ZMPCZM019000.11.04 Evidenced based guidelines for Migrane Headache : Behaviou...painezeeman
The document summarizes evidence from studies on behavioral and physical treatments for migraine headaches. It finds that relaxation training, thermal biofeedback plus relaxation training, EMG biofeedback therapy, and cognitive-behavioral therapy led to statistically significant improvements in headache frequency and severity, with effect sizes ranging from moderate to large. Combining cognitive-behavioral therapy with thermal biofeedback produced more modest improvements. Studies of acupuncture for migraines showed mixed results, with some finding it more effective than sham treatments and others finding no difference compared to sham interventions.
The document provides an overview and instructions for using the IncontiMed Checklist software. It describes how to select a patient, administer a checklist to collect patient responses, generate reports on completed checklists, and manage patient records and settings. The software is designed to collect self-reported information from patients on incontinence experiences and supports customization of report templates, password protection, and displaying initials instead of names for patient confidentiality.
The document provides an overview and instructions for using the Headache Checklist software. It describes how to select a patient, administer the checklist questions, generate reports, and manage patient records and settings. The software allows clinicians to collect self-reported headache information from patients and create standardized reports in a HIPAA-compliant manner. It can be used as an assessment tool alongside a clinical evaluation to help evaluate headache complaints.
1. This document provides instructions for using NeuroGraph software to conduct biofeedback sessions. It describes how to select a patient, choose a protocol, attach sensors, monitor signals in real-time, set goals and provide feedback.
2. The user's guide explains how to review session data, including graph displays, replay functions, and report generation. Customization options allow modifying graph types, colors, and other display settings.
3. Advanced features include creating schedules with multiple trials, setting trial properties, and exporting data. The guide provides details on protocol customization, system settings, and other administrative functions for configuring and managing NeuroGraph software.
This document provides a user's guide for NeuroGames software. It describes how to install and set up the software, select protocols, create and edit protocols, manage patients, run protocols, view reports and save session data. Key steps include checking the instrument settings, selecting or creating a protocol, selecting a patient, running the protocol, and viewing saved session reports. The guide also describes options for password protection, confidentiality settings, and alternative protocol types including jungle and star light games.
ZMPCZM019000.11.03 EMG based evaluation & therapy concept for pelvic floor Dy...painezeeman
(1) EMG is used to directly measure pelvic floor muscle function and innervation for evaluating and treating dysfunctions like incontinence. (2) A 4-channel EMG system measures the pelvic floor and surrounding muscles during standardized tests to analyze coordination and identify issues. (3) Biofeedback training then focuses on re-educating the pelvic floor muscle through isolated activation exercises and integrating it into whole body movements and daily activities. (4) Retests assess changes in muscle activation, endurance, and coordination from the training.
This document provides an introduction to kinesiological electromyography (EMG). It discusses the basics of EMG including:
- The origin of the EMG signal from motor unit action potentials generated by muscle fiber membranes.
- How the EMG signal is detected using surface electrodes and processed to analyze muscle activation patterns.
- Key concepts for interpreting the EMG signal including recruitment, firing frequency, and the interference pattern resulting from the superposition of multiple motor unit action potentials.
- Guidelines for proper EMG signal acquisition and processing to obtain meaningful data on muscle function.
ZMPCZM019000.11.04 Evidenced based guidelines for Migrane Headache : Behaviou...painezeeman
The document summarizes evidence from studies on behavioral and physical treatments for migraine headaches. It finds that relaxation training, thermal biofeedback plus relaxation training, EMG biofeedback therapy, and cognitive-behavioral therapy led to statistically significant improvements in headache frequency and severity, with effect sizes ranging from moderate to large. Combining cognitive-behavioral therapy with thermal biofeedback produced more modest improvements. Studies of acupuncture for migraines showed mixed results, with some finding it more effective than sham treatments and others finding no difference compared to sham interventions.
