U.S. patent application number 14/700349 was filed with the patent office on 2016-09-08 for device and method for contactless skin treatment.
The applicant listed for this patent is BTL HOLDINGS LIMITED. Invention is credited to Tomas Schwarz, Jan Zarsk.
Application Number | 20160256702 14/700349 |
Document ID | / |
Family ID | 56848448 |
Filed Date | 2016-09-08 |
United States Patent
Application |
20160256702 |
Kind Code |
A1 |
Schwarz; Tomas ; et
al. |
September 8, 2016 |
DEVICE AND METHOD FOR CONTACTLESS SKIN TREATMENT
Abstract
Devices and methods for contactless skin treatment use feedback
power control for non-invasive treatment of skin and human tissue.
Electromagnetic energy heats skin or tissue. A feedback system
measures an output physical quantity before the output of
electromagnetic waves from the device into the patient.
Alternatively the feedback system scans values of a physical
quantity on or near the patient. The devices and methods allow for
delivering the optimum amount of energy to the patient while
reducing the thermal load of the device.
Inventors: |
Schwarz; Tomas; (Prague,
CZ) ; Zarsk ; Jan; (Framington, MA) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
BTL HOLDINGS LIMITED |
Limassol |
|
CY |
|
|
Family ID: |
56848448 |
Appl. No.: |
14/700349 |
Filed: |
April 30, 2015 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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14637930 |
Mar 4, 2015 |
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14700349 |
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
A61N 5/022 20130101;
A61N 1/403 20130101; A61N 2/02 20130101; A61N 5/025 20130101; A61N
2/004 20130101 |
International
Class: |
A61N 1/40 20060101
A61N001/40 |
Claims
1. A device for contactless skin treatment by electromagnetic
waves, comprising: a power supply electrically connected to a high
frequency generator and at least two electrodes; a sensor between
the power supply and the at least two electrodes for measuring
values of at least one physical quantity between different branches
of symmetrical signal cables leading to each electrode and where
input power to at least one electrode is adjusted based on the
measured values.
2. (canceled)
3. The device according to claim 1 having a transmatch between the
high frequency generator and the sensor.
4. The device of claim 3 where the sensor is connected to the at
least two electrodes via a cable and measures the values of the at
least one physical quantity between the transmatch and the at least
two electrodes.
5. The device according to claim 1 wherein input power to the
electrodes is adjusted continuously or incrementally based on the
measured values.
6. The device of claim 1 where electromagnetic waves cause heating
of the skin.
7. The device according to claim 6 where electromagnetic waves
cause selective heating of dermis and/or hypodermis.
8. The device of claim 6 where the heating causes remodeling and/or
downsizing of a volume of lipid-rich cells and/or remodeling of
collagen tissue and/or remodeling of elastic fibers.
9. The device of claim 1 where the measured physical quantity is
transformed into optical information.
10. The device of claim 1 further including a control unit
electrically connected to the power supply and to the sensor.
11. The device of claim 10 where the control unit determines by
look-up-table or transfer function an output value of physical
quantity and where the input power is regulated based on the value
determined by look-up-table or transfer function.
12. The device of claim 10 where the control unit calculates output
power of the electrode.
13-14. (canceled)
15. A method for contactless skin treatment by electromagnetic
waves, comprising: providing high frequency power from a high
frequency generator to an electrode; transmitting electromagnetic
waves from the electrode into skin of a patient, with the electrode
not touching the skin of the patient; measuring a distance between
the electrode and the skin of the patient; and adjusting input
power to the high frequency generator based on the measured
distance to provide continuous energy to the skin of the patient
via feedback power control.
16. (canceled)
17. The method of claim 15 further including measuring
temperature.
18. The method of claim 15 further including measuring
impedance.
19. The method of claim 15 further including matching impedance
between the high frequency generator and the electrode via a
transmatch.
20. The method of claim 17 wherein skin temperature during
treatment is maintained between 38.degree. C.-48.degree. C.
21. The method of claim 15 further including measuring electric
field intensity.
22. The method of claim 15 wherein the electromagnetic waves cause
heating of the skin.
23. The method of claim 22 wherein the heating causes remodeling
and/or downsizing of a volume of lipid-rich cells and/or remodeling
of collagen tissue and/or remodeling of elastic fibers.
