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Multiscan
BCMultiscan BC
Description
Multi frequency segmental Body composition 3D analyzer. The device measures current, voltage, phase angle in multi frequency mode and calculates complex impedance, active and reactive resistance in tetrapolar mode.
Intended use
Multiscan BC is a General Wellness product has an intended use that relates to maintaining or encouraging a general state of health or a healthy activity. Intended use relates the role of healthy lifestyle with helping to reduce the risk or impact of certain chronic diseases or conditions.
Features
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• Segmental Body composition 3D Analyzer *
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• Body composition assessment (FM, FFM, TBW, ECW, ICW, BMI, Muscular mass, Phase angle)
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• Microcirculation assessment
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• Body composition 3D modeling (fat mass color code)
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• Diet adviser including visceral fat 3D modeling
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• Vertebral 3D Modeling
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• Assistance to the therapeutic decision for SPA / Fitness / Sport trainings
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• Measurement time: 2 minutes
Specification
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• USB connectable box
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• Tetra polar stainless steel plates for the feet
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• Tetra polar stainless steel plates for the hands
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• 4 lead Multscan cables for the hands
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• 4 lead Multscan cables for the feet
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• USB cable
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• Multiscan BC Software x 2 licenses
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• Transport bag
* CE Certificate Ref. Numbers: OSE-15-0412/01 and OSE-15-0412/02
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Multiscan
BC-OXiMultiscan BC-OXi
Description
Multi frequency segmental Body composition 3D analyzer with Digital Pulse Oximeter. The device is providing Segmental Body composition assessment in tetrapolar mode and recording Digital Pulse wave for Stress / Fatigue and Cardio assessment.
Intended use
Multiscan BC-OXi is a General Wellness product has an intended use that relates to maintaining or encouraging a general state of health or a healthy activity. Intended use relates the role of healthy lifestyle with helping to reduce the risk or impact of certain chronic diseases or conditions.
Features
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• Segmental Body composition 3D Analyzer *
-
• Body composition assessment (FM, FFM, TBW, ECW, ICW, BMI, Muscular mass, Phase angle)
-
• Microcirculation assessment
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• Body composition 3D modeling (fat mass color code)
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• Diet adviser including visceral fat 3D modeling
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• Vertebral 3D Modeling
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• Extended assistance to the therapeutic decision for SPA / Fitness / Sport trainings
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• Heart Rate Variability Indicators
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• Stress / Fatigue assessment
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• Digital pulse wave analysis;
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• Measurement time: 2 minutes
Specification
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• USB connectable box
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• Digital USB connectable pulse oximeter
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• Tetra polar stainless steel plates for the feet
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• Tetra polar stainless steel plates for the hands
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• 4 lead Multscan cables for the hands
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• 4 lead Multscan cables for the feet
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• USB cable
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• Multiscan BC-OXi Software x 2 licenses
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• Transport bag
* Multiscan BC CE Certificate Ref. Numbers: OSE-15-0412/01 and OSE-15-0412/02
Pulse Oximeter: EC Certificate Ref Number: G1 13 07 74184 004
ISO 13485 for accessories: Ref Number: Q1N 13 06 74184 003
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Bio Impedance SpectroscopyBio Impedance Measurements
Bioimpedance Measurement
Electrical impedance is the opposition to the flow of an electrical current, being the ratio between an alternating sinusoidal voltage and an alternating sinusoidal flow. In consequence impedance is a passive magnitude that does not irradiate energy, therefore energy must be provided in two ways: by exciting the tissue with current or with voltage. In this case, the EBI measurement method used consists on injecting an electrical signal with a known current and measuring the reciprocal complementary voltage magnitude the value is calculated using the Ohm’s Law, in the frequency domain. Z = V / I
Where Z is the impedance, V the voltage and I the current. The diagram block of a typical impedance measurement system is the following: Typical diagram block of a impedance measurement system
Measurement types
Depending on the type of information that we are looking for analyse several types of measurements can be done. Non-phase BIA measurement: This method measures the total resistance of the body (Z). This does not give determination of the phase angle and, as such, a subdivision of impedance into water and cellular resistance, so that no judgement can be made about the body cell mass or the extra-cellular mass with non-phase measurements Phase BIA measurement: The phase sensitive technique of measuring allows the impedance Z to be differentiated into its two components resistance (R), that shows the water resistance, and reactance (Xc), that show the cell resistance. This let us differentiate between the body cell mass and extra-cellular mass. Phase BIA multi-frequency measurement: BIA is frequency dependent, therefore for a more intensive study we can study the resistance and reactance in a different single low frequencies measurements (1-5 KHz). With this type of measurement it is possible to achieve a subdivision of the total body water into intra-cellular and extra-cellular body water.