The document provides an overview and instructions for using the IncontiMed Checklist software. It describes how to select a patient, administer a checklist to collect patient responses, generate reports on completed checklists, and manage patient records and settings. The software is designed to collect self-reported information from patients on incontinence experiences and supports customization of report templates, password protection, and displaying initials instead of names for patient confidentiality.
The document provides an overview and instructions for using the Headache Checklist software. It describes how to select a patient, administer the checklist questions, generate reports, and manage patient records and settings. The software allows clinicians to collect self-reported headache information from patients and create standardized reports in a HIPAA-compliant manner. It can be used as an assessment tool alongside a clinical evaluation to help evaluate headache complaints.
1. This document provides instructions for using NeuroGraph software to conduct biofeedback sessions. It describes how to select a patient, choose a protocol, attach sensors, monitor signals in real-time, set goals and provide feedback.
2. The user's guide explains how to review session data, including graph displays, replay functions, and report generation. Customization options allow modifying graph types, colors, and other display settings.
3. Advanced features include creating schedules with multiple trials, setting trial properties, and exporting data. The guide provides details on protocol customization, system settings, and other administrative functions for configuring and managing NeuroGraph software.
This document provides a user's guide for NeuroGames software. It describes how to install and set up the software, select protocols, create and edit protocols, manage patients, run protocols, view reports and save session data. Key steps include checking the instrument settings, selecting or creating a protocol, selecting a patient, running the protocol, and viewing saved session reports. The guide also describes options for password protection, confidentiality settings, and alternative protocol types including jungle and star light games.
ZMPCZM019000.11.03 EMG based evaluation & therapy concept for pelvic floor Dy...painezeeman
(1) EMG is used to directly measure pelvic floor muscle function and innervation for evaluating and treating dysfunctions like incontinence. (2) A 4-channel EMG system measures the pelvic floor and surrounding muscles during standardized tests to analyze coordination and identify issues. (3) Biofeedback training then focuses on re-educating the pelvic floor muscle through isolated activation exercises and integrating it into whole body movements and daily activities. (4) Retests assess changes in muscle activation, endurance, and coordination from the training.
This document provides an introduction to kinesiological electromyography (EMG). It discusses the basics of EMG including:
- The origin of the EMG signal from motor unit action potentials generated by muscle fiber membranes.
- How the EMG signal is detected using surface electrodes and processed to analyze muscle activation patterns.
- Key concepts for interpreting the EMG signal including recruitment, firing frequency, and the interference pattern resulting from the superposition of multiple motor unit action potentials.
- Guidelines for proper EMG signal acquisition and processing to obtain meaningful data on muscle function.
The Pressure Right wrist strip measures 5.5 inches long by 1 inch wide and has a hard plastic button 1.5 inches from the end that is 0.52 inches in diameter and 0.27 inches high. It is made of low-density perforated polyethylene film with an acrylate adhesive and the plastic button is made of medical-grade acrylonitrile butadiene styrene plastic through an injection molding process.
The Pressure Right wrist strip is designed to apply targeted pressure to the P6 acupressure point on the wrist to help reduce nausea and vomiting. It uses an adhesive backing to keep the plastic dome firmly placed over the P6 point for an extended period, providing relief without medication. The strip is applied using a locator guide to identify the P6 point on both wrists. Placing the plastic dome over the marked points and securing the adhesive strip helps stimulate the P6 point within five minutes to alleviate nausea and vomiting associated with conditions like surgery, chemotherapy, or motion sickness.
The NEUROMOVE is a neurological rehabilitation tool that has been proven to help patients recover lost movement from strokes and other conditions. It works by training healthy neurons to assume the functions of damaged brain cells through a concept called neuroplasticity. The device can be used even without muscle movement and is suitable both for clinical use and for patients to use at home for 30 minutes a day over 4-5 months to provide dramatic recovery results.
