode application and training in the use and interpretation of this technology is likely to be a major barrier for most physicians in general practice or geriatric specialty. Although reduced laryngeal sensation has been identified as a risk factor for aspiration, the ability to measure this non-invasiveness does not currently exist.
[000112] In view of the shortcomings of prior art devices for diagnosing dysphagia, it could be advantageous to develop improved methods for diagnosing and detecting dysphagia that are flexible, light weight, non-invasive, cost effective, and can cooperate with electronic technologies. Improved Dysphagia Diagnosis
[000113] Applicants have developed innovative devices and methods to detect parameters associated with swallowing dysfunction and diagnose dysphagia and/or aspiration. In a general embodiment, the present description provides sensors and databases that cooperate to diagnose a swallowing disorder. The database can be a database that has a statistically significant amount of data derived from the swallowing profiles of a large number of healthy and dysphagic patients. The sensors can be known apprehension sensors such as videofluoroscopy ("VF"), electromyography ("EMG"), etc. , or may be the enhanced sensors described in this document.
[000114] In one embodiment, and as illustrated in Figure 1, the present description provides an intelligent sensor device 10 that can be used for dysphagia analysis with multiple parameters. Device 10 includes, for example, a flexible substrate 12 to which various electronic elements are added. In that regard, substrate 12 may include a microcontroller 14 with communication capabilities, an antenna 16 and printed sensors 18. Devices 10 may be placed directly on an individual's skin for purposes of detecting non-invasive parameters associated with a swallowing profile. of the patient (eg, acoustics, movement, EMG, etc.), which may be indicative of an underlying swallowing disorder.
[000115] In one embodiment, the devices 10 are wearable by an individual and are placed directly on the neck, throat or surrounding areas, to detect, for example, epidermal vibrations, swallowing sounds, pressure changes, etc. that occur during swallowing. As such, devices 10 can include a layer of adhesive (not shown) for adhering devices 10 to the patient. The patch must be approved by the Food and Drug Administration ("FDA") and must be removable from the skin, while also having enough adhesive power to remain in place during diagnostic testing. One skilled in the art will also appreciate that the devices 10 need not be adhered using adhesive, but can instead be secured using other means such as rubber bands, strips, etc.
[000116] The devices 10 have an equal amount of advantageous physical properties. For example, the devices 10 are flexible and comfortable to conform to a patient's neck, throat, surrounding areas and are thin, flat and flat for discretion when in use. It is important that devices 10 are also light weight to avoid interfering with measurements when in use. Due to these advantageous physical properties, it is possible to manufacture devices 10 that are low cost but are produced in high volumes. Devices 10 can be manufactured using roll-to-roll manufacturing processes, as schematically depicted in Figure 3 and as will be discussed further below.
[000117] The materials used to manufacture the devices 10 of the present description can be of relatively low cost. For example, devices 10 can be manufactured using polymers and printed electronic components. Polymers typically include, for example, polyethylene naphthalate ("PEN"), polyethylene terephthalate ("PET") and/or similar polymers and provide devices 10 with reduced manufacturing flexibility and costs.
[000118] Devices 10 may also be manufactured using printed electronic component technologies. As mentioned above, the electronics of devices 10 include, for example, a microcontroller 14, an antenna 16, and at least one printed sensor 18. The printed sensors 18 can detect any number of non-invasive parameters that are associated with a swallow profile. of a patient and may be indicative of a probability that the patient has underlying swallowing dysfunction. For example, the printed sensors 18 can detect pressure, sound waves, acceleration, velocity, distance, electrical current or voltage, electromagnetic radiation, temperature, etc. In one embodiment, the printed sensor 18 is an accelerometer. In another embodiment, the printed sensor 18 is a microphone. In another embodiment, the printed sensor 18 is a thermometer. As used herein, "acoustic" includes at least vibration, sound, ultrasound and infrasound.