24. A method for contactless skin treatment by electromagnetic
waves, comprising: providing high frequency power from a high
frequency generator to at least two electrodes; matching impedance
between the high frequency generator and the at least two
electrodes via a transmatch; transmitting electromagnetic waves
from the at least two electrodes into skin of a patient, with the
electrodes not touching the skin of the patient, and with the
electromagnetic waves heating the skin; measuring values of at
least one physical quantity between different branches of first and
second symmetrical signal cables leading to the at least two
electrodes: adjusting input power to the high frequency generator
based on the at least one output quantity; and providing energy to
the skin of the patient via the adjusted input power to the high
frequency generator.
25. (canceled)
26. The method of claim 24 wherein the at least one output quantity
is at least one of: temperature, distance between the electrode and
the skin of the patient, impedance, electric field intensity,
current, voltage, phase shift.
27. The method of claim 15 further including calculating a true
transmitted energy.
28. The method of claim 15 further including gradually increasing
the input power.
29. The method of claim 28 further including reducing the input
power if a sensed output quantity exceeds a threshold.
30. The method of claim 24 further including calculating a true
transmitted energy.
31. The method of claim 24 further including gradually increasing
the input power.
32. The method of claim 31 further including reducing the input
power if a sensed output quantity exceeds a threshold.
Description
PRIORITY CLAIM
[0001] This Application is a Continuation of U.S. patent
application Ser. No. 14/637,930, filed Mar. 4, 2015, and now
pending.
BACKGROUND OF THE INVENTION
[0002] Human skin consists of three basic layers: the epidermis,
the dermis and the hypodermis. The outer layer of skin is the
epidermis. Epidermis is the thinnest of the layers and contains
mainly stratified squamous epithelium of which the outer side
keratinizes and ensures coverage. The inner side contains a
pigment. The middle layer of skin is the dermis. Dermis consists
mainly of the collagen, elastic and reticular fibers. The bottom
layer of skin is the hypodermis. The hypodermis is formed mainly by
blood vessels, lymphatic vessels, nerve fibers, fibroblasts and in
particular adipocytes.
[0003] Increases in average life expectancy, obesity, unhealthy
lifestyles, genetic predispositions and other factors may cause
aesthetically undesirable appearance of the skin. The undesirable
appearance of the skin may manifest itself by excessive volume of
fat, cellulite, skin laxity, loss of elasticity, loss of firmness,
etc. The undesirable appearance is caused mainly by the excessive
volume of fat cells, weakness and/or break down of collagen,
elastin fibers or other known reasons.
[0004] Aesthetic devices delivering an electromagnetic energy have
recently been developed and various invasive and contact approaches
solving undesirable skin appearance are known. However invasive
methods require long recovery time and place high time and skill
demands on practitioners. They also involve strict requirements for
a sterile environment and biocompatibility. Invasive treatments can
be painful and traumatic. Moreover there is always risk of
infection and inflammation of the treated tissue.
[0005] Non-invasive methods which still require contact with the
patient also must fulfill high sterility and biocompatibility
requirements. The operator of a contact device must disinfect or
replace an individual contact part of the applicator before or
during the application, which consumes time of the operator.
[0006] Non-contact treatment eliminates these disadvantages since
it reduces the time required for disinfection, and replacement of
an individual contact part or manipulation along the treated area.
Since the devices do not contact with the patient there is no need
for biocompatible materials.
[0007] Non-contact radiofrequency therapy can be used for reduction
of volume and number of fat cells in the hypodermis, removal of
cellulite, body contouring, neoelastogenesis and neocollagenesis.
Methods of these therapies are described for example in US patent
application number 2014/0249609, incorporated herein by
reference.
[0008] However, engineering challenges remain in trying to optimize
the amount of energy delivered to the skin of the patient during
contactless radio frequency therapy. Current devices for
contactless radiofrequency therapy present the values measured at
the HF generator as the real output values which are directed to
patient, and calculate from these values the energy delivered
during therapy.
[0009] However, a considerable amount of RF energy is
unintentionally converted to other forms of energy in the devices
for contactless skin treatment, due to parasitic effects,
transformation losses, resistivity of various conductive materials,
etc., which limits the amount of output energy.