Zmpczm0170001003 ZMPCZM017000.10.03 Neuromove clinical presentation from Pain...Painezee Specialist
The NeuroMove is an EMG-triggered neuromuscular relearning device that uses electrical stimulation to reinforce attempted movements in patients with stroke, traumatic brain injury, spinal cord injury, and other neurological conditions. It detects muscle activity through electrodes and provides electrical stimulation as a reward when activity surpasses a threshold, helping to retrain motor control through neuroplasticity. Clinical studies have found the NeuroMove effective in regaining function for chronic stroke patients by improving proprioceptive feedback through activity time-locked to movement attempts.
ZMPCZM017000.10.03 Neuromove clinical presentation from PainEzeePainezee Specialist
The NeuroMove is an EMG-triggered neuromuscular relearning device that uses electrical stimulation to reinforce attempted movements in patients with stroke, traumatic brain injury, spinal cord injury, and other neurological conditions. It detects muscle activity through electrodes and provides electrical stimulation as a reward when activity crosses a threshold, helping to retrain motor control pathways in the brain. Clinical studies have found the NeuroMove effective in regaining function for chronic stroke patients by improving proprioceptive feedback through intensive, repetitive therapy sessions using this brain retraining tool.
ZMPCZM017000.10.03 Neuromove clinical presentation from PainEzeePainezee Specialist
The NeuroMove is an EMG-triggered neuromuscular relearning device that uses electrical stimulation to reinforce attempted movements in patients with stroke, traumatic brain injury, spinal cord injury, and other neurological conditions. It detects muscle activity through electrodes and provides electrical stimulation as a reward when activity crosses a threshold, helping to retrain motor control pathways in the brain. Clinical studies have found the NeuroMove effective in regaining function for chronic stroke patients by improving proprioceptive feedback through intensive, repetitive therapy sessions using this brain retraining tool.
The document summarizes the features and benefits of the MY TENS device, which is designed for home use transcutaneous electrical nerve stimulation (TENS) therapy. Key points:
- MY TENS is certified for safety and designed for easy home use without complicated settings. It provides a preset operating program to effectively treat most pain conditions.
- The device has an ergonomic design that allows for simple, flexible application to any part of the body. It also ensures the electrical signal is transmitted intact from the device to the patient.
- MY TENS can be discreetly used in public as it can be placed under clothes. It is also affordable and reusable through replacement of consumable parts.
This document declares that the NexWave Combo Muscle Stimulator and similar products manufactured for other distributors meet the essential health and safety requirements of the European Community. The manufacturer, Zynex Medical, Inc., used conformity assessment procedures and standards including ISO 13485 for quality management, IEC 60601 for electrical safety of medical equipment, and EN 1041 for information supplied by manufacturers. Thomas Sandgaard, President and CEO of Zynex Medical, Inc., signed the declaration on November 18, 2011.
This document provides instructions for electrode placement for various neuromuscular electrical stimulation (NMES) treatments. It describes the patient positioning and placement of the red and black electrodes on the body for treatments targeting the biceps, triceps, elbow flexion, elbow extension, wrist and finger flexion, shoulder abduction, and ankle dorsiflexion. Electrode placement may require trial and error to find the correct spots using low level stimulation. Additional targeted muscle groups and placements are described in the user manual.
Zywie Medical Devices Private Limited has commenced a collaboration with the Medical Devices Division of Juno Pharm from October 13, 2013. This collaboration will help both companies capture their full potential and help expand their business footprint in pain management medical devices across India. Ms. Chavali Anilaja announced the collaboration.
The document discusses the benefits of exercise for mental health. Regular physical activity can help reduce anxiety and depression and improve mood and cognitive function. Exercise causes chemical changes in the brain that may help protect against developing mental illness and improve symptoms for those who already suffer from conditions like anxiety and depression.