[000119] Devices 10 can be either reusable or disposable. In an embodiment where devices 10 are reusable, devices 10 must be able to withstand sterilization conditions when devices 10 are cleaned and sterilized between uses by different patients. In an embodiment where devices 10 are disposable, it is important that the cost of devices 10 be low enough that it is feasible and economical to dispose of devices 10 after just one use or after a limited number of uses by the same patient. In one embodiment, devices 10 are disposable. In another embodiment, the devices 10 can be sold at a cost of about fifty cents to about two dollars. In one modality, the 10 devices can be sold for a dollar.
[000120] The antenna 16 of the devices 10 can act as a transmitter and/or receiver to send or receive electronic signals. For example, in one modality, antenna 16 acts as a transmitter. In such an embodiment, device 10 can be placed on a patient's neck/throat and used to detect at least one parameter associated with the patient's swallowing profile. Once the swallow parameter has been measured, the antenna 16 can act as a transmitter to wirelessly send the measured parameter data to a processing device 20 to record and evaluate the data. Alternatively, antenna 16 can act as a receiver to receive electronic signals from a transmitter or processing unit 20.
[000121] The person skilled in the art will realize, however, that including the transmit/receive functions in devices 10 can be somewhat costly and may prevent the disposable nature of devices 10. Therefore, to reduce the costs associated with devices 10 and, in another embodiment, as shown in Figure 2, devices 10 can be wired to a second device 22 that can transmit an electronic signal to a processing device 20. The second device 22 can be any electronic device that can send and/or receive electronic information such as, but not limited to, an iPod, an iPhone, an iPad, a cell phone, a personal digital assistant ("PDA"), a pager, a short message service system ("SMS" ), a Blackberry, etc. In this mode, the devices 10 obtain the measured parameters and wire the measured parameter to the second device 22, which transmits the measured parameter to the processing unit 20.
[000122] As such, one skilled in the art will appreciate that devices 10 can communicate data via wired connections or wirelessly. Any wireless communication described in this document will be understood to include any wireless communication path (e.g., form of energy) including, for example, radio frequency, infrared light, laser light, visible light, acoustic energy, radio waves , etc. In one modality, wireless communication is Bluetooth technology. In another embodiment, wireless communication is a cell phone network.
[000123] The person skilled in the art will understand that the processing devices 20 of the present description are constructed and arranged to cooperate with software that is configured to perform many of the processes discussed in this document. For example, the software can be configured for data acquisition and gathering, database updating, data point evaluation and comparison, data storage and wired and wireless data transmission, among others.
[000124] As briefly mentioned above, the sensors of the present description need not be devices 10 and can be any other sensor known in the art and useful to detect parameters associated with a patient's swallowing profile. In the case where known sensing devices are used, a swallow signal (eg swallow sounds, pressures and velocities, etc.) is generated by the known sensing device and then output to either the compiled database described above or an interpretive algorithm which can evaluate the sensor output. Known devices that can be used to measure a swallowing signal may include, but are not limited to, videofluoroscopy, acoustics, acceleration, velocity, distance, electromyography, mechanical myography, electrical myography, thermography/temperature, or combinations thereof. In this mode, the signal generating device (EMG) actually takes and processes the measurement. This is distinguishable from the use of devices 10 of the present description, where devices 10 measure the signal and transmit the signal to a signal processing unit that can be remote to device 10 such as, for example, an algorithm that monitors. finds on a remote server. Going forward, a "sensor" discussed herein may be either the sensors 18 of device 10 or sensors built into known devices such as EMG, unless otherwise specified.
[000125] In use, a sensor is placed on a patient's skin and is used to obtain swallow data from the patient's swallow profile. These data may include, as discussed above, the acoustics, velocity, and temperature of the patient's single swallow mechanics. Epidermal vibrations, swallowing sounds and pressure changes are just a few examples of data detected by sensors that form the acoustic profile of the patient's swallowing. The sensors can be used in a variety of ways to obtain measurements related to a patient's unique swallowing characteristics and to characterize and predict swallowing disorders.
