Physical Therapy Lecture outline Main methods of physical therapy: Ø Therapy by mechanical treatment Ø Non-electric thermotherapy – (heating and cooling, hydrotherapy) Ø Electrotherapy Ø Ultrasound therapy Ø Magnetotherapy Ø Phototherapy Appendix: safety aspects of use of electric currents Therapy by mechanical treatment Massages – manual or instrumental Changes in blood circulation, muscular relaxation Rehabilitative exercises increase of body strength and mobility, psychical effects, improvement of body posture Thermotherapy The application of heat is (from biophysical point of view) an intervention in the body thermoregulation. Heat can be delivered to the organism (positive thermotherapy), or taken away from the organism (negative thermotherapy). The body response depends on: - the way of application - heat conduction, convection or radiation (see electrotherapy and phototherapy) - the intensity, penetration ability and duration of the heat stimulus. Non electric thermotherapy causes mainly changes of body surface temperature (to depths of 2 - 3 cm), with electrotherapy we can heat deeper tissues. - the size and geometry of the application area in the case of local application: The tissue temperature increases when the heat input from outside exceeds the heat output. Cylindrical body parts are heated faster when the radius is small. Considering only conduction, the resistance to heat flow increases linearly with the thickness of tissue layers. In cylindrically shaped tissues it increases non-linearly. - the patient’s health (ability of thermoregulation). Thermotherapy The following sources of heat are used in thermotherapy: • Internal (heat produced by the organism itself). • External. Considering the origin and transfer of heat, the thermotherapeutic methods can be divided into five main groups based on: - heat conduction - heat convection - radiation - high-frequency electric currents - thermal action of ultrasound Heat conduction Ø Mainly packs and compresses. According to the extent of the covered body part, they can be total or partial, according to the temperature hot, indifferent or cold, and also wet or dry. Ø The compresses can be dry (blankets, bottles), peloids (mud) and paraffin. Their temperature ranges from 45 to 55 ºC in dry compresses up to 60 - 77 ºC in paraffin compresses. Heat convection – hydrotherapy Ø hydrotherapy encompasses, besides heat effects, also mechanical action (buoyancy, hydrostatic pressure, impacts of water streams, water movement). It acts mainly on the cardiovascular system, vegetative nerves and psychology. Heat helps muscles to relax, reduces pain, accelerates resorption of oedemas. The procedures differ from each other in the way of heat transfer, in the ratio of conduction and convection, and in the degree of homogeneity of heat flux: Ø cold (less than 18 °C), cool (18 – 24 °C), tepid (24 – 33 °C), warm (33 – 36 °C) or hot (37 – 42 °C). Ø Or: hypothermic (10 - 34 °C, 5 min.), isothermal (34 - 36°C, 20 - 30 min), hyperthermic (37 - 42°C, short duration). Ø The effect of the whole-body bath is given mainly by the surface body temperature. After immersion, the body surface is exposed to the actual medium temperature until thermal equilibrium is formed in several millimetres thick water layer, and the effective bath temperature starts to act. Disturbing the layer prevents stabilisation of the effective temperature, that is why the patient should not move during the bath. Whirling baths, underwater massages, hot and cold water jets Sauna Effects of hot (80 - 100°C) air of low relative humidity (10-30%) are utilised, followed by cooling in cold water. Outstanding tonic action. Electrotherapy Conduction of electric currents in tissues Ø Passage of electric current through human body obeys the Kirchhoff’s laws. Tissue resistance varies. The ions are current carriers. Ø We can distinguish two types of tissue electric conductivity. Cytoplasm and intercellular medium behaves like conductors whose resistance does not depend on frequency. Membrane structures have properties of capacitors, i.e. their impedance Z depends on frequency: Resistivity (r) of tissues Tissue polarisation Ø The electric charges present in tissues are not always free, they are often bound to macromolecules which are an integral part of cellular structures and their mobility is limited. The macromolecules behave like electric dipoles – variously oriented – their dipole moments are mutually compensated. Ø The electric dipoles are oriented according to the direction of the outer electric field when it is present – their polarisation occurs. So an inner electric field of opposite polarity arises, and the intensity of the outer electric field is lowered. This turning of polar molecules gives rise to the so-called displacement current. Permittivity e is a measure of this ability. Effects of direct electric current (galvanotherapy, iontophoresis) Ø Continuous direct current (DC) does not stimulate, but can change conditions for that. This effect of DC is called electrotonus and is used in galvanotherapy. Ø Around cathode (-) an increase of stimulation of motor nerves occurs = catelektrotonus. Ø Around anode (+) a decrease of stimulation of sensitive nerves occurs = anelectrotonus. Ø Application in electrotherapy. Ø Electrokinetic phenomena – movement of ions or solvent in electric field – iontophoresis – ions are transported inside the body. Low-frequency AC - electric stimulation Ø The excitability is a general feature of living systems. In mammals, it is