This document provides instructions for connecting electrodes for a TENS (transcutaneous electrical nerve stimulation) unit. It notes that the unit has two lead wires that should be connected to opposite electrodes in a diagonal configuration as shown in the diagram, and that the lead wire colors do not matter as long as the connections are diagonal.
This document provides instructions for proper electrode placement for a TENS (transcutaneous electrical nerve stimulation) unit. It notes that the unit has two lead wires that should be connected to opposite electrodes in a diagonal configuration as shown in the included diagram. The document also specifies that the lead wire colors do not matter and can be placed on either the top or bottom of the area being treated.
This document provides instructions for using ChiroScan software to conduct electromyography (EMG) scans. It describes connecting hardware, installing and registering the software, configuring instruments and protocols, and conducting scanning procedures. The scanning procedure involves preparing the skin, applying sensors coated with electrode gel to specific sites on the back, and collecting EMG data to measure muscle activity levels. The software analyzes the data and can generate reports comparing results to normative values.
This document contains information about dermatome charts, peripheral nerve charts, and motor point locations for electrostimulation therapy. The dermatome charts show the cutaneous nerve innervation patterns for the front, back, and foot. The peripheral nerve charts display the branches of the cervical, brachial, lumbar, and sacral plexuses. The motor point sections provide diagrams of the anterior and posterior muscle motor points for the trunk, upper extremities, and lower extremities.
There are two types of nerve fibers that transmit signals from the body to the brain. Large nerve fibers called nociceptive fibers do not transmit pain signals, while small nerve fibers do transmit pain signals. A TENS unit works by using electrical currents to stimulate the large nerve fibers, which prevents the small pain fibers from reaching the brain. This stimulation of large fibers closes the "gate" in the spinal cord to pain signals from the small fibers, providing pain relief. This mechanism is known as the "gate control theory of pain."
There are two types of nerve fibers that transmit signals from the body to the brain. Large nerve fibers called nociceptive fibers do not transmit pain signals, while small nerve fibers do transmit pain signals. A TENS unit works by using electrical currents to stimulate the large nerve fibers, which prevents the small pain fibers from reaching the brain. This stimulation of large fibers closes the "gate" in the spinal cord to pain signals from the small fibers, providing pain relief. This mechanism is known as the "gate control theory of pain."
There are two types of nerve fibers that transmit signals from the body to the brain. Large nerve fibers called nociceptive fibers do not transmit pain signals, while small nerve fibers do transmit pain signals. A TENS unit works by using electrical currents to stimulate the large nerve fibers, which prevents the small pain fibers from reaching the brain. This stimulation of large fibers closes the "gate" in the spinal cord to pain signals from the small fibers, providing pain relief. This mechanism is known as the "gate control theory of pain."
This study examined the feasibility and efficacy of home-based electromyography-triggered neuromuscular stimulation (ETMS) for chronic stroke patients with limited wrist extension ability. Twelve chronic stroke patients were randomly assigned to receive either 8 weeks of ETMS followed by 8 weeks of home exercises, or vice versa. Outcome measures included the Fugl-Meyer assessment, Action Research Arm Test, and goniometry. After ETMS, patients showed modest improvements on the Fugl-Meyer but no changes on the Action Research Arm Test. Both groups increased active wrist extension by 21 degrees after ETMS. The study demonstrated ETMS can be feasibly administered at home and can increase active wrist movement, though it did
The Pressure Right wrist strip measures 5.5 inches long by 1 inch wide and has a hard plastic button 1.5 inches from the end that is 0.52 inches in diameter and 0.27 inches high. It is made of low-density perforated polyethylene film with an acrylate adhesive and the plastic button is made of medical-grade acrylonitrile butadiene styrene plastic through an injection molding process.
The Pressure Right wrist strip is designed to apply targeted pressure to the P6 acupressure point on the wrist to help reduce nausea and vomiting. It uses an adhesive backing to keep the plastic dome firmly placed over the P6 point for an extended period, providing relief without medication. The strip is applied using a locator guide to identify the P6 point on both wrists. Placing the plastic dome over the marked points and securing the adhesive strip helps stimulate the P6 point within five minutes to alleviate nausea and vomiting associated with conditions like surgery, chemotherapy, or motion sickness.