[000126] For example, in a first modality, the sensors can be used in combinations with a device to emit electronic signals corresponding to a characteristic of a patient's swallowing profile to a pre-existing database for comparison with dysfunction data swallowing problems and to diagnose a potential swallowing weakness. In this regard, a patient's swallowing profile can be calibrated and compared against a comprehensive database, which can indicate any dysfunction in the patient's swallowing. Thus, the combination of sensor and database can provide an accurate diagnosis of the nature of the patient's swallowing difficulty and a recommended therapy. As a result, the complete system, including sensors and database, can be used in swallowing rehabilitation as biological feedback.
[000127] In another embodiment, the sensors in combination with the devices can be used to emit signals that correspond to at least one swallow parameter of a patient's swallow profile that is fed to an interpretive algorithm, which can evaluate the data for swallowing disorders. Thus, in the absence of a database, measurements obtained using the sensors can be used to build an interpretive algorithm that models the probability of underlying swallowing dysfunction and dysphagia risk.
[000128] Both the database and the algorithm are used to record and assess the swallowing profiles of many healthy patients and many dysphagic patients. By shaping the swallowing profiles of healthy patients, "normal" ranges for different parameters associated with swallowing can be determined. By modeling the swallowing profiles of dysphagic patients, it is then possible to determine how outside of the normal ranges dysphagic patients are and, alternatively, which constitute the "normal" ranges for different parameters associated with a dysphagic patient's swallowing profile.
[000129] The pre-existing database can be located anywhere and may include information obtained over many years that refers to dysphagia and aspiration. The database can be any type of database and can be located in close proximity or remote to the patient. For example, the database may be a computer database or processing device located at or near a patient testing device. Similarly, the database may be located in the same building as the patient and patient testing device. Alternatively, the database may be a central database that is located remote from a patient testing device. Such a central database can gather data from a remote user site that has measured parameters and specific data for any number of patients. The person skilled in the art will realize that any database that can cooperate with a processing hardware and software can be used. Depending on where the patient testing is performed, adjacent and/or remote locations could be, for example, a healthcare professional's office, a doctor's office, a clinic, a hospital, a nursing facility, a clinic specialist or a long-term care facility. In one modality, the remote location is mobile. Such mobile location refers to, for example, a home health care provider, a clinic on wheels, an aerial care clinic, etc. Regardless of its location, the database can be used by one patient testing site or it can be used by more than one patient testing site.
[000130] As mentioned above, the database may include information obtained over many years that refers to both healthy patients and patients who have swallowing disorders such as dysphagia and aspiration. The database can be comprised of data obtained from measurements taken with, for example, videofluoroscopy ("VF") tests performed over several years and can include data from a variety of healthy and dysphagic patients.
[000131] In one modality, the data contained in the database has been accumulated over a time period of at least 5 years or at least 10 years or at least 20 years. In another embodiment, data contained in the database were obtained from a patient population of at least 500 patients or at least 1,000 patients or at least 3,000 patients or at least 5,000 patients. Regardless of the number of tests performed or patients tested, the database must include a statistically significant dataset that is of sufficient size, scientifically based, and contains differential/relative measurements of absolute values. As the database is already established and the devices 10 can be relatively inexpensive to manufacture, it is relatively inexpensive to provide such a system, for example, to a general healthcare professional for use in their office.
[000132] As used above, the swallowing profiles of healthy patients are recorded and evaluated to serve as a reference comparison to the swallowing profiles of potentially dysphagic patients. Various parameters associated with swallowing profiles may be included in the database. For each parameter (eg time of flight) there can be, for example, at least 5,000 measurements. Plotting for each of the measurements on the same curve gives a Gaussian distribution of a small number of possible malfunctions. That is, 5,000 measures from dysphagic patients, representing 25 underlying conditions, can be "translated" into three or four discrete Gaussian curves. There may also be, for example, two methods for recording healthy reference data: a) really healthy during the initial videofluoroscope measurement; and b) healthy "composite", in which it can be assumed that, for example, for a patient with head/neck cancer, the dysfunction is apparent in the neck, leaving, for example, the functioning of the lip seal as that of a normal individual. . Using a two-part method can considerably increase the robustness of healthy data contained in the database.