[0010] The actual therapeutic energy delivered to the patient
varies depending on the impedance of the patient and distance
between patient and the radiofrequency electrode. Since the patient
is not in direct contact with a source of RF signal, the distance
between patient and the radio frequency electrode during the time
therapy is changing. This may be caused either by biological
rhythms such as breathing and heartbeat which cause movements of
the treated tissue or movements during the duration of therapy. The
therapeutic energy delivered may be insufficient due to low
electrical resistance of some patients, and distance changes
leading to creation of electric potential in thousands of Volts on
each symmetrical branch of the non-contact device.
[0011] Accordingly, there is need for improvement of the devices
for contactless skin treatment so as to control the input power in
order to obtain a continuous heating of the target skin and human
tissue and to continuously deliver an optimum amount of energy into
the skin of the patient without causing any injury to the upper or
inner layer of the skin.
SUMMARY OF THE INVENTION
[0012] Devices and methods for skin and human tissue therapy use
non-invasive and non-contact application of electromagnetic waves,
for example in aesthetic medicine. The input power for generating
the electromagnetic waves is regulated depending on measured values
of at least one physical quantity (such as voltage, current or
phase) inside the device or values of one or more physical quantity
measured on or near the patient. Via feedback power control, the
present devices and methods provide for controlled and continuous
delivery of more optimum amounts of energy into the patient and for
overheating protection.
[0013] An electromagnetic field is generated at frequency in the
range of 1 MHz to 100 GHz in a system having a power supply, a high
frequency generator and one or more electrodes. A transmatch may
optionally be used to improve the power transfer by impedance
matching. The transmatch may be placed between the high frequency
generator and the at least one electrode.
[0014] The high frequency generator generates a signal which
further goes to transmatch. The transmatch matches impedance to
avoid formation of standing waves along the transmission cable.
Afterwards the radio frequency signal is supplied to the at least
one electrode. The contactless skin treatment device behaves as a
symmetrical voltage power supply.
[0015] In order to ensure continuous heating of selected tissue
with the optimal energy, the values of at least one physical
quantity between the power supply and the electrode are measured.
The measured values may be subsequently sent to a control unit or
directly to the power supply, which adjusts the input power based
on the measured values. Similarly, it is possible to forward only
the information about exceeding preset threshold value and
accordingly adjust the input power.
[0016] Alternatively, the input power is adjusted based on values
of at least one built-in or external sensor which measure at least
one of the following parameters: temperature, distance between the
electrode and the patient, impedance, electric field intensity.
BRIEF DESCRIPTION OF DRAWINGS
[0017] FIG. 1 is a block diagram of an apparatus for contactless
skin and human tissue treatment with feedback control
GLOSSARY
[0018] In the context of the present disclosure, unless otherwise
stated:
[0019] the "input value" means values of physical quantity before
the input to the high frequency generator.
[0020] the "output value" means values of physical quantity after
the output of the high frequency generator.
[0021] the "input power" means energy which inputs to high
frequency generator.
[0022] the "output power" means energy which outputs the device and
is directed to the patient.
DETAILED DESCRIPTION
[0023] FIG. 1 depicts a block diagram of a device for contactless
treatment of skin and subcutaneous tissue with feedback control of
the input power. The device may include a power supply 1, an HF
generator 2 and at least one electrode 5. The power supply 1 is
connected to power source. The input power of the generated signal
exceeds 40 W, and more preferably 80 W. The HF generator 2 may
generate an electromagnetic field in the range of 1 MHz to 100 of
GHz or optionally other frequencies as well. The 6.78, 13.56, 27.12
and 40.68 MHz; 2.45, 5.80 GHz and all other ISM bands avoid
creating radio interference, as these frequencies are exclusively
assigned as free or open frequencies.
[0024] The output signal from HF generator 2 is subsequently
conducted to the electrodes 5, which may be positioned above the
surface of the skin or applied on dielectric or insulating,
non-conductive material which is in contact with the skin surface.
The device for contactless skin treatment delivering RF energy into
the patient is constructed as a symmetrical voltage power
supply.
[0025] One or more sensors 4 are located between the HF generator 2
and at the least one electrode 5 to measure the values of at least
one physical quantity, e.g. voltage, current or phase shift between
physical quantities.
[0026] A transmatch 3 may optionally be connected by transmission
cable to the HF generator 2. The transmatch 3 adapts the signal
from the RF generator 2 and based on reflection coefficient,
measured for example by SWR meter, matches the impedance so as to
optimize the power transfer and minimize the reflected signal load.