The NEUROMOVE is a neurological rehabilitation tool that has been proven to help patients recover lost movement from strokes and other conditions. It works by training healthy neurons to assume the functions of damaged brain cells through a concept called neuroplasticity. The device can be used even without muscle movement and is suitable both for clinical use and for patients to use at home for 30 minutes a day over 4-5 months to provide dramatic recovery results.
Zmpczm0170001003 ZMPCZM017000.10.03 Neuromove clinical presentation from Pain...Painezee Specialist
The NeuroMove is an EMG-triggered neuromuscular relearning device that uses electrical stimulation to reinforce attempted movements in patients with stroke, traumatic brain injury, spinal cord injury, and other neurological conditions. It detects muscle activity through electrodes and provides electrical stimulation as a reward when activity surpasses a threshold, helping to retrain motor control through neuroplasticity. Clinical studies have found the NeuroMove effective in regaining function for chronic stroke patients by improving proprioceptive feedback through activity time-locked to movement attempts.
ZMPCZM017000.10.03 Neuromove clinical presentation from PainEzeePainezee Specialist
The NeuroMove is an EMG-triggered neuromuscular relearning device that uses electrical stimulation to reinforce attempted movements in patients with stroke, traumatic brain injury, spinal cord injury, and other neurological conditions. It detects muscle activity through electrodes and provides electrical stimulation as a reward when activity crosses a threshold, helping to retrain motor control pathways in the brain. Clinical studies have found the NeuroMove effective in regaining function for chronic stroke patients by improving proprioceptive feedback through intensive, repetitive therapy sessions using this brain retraining tool.
ZMPCZM017000.10.03 Neuromove clinical presentation from PainEzeePainezee Specialist
The NeuroMove is an EMG-triggered neuromuscular relearning device that uses electrical stimulation to reinforce attempted movements in patients with stroke, traumatic brain injury, spinal cord injury, and other neurological conditions. It detects muscle activity through electrodes and provides electrical stimulation as a reward when activity crosses a threshold, helping to retrain motor control pathways in the brain. Clinical studies have found the NeuroMove effective in regaining function for chronic stroke patients by improving proprioceptive feedback through intensive, repetitive therapy sessions using this brain retraining tool.
The document summarizes the features and benefits of the MY TENS device, which is designed for home use transcutaneous electrical nerve stimulation (TENS) therapy. Key points:
- MY TENS is certified for safety and designed for easy home use without complicated settings. It provides a preset operating program to effectively treat most pain conditions.
- The device has an ergonomic design that allows for simple, flexible application to any part of the body. It also ensures the electrical signal is transmitted intact from the device to the patient.
- MY TENS can be discreetly used in public as it can be placed under clothes. It is also affordable and reusable through replacement of consumable parts.
This document declares that the NexWave Combo Muscle Stimulator and similar products manufactured for other distributors meet the essential health and safety requirements of the European Community. The manufacturer, Zynex Medical, Inc., used conformity assessment procedures and standards including ISO 13485 for quality management, IEC 60601 for electrical safety of medical equipment, and EN 1041 for information supplied by manufacturers. Thomas Sandgaard, President and CEO of Zynex Medical, Inc., signed the declaration on November 18, 2011.
This document provides instructions for electrode placement for various neuromuscular electrical stimulation (NMES) treatments. It describes the patient positioning and placement of the red and black electrodes on the body for treatments targeting the biceps, triceps, elbow flexion, elbow extension, wrist and finger flexion, shoulder abduction, and ankle dorsiflexion. Electrode placement may require trial and error to find the correct spots using low level stimulation. Additional targeted muscle groups and placements are described in the user manual.