[000133] In addition, the database can be a continuously changing database in which new data points (eg swallow profile measurements) are entered into the database after collection. In this way, the database will continue to grow in number and variety of data points and, as a result, will continue to improve in its accuracy of prediction/diagnosis of swallowing dysfunction. As such, database improvement continually improves the evaluation methods of the present description, where the database uses gathered information to "learn" even more about potential dysfunctions and disorders. Simply by continually providing additional data points, the database can "learn" more about normal variants for swallowing disorders and disorders.
[000134] Similarly, the more information contained in the database, the more "intelligent" the database becomes. In this regard, if the database information includes information related to a patient's pre-existing condition, the database and/or algorithm may be able to better determine whether the patient's swallowing characteristics are normal. For example, if a patient has previously undergone oral surgery to remove a cancerous portion of the patient's tongue, the patient will have "normal" swallowing characteristics that may be drastically different from a patient who has not had a portion of their tongue removed. By evaluating the sensor output and comparing the sensor output to the data, the assessment can describe that the patient's swallowing characteristics, although representative of a swallowing dysfunction, are still "normal" for a patient who has undergone such surgery.
[000135] Once the parameters associated with the patient's swallowing profile are measured, the electronic data is transferred via a wired connection or wirelessly to a processing device. For example, device 10 can send a measured parameter to processing device 20 via an electronic signal from a second device 22. Sensors can transmit the signal via a wired or wireless connection to a device that can process the signal (eg a computer, any processing device, etc. ). The signal processing unit can then compare the measurement to existing data in the database or use an interpretive algorithm to evaluate the data. Modalities that include the interpretive algorithm can be based on 90° double acceleration measurements.
[000136] A processing unit can evaluate sensor output in a number of ways based on the capabilities and configuration of the processing unit's software. The assessment can, for example, translate the signal output into a significant value or data form or determine whether dysphagia exists or associated the signal output to a numerical value associated with a predetermined swallowing dysfunction. In one embodiment, the assessment compares the sensor output (eg, measured parameter) to disturbance and dysfunction data already in the database. Software associated with the database can categorize the sensor output into any number of categories already established in the database in relation to known dysfunctions and disorders. Software associated with the database can also cause an interpretive algorithm to interpret the sensor output and characterize any potential patient dysfunction or disorder. Evaluation by the processing device can take up to 10 minutes or can be substantially instantaneous.
[000137] As the database contains a large amount of statistically significant information, the comparison of measured parameters with known data indicative of dysfunctions and disturbances is a cost-effective and time-effective process. The assessment takes place in a validated, sensitive, specific and reliable way. Assessment can occur with or without clinician-specific variability and can be simplified for use by non-specialists. Additionally, the assessment can take place in a patient database or in a central database that can gather data from a user site or any number of patient databases.
[000138] An example of the assessment database is a determination of whether the specific parameter measured from the patient's swallow profile is within a normal range or is higher or lower than a normal range and whether the ranges can be indicative of a swallowing disorder or disorder. This first assessment results in a first issued assessment that is representative of, for example, a high or low reading or a positive or negative indication of a swallowing disorder or disorder. The first assessment issued may be in various forms easily understood by the patient including, but not limited to, a printout of the assessment results, a color-coded or flashing light-emitting diode ("LED"), an audible output, or any other electronic signal which may be representative of the results of the first assessment.
[000139] For example, in one modality, the results of the first assessment can be a printout that displays normal quantitative or qualitative measurement ranges for certain swallowing parameters, along with patient-specific measurements for the same swallowing parameters. In this regard, the patient and/or healthcare provider will be able to easily determine what the normal ranges are for the parameter and whether the patient is within these ranges or above or below the ranges.
[000140] After a result of the first evaluation to be established, the processing device and/or a second processing device can still evaluate the results of the first evaluation. In an embodiment where further evaluation takes place in a second processing device, the second processing device also cooperates with a patient database or a central database. After the first results are further evaluated, the processing device issues a second result(s), which is the product of the additional (or second) evaluation. The shape of the second output produced can be the same or different from the shape of the first output output.