Transmatch 3 is designed to withstand the high power load by using
appropriate electromechanical components as is known in the
art.
[0027] The output signal from transmatch 3 is provided to the
electrodes 5 by transmission cables where parasitic effects might
occur. The undesirable parasitic effects are caused mainly by
internal capacitance of the transmission cables. The parasitic
capacitance is intensified by proximity of transmission cables,
proximity with other conductors or high frequency signals.
Parasitic effects cause reduction of the output power and distort
the values measured by the sensor 4.
[0028] Significant reduction of parasitic capacitance can be
achieved by its material composition and shading of the
transmission cables 8. For example, the parasitic capacitance in
the transmission cables is reduced or eliminated by using an
electric cable with an outer cylindrical conductor and an internal
conductor, where the space between them is filled with dielectric.
Consequently, it is possible to measure values of at least one
physical quantity inside the device more accurately, which allows
the actual power delivered to the patient during therapy to be
determined.
[0029] As shown in FIG. 1 the power supply 1, HF generator 2,
transmatch 3 and sensor 4 can be communicatively coupled by
microprocessor control unit 6. The microprocessor control unit 6
can provide communication with a user interface 7, which may be a
touch screen on the device display.
[0030] The contactless device for treatment of the skin and human
tissue by radio waves causes controlled heating of the designated
areas on the patient. Based on the settings of a treatment device,
for example as described in U.S. Patent Publication No.
2014/0249609, the radio waves cause selective heating of the dermis
and/or the hypodermis. The controlled heating may lead to
remodeling and/or downsizing of a volume of lipid-rich cells and/or
remodeling of collagen tissue and/or remodeling of elastic
fibers.
[0031] However the average impedance of the patient and treatment
electrode changes during therapy due to reasons discussed below,
which may cause inconsistency in the treatment. The impedance of
the patient and treatment electrode can be compared to the
impedance of a series circuit consisting of capacitor and resistor.
Typical capacitance values ranges about 0.1-100 pF and resistance
about 0.1-100 Ohms.
[0032] Since the patient is not in direct contact with the source
of RF signal, the distance between patient and at least one
electrode during the therapy permanently changes. The space between
skin of the patient and at least one electrode is occupied by air
gap or highly air permeable material. The distance between
electrode and patient changes due to movements of the patient and
either by biological rhythms such as breathing and heartbeat, which
cause vibrations or movements of the treated tissue. Small
movements and displacements during the therapy may cause impedance
changes and the signal is not tuned for the whole time of the
therapy. Therefore the output energy directed to the patient and
absorbed by the patient may vary during the therapy.
[0033] The actual impedance depends besides the above mentioned
factors and also on the shape and disposition of the patient and
the amount of adipose tissue. In order to achieve optimal heating
of treated skin or subcutaneous tissue in a patient with low
resistance, it is necessary to increase the supplied power. The
capacitance however causes formation of undesirable high voltage.
The voltage can arise to about few kV in this area. Excessive
voltages influence the quality of treatment process and may lead to
inconsistency of treatment, with variable amounts of energy
consumed in the epidermis layer. High voltage may also cause
interference nearby electrical equipment.
[0034] To overcome these treatment irregularities, in one
embodiment the sensor 4 measures the output values of at least one
physical quantity (e.g. voltage, current) or phase shift between
the physical quantity. In the case of using more than one electrode
the sensor 4 may measure the values between different branches of
the symmetrical signal cables leading to each electrode. The closer
to the electrode the sensor is, the more precise the values can be
measured.
[0035] However when the sensor 4 is placed near the electrode, the
values can be out of scale of common measuring devices, since the
output values can reach several kV. Therefore the sensor 4 may
optionally be placed closely behind the transmatch 3. The values
measured in this part are proportional to the values which are
located close to the electrode of the device and are in the range
from tens to several hundreds of Volts.
[0036] In another embodiment a look-up-table or a correction
function can be used for determination of the output values of at
least one physical quantity even if the values are measured in any
part of the device. The look-up-table can be also used for
determination of the output power delivered into the patient. In a
similar way it is possible to determine the output power delivered
into the patient by a correction function which corresponds to the
transmission characteristics of the device e.g. y=f (x), where
input x represents the measured value of physical quantity inside
the device. Thus by determination of the transmission
characteristics it is possible to place the sensor 4 anywhere
behind the transmatch so as to measure the output value and
calculate the output power which is delivered into the patient.