Measurement Techniques
There are several approaches to measure Bioimpedance that should be chosen depending on the desired characteristics of the system built. Null Techniques: Detection with this technique is very simple and it is based in a simple ampere meter. The most common method used is a Wheatstone bridge. This is a high accurate method with the inconvenient of needing a large number of electronic components and not being time efficient in some applications because of its iterating process. Deflection Techniques: The impedance estimation is done by measuring the voltage drop or the current through the load as a response to an alternative known current. This method is based on simple electronics using complex operations. Due to Measurements of Bioimpedance & Instrumentation this an application specific integrated circuit or microcontroller is needed to carry these operations. Its main characteristic is the time efficient, being able to do short time accuracy measurements. For the impedance estimation we are going to focus only in the deflection techniques that are those that are commonly used in bioimpedance measurements. In impedance estimation is it possible to do single frequency and multy-frequency analysis using different techniques, basing the study in the known excitation provided and the measured obtained. So for single frequency or sweep frequency measurements usually Sine Correlation is used and for multi-frequency measurements it is common used the Fourier Transform.
Renal function monitoring
Electrical Bioimpedance measurements have been used for many years to study the electrical properties of biologic tissue and to measure physiological events, being applied in several clinical areas, including body composition. The assessment of oedema formation from EBI measurements is based on the dependency of the electrical properties of tissue on its structure and intrinsic constituents, i.e. alterations in the tissue structure produce a modification of its electrical properties.
When the renal function is impaired in the kidneys, an immediate physiological consequence is an excessive accumulation of liquid in the rest of the body, and consequently oedema is formed. Oedema is considered by the physician a common indicator of renal failure, and therefore visual inspection by the physician is a regular practice to detect such kidney function impairment. Such an inspection is usually performed targeting the limbs, legs and arms, targeting the inspection for peripheral oedema.
There are several methods of assessing extracellular swelling, and the EBI measurement approach is one of the more comfortable ones, due to the fact that the electrical properties of tissue can be measured non-invasively and without tightening the skin. Some studies about the excess of fluid in chronic HD patients, using Bioimpedance spectroscopy measurements, where performed. The experimental results suggested that HD patients keep their excess fluid volume primarily in the extracellular compartment (interstitial fluid). Bioimpedance spectroscopy together with a stable measurement of lean tissue can determine the degree of relative excess hydration. Due to the capacitance effects of the cell membrane, the tissue impedance depends on the measurement frequency. As a consequence, the accuracy of measurements by means of multiple frequency Bioimpedance spectroscopy analysis is superior to the accuracy of measurements based on a single frequency for the prediction of extracellular water. Some authors suggest that the best frequency range to assess extra-cellular fluid is up to 10 kHz and the range between 50-100 kHz is a suitable measurement range for a successful assessment of extra- and intra-cellular fluid.
Concluding, the monitoring principle of the EBI measurement system implemented in this thesis work lays as follows: during renal failure the amount of interstitial fluid in the limbs increases, causing extracellular oedema. The consequent interstitial swelling modifies the electrical properties of the tissue, and by means of the combination of non- invasive EBI measurements with skin-surface electrodes and EBI spectroscopy analysis, the ongoing swelling can be detected. Therefore changes in the EBI of the limbs may be used as an efficient indicator for early detection of renal failure.