[000141] In one modality, the result of the first evaluation can be an electronic signal that can be sent to a different processor for further evaluation (eg a second evaluation). At the second assessment, another issue (for example, a result of the second assessment) may be issued to the patient. For example, the first assessment on a first processing device may result in a result of a first assessment which is an electronic signal that indicates the presence of dysphagia based on a swallow pressure of a specific value. The first processor can pass the value to a second processor for a second evaluation. In the second assessment, the database can compare the electronic signal representing a specific pressure value to known pressure ranges representative of certain types of dysphagic dysfunctions (eg mechanical, biomechanical, neurological, etc.) and output the specific type of dysfunction that the patient is suffering from. The specific type of dysfunction, then, could be the second outcome and the product of the second assessment.
[000142] In another modality, additional assessment can be performed using the results or the first and/or second assessment and another database that contains information related to therapy recommendations for specific swallowing disorders. The database can include any known swallowing disorders and disorders and correlate the disorders and disorders with treatments that can be used to treat the disorder/disorder and/or alleviate the symptoms associated with it. For example, in the previous modality, where the first result is an indication of dysphagia and the second result is a specific type of dysfunction, a third assessment can occur in any of the first two processing units or in a third processing unit , in which an electronic signal of the type of dysfunction is evaluated and compared to the therapy database to determine an optimal therapy regimen. Once the therapy or therapies are determined, the third output of a therapy recommendation can be issued in a form that is easily understood by the patient and/or healthcare provider.
[000143] In a modality where therapy recommendations are provided, the therapy recommendation may be one less of products, tools, or services tailored to the patient based on their diagnosed dysfunction/disorder. A recommended therapy plan might include, for example, at least two of physical therapy, occupational therapy, speech therapy, nutritional formulation, diet modification, oral health enhancement, electrical stimulation, biological feedback, and pharmacological treatment. Diet modification can include at least one of increased cohesion, increased thickness, trigeminal stimulants, swallow stimulants, food temperature modification, food texture modification, and food sensory modification. Oral health enhancement can include at least one of mouthwash, toothpaste, probiotics, saliva stimulants, toothbrush, floss, and tongue brushing. One of skill in the art will appreciate that therapy recommendations are not limited to those described herein and may include any therapy known to treat swallowing disorders or disorders.
[000144] The person skilled in the art will understand that the databases of the present description can be updated. Updates can occur on a continuous basis or at predetermined times (eg, quarterly or annually). Updates may be by subscription and may be received via one of the internet, physical media and the internet and physical media. Physical media can be at least one of a compact disc, DVD, flash drive, tape, or combinations thereof. Regardless of whether the database is a patient database located at or near the site of patient use or a central database located in a remote location, all databases described in this document can be updated.
[000145] As briefly mentioned above, a processing unit can output the first and/or second results in any manner that can be easily understood by a patient. For example, the first, second and third results may be visually displayed on a display of the processing unit 20 or the second device 22 or by means of an illuminated light-emitting diode ("LED"), etc. The first, second and third results can also be output by means of an auditing medium such as, for example, loudspeakers or by means of textured means such as, for example, Braille. The output can be one of an electronic signal; a diagnosis of disorder/dysfunction; at least one qualitative measure of the disorder/dysfunction; at least one quantitative measure of the disorder/dysfunction; a mechanical dysfunction; a biomechanical dysfunction; a neurological dysfunction; a qualitative or quantitative measure of a mechanical, biomechanical, or neurological dysfunction; a qualitative or quantitative measure of dysphagia; a weakness in swallowing; a characteristic of poor swallowing; an indication of poor lip seal during swallowing; a classification of a swallowing disorder; a classification of a disorder; a classification of a type of dysphagia; qualitative or quantitative measure of the classification of a swallowing disorder, classification of a disorder or classification of a type of dysphagia; a diagnosis of anatomical structures that do not function within normal parameters; a qualitative or quantitative measure of various parameters of one or more functions of one or more anatomical structures; and a risk of sequelae from the disorder. In another embodiment, the first, second, and third outcomes can be in the form of a visible or audible question such as, for example, "does the patient have a disorder/dysfunction "
[000146] In one modality, the first, second and third results are an indication of a risk of sequelae of a disorder. The sequel can be at least one of aspiration pneumonia, chronic obstructive pulmonary disorder ("COPD"), malnutrition, sarcopenia, dehydration, orthostatic hypotension, functional decline, falls, pressure ulcers, urinary tract infections, skin infection, conditions of specific nutrient deficiencies, airway obstruction, coughing, anxiety and depression. When present, the sequel may require at least emergency care, hospitalization, a visit to a doctor's office, medical treatment, and medication.