best expressed in nerve and muscle tissue. Electric stimulation - ability of tissue to react on electric stimuli. The direct current has stimulating effects only when suddenly changed. Ø The stimulation is a threshold phenomenon, it occurs only after a specific threshold intensity has been reached - the rheobase. Ø The time factor is more important for quantification of stimulation ability: Chronaxie is a time interval necessary for induction of stimulation at the current intensity equal to a two-fold value of rheobase. Ø Any skeletal muscle has a characteristics chronaxie. Changes of chronaxie help to determine the degree of excitability impairment and also the degree of muscle impairment. The shortest chronaxie is found in skeletal muscles (< 1 ms), heart muscle (5 ms), the longest one have smooth muscles (50-700 ms). The chronaxie can be read from the so called I/t curve, the dependence of current pulse intensity on its duration. Ø The skeletal muscle with normal innervations reacts differently on stimulation by electric impulses with rapid onset (rectangular impulses) and with slow onset (triangular impulses). In short impulses below about 10 ms, the I/t curve has the same shape. For longer rectangular impulses the excitability does not change (curve 1) but the excitability for triangular impulses lowers (curve 2). Ø The muscles with damaged innervations (denerved) are not excitable by very short impulses. However, their excitability for long impulses with slow onset increases (curve 3). So arises area of selective excitability („OSD“), which allows stimulation of denerved muscles without stimulation of healthy muscles. Low-frequency AC - frequency dependence of stimulatory action Ø In very low frequencies (< 100 Hz), the stimulatory action grows linearly with frequency. In high frequencies, the growth of stimulatory action becomes smaller and changes in decrease. In the range of 500 - 3000 Hz, the threshold value of stimulating current depends on Öf. The stimulatory action starts to decrease above 3000 Hz and at about 100 kHz disappears fully. Ø High frequency currents have no stimulatory action because the duration of one period is much more shorter than the shortest chronaxie. They have no electrochemical effects either. Electrostimulation Pacemaker Defibrillators Thermal effects of high frequency (HF) currents Ø Mechanism of the HF currents action is based on transformation of the absorbed electric energy into heat Q according to Joule’s law: Q = U.I.t where U is voltage, t is the time of current I passage. This mechanism of heat production depends on the way of HF currents application. Ø Dielectric heating (due to dielectric losses) takes place when applying currents by means of a capacitor field. Ø When using induction fields, heat is produced by the so called eddy currents. Utilisation of high-frequency (HF) electric currents Ø In the case of alternating electric HF currents (>100kHz), the heat effects dominate totally. The heat originates directly in tissues due to dielectric heating, eddy currents or absorption of electromagnetic energy. Ø For HF therapy, international agreements specified the following frequencies: – Short-wave diathermy (27.12 MHz, i.e. wavelength of 11.06 m), – Ultra-short-wave diathermy 433.92 MHz (69 cm), – Microwave therapy 2 400 or 2 450 MHz (12.4 or 12,25 cm) . – HF therapy makes possible deep heating. Three ways of application of HF currents: Ø 1. The tissue is connected in the electric circuit as a resistor by means of contact electrodes – classical diathermy. It is not used in practice today. Ø 2. Tissue is connected as dielectric placed between insulated electrodes – heating in the capacitor field. The heat produced is proportional to the dielectric loss. Amount of heat arising in subcutaneous fat tissue is lower than in the muscles. Ø 3. Use of eddy currents in magnetic field of a coil – inductive heating. An insulated cable is wound round a limb or a coil is laid to the body. The skin is less heated, 2 cm thick muscle layer lowers the heating to one half. Different ways of HF diathermy Short-wave diathermy – heating in capacitor field Microwave therapy Source: magnetron. The oscillations of electromagnetic field are led to an emitter - a dipole with a reflector. 1 cm of muscle is enough to lower the intensity to one half, the relation between heat production in the skin and the muscles is almost equalised. Microwaves put electrically charged particles (ions, dipoles) into oscillatory motion which is transformed into heat by friction. Microwave diathermy Potential risks of microwave and radiofrequency radiation Ø Mainly thermal effects. Ø Microwave sources Ø Radars Ø Cell phones Ø Radio and TV transmitters Ø Electric mains Ø Trolley lines (wires) Ø Some studies showing carcinogenic effects of microwaves or low-frequency electromagnetic fields were not verified sufficiently, but it is prudent to reduce exposures. Ultrasound therapy Ø Ultrasound therapy is based on biological effects of ultrasonic oscillations which are not electric. Despite of that, this therapy is sometimes included in the list of electrotherapeutic methods. Ø An ultrasound (US) therapeutic system consists of two main parts: generator of HF electric current and the application probe, the US source itself, which consists of a piezoelectric transducer. Ø In therapy, f = 0,8 - 1 MHz is used, sometimes up to 3 MHz, with intensity of US - typically 0.5 - 1 W.cm^-2 . Exposure time is 5 - 15 min., in 5 - 10 repetitions. US can be applied continuously or