Transthoracic impedance and impedance cardiography analysis
Electrical Bioimpedance (EBI) through transthoracic measurements offers a non-invasive manner to measure hemodynamic values. In the last decades, advances in the field of electrodes, electronic hardware and the development of textrodes have paved the ways for smaller, easier to use equipment for EBI measurements.
Impedance cardiography is the study of the bioimpedance of the human body but limiting measurement area to the chest cavity. The changes of the bioimpedance signal can be monitored to estimate cardiac parameters and assess the cardiac cycle. The monitoring can be performed using non-invasive measuring methods with skin electrodes.
Bioimpedance Plethysmography is a method of studying tissue volume changes in a living body by measuring the changes of electrical impedance at the body surface. Impedance Cardiography (ICG) is the Impedance Plethysmography measurement limited to the chest/thorax region.
Electrocardiography or EKG is the process of recording all the electric excitation phenomena of the heart. The EKG records with a good level of detail the electrical excitation in different parts of the heart muscle: which include the sinus and AV nodes, the atrial and ventricular muscles and nerve fibers in the ventricular muscle; it is crucial in the diagnosing of several heart diseases. As will be seen later on, the EKG signal shows a good relation with the ICG signal as some of the waves of the EKG are correlated with waves in the ICG measurement.
As with EKG, ICG measurements have the potential of being done in a non-invasive way. Several authors have tried to correlate invasive methods like thermo-dilution with ICG with skin electrodes with different degrees of success. Most of the authors agree that ICG requires more methodological investigation but are good enough to estimate changes of the Stroke Volume.
The impedance cardiography signal is obtained by injecting a current and then sensing the voltage in the thorax region to estimate the impedance using the Ohms law equation.
The typically used current to measure the impedance is a sinusoidal signal with a constant frequency between 20 and 150 kHz with a constant amplitude of 0.5-5 mA. The impedance usually consists of a Real component, with values between 15Ohm to 30 Ohm, and an often negligible and not used imaginary component.The changes of impedance due to the changes of fluid in the chest area are typically between 100-400 mOhm which results in a change of 0.1-0.4 mV in the signal received when applying 1mA to the patient.
Lung edema
At this stage, the patient typically has dyspnea (short breath) and hypoxia (low partial pressure of oxygen in the blood) because of impaired gas exchange due to the increased interstitial fluid volume. As a consequence, the patient is usually committed to an intensive care unit for medical treatment. Preclinical detection and continuous monitoring of the lung fluid volume during medical treatment would enhance medical care while reducing costs.
Unfortunately, conventional detection methods like radiographic imaging, monitoring pulmonary capillary wedge pressure or double indicator thermodilution are impractical for continuous monitoring. A promising alternative is the Bioimpedance Spectroscopy (BIS). Detection of lung edema using BIS is based on the fact that the amount of fluid in the lungs has significant impact on their electrical impedance. Normally, the lungs have about 5% of fluid and 95% of air, resulting in an electrical impedance in the range of about 10 to 20 Ohm. If the amount of fluid in the lungs increases, electrical impedance decreases because of the much lower electrical impedance of fluid (serum, for example, has a resistance of about 0.6 Ohm).
Compared to other measurement methods, BIS has two significant advantages: the measurement is non-invasive and it can easily be done at the patient’s home. In previous work, BIS was shown to be practical for detection of lung edema and, in a single-frequency version, it is used in some ICDs (implantable cardioverter-defibrillator).
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3Дек.Russian Healthcare Week
On December 3-7, MultiscanPro health screening equipment was showcased at the 28th international exhibition for Medical Engineering, Products and Consumables – Russian Healthcare Week.
The year 2018 was rich in healthcare industry fairs and trade shows for us.
On December 3-7, the MultiscanPro health screening equipment was being showcased at the 28th international exhibition for Medical Engineering, Products and Consumables – Russian Healthcare Week, held in Expocentre in Moscow, Russia.