[000147] Using the combinations of sensors, the databases and/or algorithms of this description provide the diagnosis of various disorders and swallowing disorders. In addition to the disorders and dysfunctions described above, the present description also refers to any pathologies, syndromes or diseases that can be diagnosed or classified using the measured parameters. For example, the disorders can also include at least one arthropathy, temporal mandibular dysfunction, colic, irritable bowel syndrome, irritable bowel disorder, at least one bowel disorder, and at least one pathology, syndrome, disorder or disease that can manifest dysphagia.
[000148] Additionally, providing the combinations of sensors, databases and/or algorithms of this description also allow the early detection of various disorders and swallowing disorders. Early detection provides early treatment, which can provide reduced medical care costs, reduced risk of dysfunctions and/or disorders, and reduced symptoms of existing dysfunctions and/or disorders. Medical care costs can be reduced simply by reducing the number of patient emergency room visits, hospitalizations, doctor visits and/or medical treatments, depression, pain, anxiety, etc. and reduction in dysphagia sequelae (eg COPD, aspiration pneumonia, malnutrition, etc.).
[000149] Early treatment can reduce the risk of conditions including, for example, malnutrition, dehydration, blocked airways, etc. It is important to reduce such conditions due to the fact that they can lead to additional health concerns. For example, poor nutrition can lead to, among other things, suppression of the patient's immune system, sarcopenia, muscle dystonia, and worsening dysphagia. Dehydration can lead to, among other things, Persian appetite, fatigue or tiredness, increased heart rate and breathing, increased body temperature, muscle cramps and nausea.
[000150] The devices 10 of the present description can be manufactured using a hybrid integration to realize an optimal cost-performance compensation. printed electronic components are generally low cost and use lower end elements. printed electronics have long switching times, low integration density, large areas, flexible substrates, simple fabrication and extremely low fabrication costs. In contrast, conventional electronic components are generally higher in cost and use higher end elements. conventional electronics have extremely short switching times, extremely high integration density, small areas, rigid substrates, sophisticated manufacturing and high manufacturing costs. The devices 10 of the present description, however, can use elements of both printed and conventional electronic components to achieve optimal cost-performance compensation. Hybrid device integration 10, for example, can use printed devices (sensors, batteries, conductor lines, etc.) for lower costs, as well as silicon devices (embedded computing) for high performance.
[000151] Devices 10 can be prepared using a roll-to-roll process, as shown in general in Figure 3. Roll-to-roll processing is the process for creating electronic devices on a roll of flexible plastic or sheet metal. Roll-to-roll processing is similar to the process used for newspaper printing and is still an evolving technology that could prove very useful in the future for manufacturing many devices at a fraction of the cost of traditional semiconductor manufacturing methods.
[000152] An important advantage of the devices and methods of the present description is that the system will link the measurements obtained by the sensors to an underlying swallowing dysfunction (a biomechanical failure) and not to an underlying disease, which has probably already been diagnosed by a health professional. health care. As a result, the underlying biomechanical failure can be assessed and treated, which can, in turn, reduce a patient's symptoms of dysphagia and aspiration. In this regard, knowledge of biomechanical failure will allow a more effective treatment of dysphagia and aspiration through the recommended use of specific products, tools and services whose properties are linked to the diagnosed mechanical dysfunction. In one embodiment, devices 10 can be manufactured to be integrated and disposable and are convenient, easy to use, and provide quick results.