[0037] The actual power delivered to the patient at a given time
may be calculated according to the formula P=UIcos .phi.. Where the
U is voltage output value, I is current output value, cos .phi. is
a phase shift between voltage and current. Summarization of such
calculations may also provide the operator the true energy
delivered into the patient during the therapy.
[0038] The measured values may be monitored and evaluated even by
the sensor itself or by microprocessor control unit 6, which is
electrically connected to the sensor 4. If the measured value
exceeds a predetermined limit, a feedback signal is sent to the
power supply 1 or HF generator 2 to adjust the input power. The
signal may include information about exceeding a threshold both
qualitative (e.g. yes/no) as well as the quantitative value (e.g. a
real value). The signal from sensor 4 can be transmitted as optical
information by e.g. optical fiber, so as to eliminate the effects
of electromagnetic fields on the transmitted signal.
[0039] A method for contactless skin and human treatment starts by
gradually increasing input power. The initial input power may be,
for example 10 W, and consequently can be increased in
predetermined intervals by an additional e.g. 10 W up to the
maximum input power for a given therapy. Similarly, the input power
can be added continuously. The size of the initial input power, the
abrupt increase or rate of continuous increment can differ
depending on the kind of therapy.
[0040] The input power is gradually increased until the sensor 4
measuring the output values measures an output value greater than
the threshold. When the measured values exceed the threshold, the
input power is reduced to either the last increment or by a value
equal to the amount by which the last measured value exceeds the
threshold. The threshold value of the output quantity can be
adjusted based on type of therapy.
[0041] Since the impedance of the patient is dependent on any
change in the distance between the electrode and patient's skin,
the system is advantageously responsive to such change. Sampling
frequency measurements of the output values of at least one
physical quantity should be higher than 0.01 Hz.
[0042] The duration of therapy may be influenced by the calculated
output power. As an example there may be a predetermined range of
the output power for a specific kind of therapy. Time of therapy
spent within the predetermined range will be counted into the real
time of therapy. Therefore the therapies will be more precise,
since the low/high powers will not be included into the treatment
time.
[0043] According to the yet another embodiment the device for
contactless skin and human tissue treatment is in communication
with the sensor measuring the electric field intensity. Based on
values measured by electric field intensity sensor the input power
is adjusted. Communication links can be both wired and wireless.
The sensor measuring the electric field intensity can be placed in
close proximity to the skin of the patient or directly on the skin,
or it can be built into the device or be an external device. If
electric field intensity exceeds a predefined threshold, the input
power is reduced to either by last increment or by a value equal to
the amount by which the last measured value exceeds the
threshold.
[0044] The skin temperature of the patient may optionally be
measured, with input power adjusted based on a measured skin
temperature. Optimal skin surface temperature during treatment is
between 38.degree. C.-48.degree. C., preferably between 41.degree.
C.-44.degree. C. A sensor measuring the temperature of the skin of
the patient can be placed in close proximity to the skin of the
patient or directly on the skin. If the skin temperature exceeds a
predefined threshold, the input power is reduced either by the last
increment or by or by a value equal to the amount by which the last
measured value exceeds the threshold. Similarly, it is possible to
measure the temperature of the skin and/or human tissue by
contactless methods as in e.g. WO2014114433, incorporated herein by
reference. These may be contact or contactless or invasive method
for obtaining detailed information about the temperature in the
deep layers. A sensor measuring the temperature of the patient can
be built-in or external device.
[0045] A distance sensor can measure the distance between the at
least one electrode and patient. Based on the measured distance
value, input power may be adjusted instantaneously. Optimal
distance between electrode and patient varies depending on
treatment frequency of radio wave, treated area, impedance, and
time duration. The optimal distance may vary over a few tenths of a
centimeter. If the distance exceeds a predefined threshold, the
input power is reduced at either by last increment or by or by a
value equal to the amount by which the last measured value exceeds
the threshold. A sensor measuring the distance between the at least
one electrode and patient can be built-in or an external
device.
[0046] Alternatively a system may control the input power according
to the received impedance values of the patient. A sensor measuring
the impedance of the patient can be built-in or an external
device.
* * * * *