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12Ноя.MultiscanPro at MEDICA 2018
On November 12-15 MultiscanPro along with the top decision makers of the international healthcare industry took part in the largest international medical trade fair MEDICA in DГјsseldorf, Germany.
On November 12-15 MultiscanPro along with the top decision-makers of the international healthcare industry took part in the largest international medical trade fair - MEDICA in DГјsseldorf, Germany.
On the four days of the fair, around 120,000 visitors from 155 countries got the opportunity to see the entire process chain of innovations for the development, manufacture and marketing of medical devices, products, instruments and high-tech solutions presented by 5,273 exhibitors from 66 countries.
One of the significant trends that could be noticed at the fair was the digital transformation of the industry. This not only offers good business perspectives to the providers, they also benefit doctors and particularly patients.
The MultiscanPro team was excited to be part of such a significant event and to showcase our latest developments. The MultiscanPro systems attracted a lot of attention both from the visitors and exhibitors, who had an opportunity to get a free health screening and consultation, as well as learn about the technical part of the devices.
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6Дек.FIBO USA 2018: Highlights & Results
On December 6-8, we took part in the largest fitness event of the year – FIBO, held in the USA for the first time in the history of the event.
On December 6-8, we took part in the largest fitness event of the year – FIBO, held in the USA for the first time in the history of the event.
Standing among the industry giants, we showcased our equipment and held free wellness assessment tests for all the visitors of the trade show, including some athletes who got amazing scores for body composition, muscle to fat mass ration, and the overall wellness. They also enjoyed receiving training and nutrition recommendations based on the test results, which they found really handy for putting together customized training and nutrition programs.
We are thankful to the FIBO organizers for this great opportunity to learn more about the US market and the global fitness industry and are looking forward to coming back to FIBO in the upcoming year.
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5Янв.CE Mark clearance
MultiscanPro received ISO 13485 and CE mark clearance.
MultiscanPro received ISO 13485 and CE mark clearance for the System for noninvasive Functional Body State Assessment MULTISCAN PRO. -
29Окт.InterCHARM 2016
Multiscan participated in an international autumn exhibition - InterCHARM 2016 in Moscow
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3Июн.Startup Village 2015
On 2-3 June 2015, MultiscanPro took part in the Startup Village held at the Skolkovo Hypercube in Moscow.
Only in its third year and yet already a fixture on the European startup calendar.
Startup Village matches investors with innovators in an open-air festival of entrepreneurship.
Held over two summer days (2-3 June 2015) at the Skolkovo Hypercube, Startup Village incorporates lively debates, interactive startup exhibitions, and the startup pitch sessions.
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Asia
Streeter Biofield Science Pvt Ltd.
213, 31st Jan Road,
Panjim, Goa India. 403001
India +91 9545529944
drthornton@biofieldsciences.com
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Europe
A. Coppenslaan 5 B9
2300 Turnhout
Belgium
office: +32 14 61 99 37
mobile: +477 27 18 24
http://www.multiscanpro.com
Biofield Science
Reddicks Hill
Honiton
Devon UK
E149PY
+44 7980788495
drthornton@biofieldsciences.com
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Middle East
We are seeking new distributors
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Russia
Master Media
Moscow City, Imperia Tower, 16th Floor, Office 1620
http://www.multiscan24.ru
Tel. +7-495-545-7070
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South America
Menla technologies, LLC
Independence, Missouri
United States
office: +1 816.350.3219
mobile: +1 816.547.4206
info@menlatech.com
http://www.multiscanpro.us
MEDICALSOFT LLC
http://www.medicalsoft.com
support@medicalsoft.com
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USA
Menla technologies, LLC
Independence, Missouri
United States
office: +1 816.350.3219
mobile: +1 816.547.4206
info@menlatech.com
http://www.multiscanpro.us
MEDICALSOFT LLC
http://www.medicalsoft.com
support@medicalsoft.com