[000153] The person skilled in the art will understand that the devices 10 of the present description are not limited to the methods and uses described herein. Instead, devices 10 can be used in any application where the use of devices 10 is beneficial. Other applications include, for example, smart packaging, low-cost radio frequency identification ("RFID") transmitters, rolling displays, flexible solar cells, disposable diagnostic devices, printed batteries, wearable devices/smart textiles and various other applications for sensor. For example, the present technology can be used to fabricate plastic sheet smart RFID apprehension tags that act as sensors, use a thin-film battery, and use printed electronic components for communication. Additionally, the devices 10 of the present description can be used as multiple sensor platforms on the plastic sheet, where the sensors act as, for example, capacitive volatile organic compound sensor, resistive temperature sensors, a capacitive humidity sensor, etc. .
[000154] It should be noted that various changes and modifications to the currently preferred modalities described in this document will be noticed by those skilled in the art. Such changes and modifications may be made without departing from the spirit and scope of the present subject matter and without diminishing its intended advantages. It is, therefore, intended that such changes and modifications are included in the appended claims.

权利要求:
Claims (9)
[0001]
1. Swallowing tester characterized in that it comprises: a sensor device (10) consisting of a flexible substrate (12) and a printed sensor (18) designed for the detection of a number of non-invasive parameters that are associated with a patient swallow profile, wherein the flexible substrate (12) and the printed sensor (18) are wrapped in a plastic sheet; and a processing device (20), the processing device (20) being configured to communicate with the sensor device (10), for accepting a respective sensor output and for evaluating the sensor output to obtain a result. , in which the sensor output evaluation comprises comparing the sensor output to known swallowing disorders or disorders stored in a central patient database containing statistically significant data related to at least one swallowing profile and being remotely located from of the sensor device (10) and the processing device (20), wherein the processing device (20) is further configured to output the result.
[0002]
2. Swallowing test apparatus according to claim 1, characterized in that the sensor device (10) further comprises a printed microcontroller (14).
[0003]
3. Swallowing tester according to claim 1 or 2, characterized in that the flexible substrate (12) comprises a polymer selected from the group consisting of polyethylene naphthalate ("PEN"), polyethylene terephthalate ("PET" ) and their combinations.
[0004]
4. Swallowing tester according to any one of claims 1 to 3, characterized in that at least one printed sensor (18) is configured to detect pressure, sound waves, acceleration, velocity, distance, electric current, electrical voltage, electromagnetic radiation, temperature and their combinations.
[0005]
5. Swallow test device according to any one of claims 1 to 4, characterized in that the plurality of swallow profiles in the database includes both healthy patient and dysphagic patient swallow profiles.
[0006]
6. Swallowing tester according to any one of claims 1 to 5, characterized in that the sensor device (10) comprises an antenna (16) which is designed to act as a transmitter to send wirelessly the measured parameter data to the processing device (20).
[0007]
7. Swallowing tester according to any one of claims 1 to 6, characterized in that the device comprises a second device (22) capable of transmitting an electronic signal to the processing device (20), in which the second device (22) is wired to the sensor device (10).
[0008]
8. Swallowing tester according to claim 7, characterized in that the second device (22) is an electronic device capable of sending/receiving electronic information such as an IPod, an IPhone, an iPad, a cell phone , a personal digital assistant, a pager, a short message service system, or a Blackberry.
[0009]
9. Swallowing tester according to any one of claims 1 to 8, characterized in that the sensor device (10) comprises an acceleration sensor being a dual axis acceleration sensor.

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法律状态:
2018-12-18| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

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2019-11-05| B25A| Requested transfer of rights approved|Owner name: SOCIETE DES PRODUITS NESTLE S.A. (CH) |

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2019-12-17| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

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2021-06-15| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2021-07-27| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 27/01/2012, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

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申请号 | 申请日 | 专利标题

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US201161437051P| true| 2011-01-28|2011-01-28|

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US61/437,051|2011-01-28|

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PCT/IB2012/000218|WO2012101514A2|2011-01-28|2012-01-27|Apparatuses and methods for diagnosing swallowing dysfunction|

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