Zywie Medical Devices Private Limited has commenced a collaboration with the Medical Devices Division of Juno Pharm from October 13, 2013. This collaboration will help both companies capture their full potential and help expand their business footprint in pain management medical devices across India. Ms. Chavali Anilaja announced the collaboration.
The document discusses the benefits of exercise for mental health. Regular physical activity can help reduce anxiety and depression and improve mood and cognitive function. Exercise causes chemical changes in the brain that may help protect against developing mental illness and improve symptoms for those who already suffer from conditions like anxiety and depression.
This document provides instructions for connecting electrodes for a TENS (transcutaneous electrical nerve stimulation) unit. It notes that the unit has two lead wires that should be connected to opposite electrodes in a diagonal configuration as shown in the diagram, and that the lead wire colors do not matter as long as the connections are diagonal.
This document provides instructions for proper electrode placement for a TENS (transcutaneous electrical nerve stimulation) unit. It notes that the unit has two lead wires that should be connected to opposite electrodes in a diagonal configuration as shown in the included diagram. The document also specifies that the lead wire colors do not matter and can be placed on either the top or bottom of the area being treated.
This document provides instructions for using ChiroScan software to conduct electromyography (EMG) scans. It describes connecting hardware, installing and registering the software, configuring instruments and protocols, and conducting scanning procedures. The scanning procedure involves preparing the skin, applying sensors coated with electrode gel to specific sites on the back, and collecting EMG data to measure muscle activity levels. The software analyzes the data and can generate reports comparing results to normative values.
This document contains information about dermatome charts, peripheral nerve charts, and motor point locations for electrostimulation therapy. The dermatome charts show the cutaneous nerve innervation patterns for the front, back, and foot. The peripheral nerve charts display the branches of the cervical, brachial, lumbar, and sacral plexuses. The motor point sections provide diagrams of the anterior and posterior muscle motor points for the trunk, upper extremities, and lower extremities.
There are two types of nerve fibers that transmit signals from the body to the brain. Large nerve fibers called nociceptive fibers do not transmit pain signals, while small nerve fibers do transmit pain signals. A TENS unit works by using electrical currents to stimulate the large nerve fibers, which prevents the small pain fibers from reaching the brain. This stimulation of large fibers closes the "gate" in the spinal cord to pain signals from the small fibers, providing pain relief. This mechanism is known as the "gate control theory of pain."
There are two types of nerve fibers that transmit signals from the body to the brain. Large nerve fibers called nociceptive fibers do not transmit pain signals, while small nerve fibers do transmit pain signals. A TENS unit works by using electrical currents to stimulate the large nerve fibers, which prevents the small pain fibers from reaching the brain. This stimulation of large fibers closes the "gate" in the spinal cord to pain signals from the small fibers, providing pain relief. This mechanism is known as the "gate control theory of pain."
There are two types of nerve fibers that transmit signals from the body to the brain. Large nerve fibers called nociceptive fibers do not transmit pain signals, while small nerve fibers do transmit pain signals. A TENS unit works by using electrical currents to stimulate the large nerve fibers, which prevents the small pain fibers from reaching the brain. This stimulation of large fibers closes the "gate" in the spinal cord to pain signals from the small fibers, providing pain relief. This mechanism is known as the "gate control theory of pain."
This study examined the feasibility and efficacy of home-based electromyography-triggered neuromuscular stimulation (ETMS) for chronic stroke patients with limited wrist extension ability. Twelve chronic stroke patients were randomly assigned to receive either 8 weeks of ETMS followed by 8 weeks of home exercises, or vice versa. Outcome measures included the Fugl-Meyer assessment, Action Research Arm Test, and goniometry. After ETMS, patients showed modest improvements on the Fugl-Meyer but no changes on the Action Research Arm Test. Both groups increased active wrist extension by 21 degrees after ETMS. The study demonstrated ETMS can be feasibly administered at home and can increase active wrist movement, though it did