pulsed. Ø The main therapeutic mechanism is high-frequency massage of tissue. Additional effects are caused by tissue heating (causing hyperaemia) and some physico-chemical effects. Ø Acoustic coupling between the probe and the skin is secured by an oil or gel (local application) as well as water (underwater application). Ø Main indications of US therapy: chronic joint, muscle and neural diseases. Limited success is reported in healing wounds after surgery, healing injuries and varicose ulcers. Thermal action of ultrasound Ø In US therapy, thermal dissipation of acoustic energy takes place. Tissue heating depends on physical properties of tissue and its blood supply. The highest heating appears at the interfaces between tissues of very different acoustic impedances. Ø The thermal action of US cannot be considered without respect to other healing mechanisms (micromassage etc.) US - THERAPY Effects of magnetic fields - magnetotherapy Ø Basic concepts: magnetic fields: static, alternating and pulsed. Homogeneous and non-homogeneous magnetic fields. Ø Magnetic flux density B depends on the magnetic permeability of the medium m: m = m[r].m[0] – Ferromagnetic substances - m[r] >>1. – Diamagnetic substances - m[r] is slightly lower than 1 – Paramagnetic substances - m[r] is slightly higher than 1. (m[0] is permeability of vacuum – 4p.10^-7 N.A^-2) Ø Body tissues are composed almost only from diamagnetic and paramagnetic substances. Magnetic fields can induce electric voltages and currents in biological medium (due to action of Lorentz force on moving electrical charges, or by action of Faraday force in varying magnetic fields). The induced voltages are, of course, substantially lower than the membrane potentials. Magnetomechanical and magnetochemical effects Ø In a strong mg field, the diamagnetic and paramagnetic molecules orient themselves to minimise their free energy. In non-homogeneous fields with big gradients, a translation movement of ferromagnetic compounds takes place (in living organisms negligible). A strong mg field would reduce the flow rate of laminar streaming in a tube. Ø Further, it is necessary to consider indirect action as well, mediated by free radicals arising as a consequence of magnetochemical reactions. Ø We can say that a stable magnetic field of high intensity inhibits metabolic processes, but a varying one stimulates them. These changes are transient. Ø The interactions of magnetic fields with human tissues are utilised in both diagnostics and therapy. Magnetotherapy is an example of healing procedure. Magnetic stimulation of brain can be used both in diagnostics and therapy. Magnets in medicine Transcranial magnetic stimulation Phototherapy Ultraviolet (UV), visible (VIS) and infrared (IR) light sources are commonly used in medicine, namely in physical therapy. Light radiation Ø ultraviolet (UV) 1- 380 nm: UV-A 380 - 315 nm UV-B 315 - 280 nm UV-C 280 - 190 nm Ø visible (VIS) 380 - 780 nm Ø infrared (IR) 0.780 - 1 mm: IR-A 0.78 – 1.4 µm IR-B 1.4 – 3.0 µm IR-C 3.0 µm – 1.0 mm Ø From a practical point of view, the ultraviolet range begins from the wavelength of 190 nm. The spectral range 1 - 190 nm is so called vacuum UV radiation. It is attenuated strongly even by air and hence its biological effects are rare. Sources of light Ø The only natural source is the Sun. Ø The other sources are artificial and each of them emits only one part of the optical spectrum: Ø Hot objects. The wavelength of radiation depends on source temperature, its spectrum is continuous. Light bulbs and various sources of radiant heat. Ø Luminescent sources (fluorescent lamps and tubes). They are based on excitation processes in atoms and molecules. Spectrum of these sources can consist of individual spectrum lines. Ø Both these sources emit non-coherent radiation. Ø The only artificial source of intense coherent light is the laser. Sources of visible light Molecular mechanisms of biological effects of light Ø Energy of single atoms depends on its electron configuration. Delivery of energy causes electron jumps to higher energy levels (DE[e]) – an excited state arises. Absorption spectrum is not continuous. The excitation takes place mainly in the valence shell. Ø Energetic states DE of a single molecule are, in principle, sums of electron energies DE[e] corresponding to the electron configuration, vibration energy DE[n] and rotation energy DE[r] : DE = DE[e] + DE[n] + DE[r][] [ ] Ø All the three kinds of energy are quantised. The action of the radiation depends on photon energy. The lowest energy have photons of IR-C, it corresponds to the changes of rotation energy of molecules. The energy of IR-B and IR-A photons can influence both the vibration and rotation of molecules. The energy of VIS and UV photons can influence rotation, vibration and also electron configuration. Effects of visible light Ø Photosynthesis ?biochemistry Ø Photoreception biophysics of vision Molecular effects of ultraviolet radiation Ø Considering compounds of biological importance, the most sensitive are those with conjugated double bonds. Ø In proteins, the most sensitive amino acids are tyrosin and tryptophan. (abs. maximum around 280 nm). Ø In NA, the N-bases are sensitive. Their absorbance is higher than the absorbance of proteins, maximum at 240-290 nm. Ø UV radiation penetrates only into the surface layers of the skin Ø The skin effect of UV light manifests itself as reddening – erythema – followed by melanin pigmentation Þ protecting mechanism against further penetration of UV. Synthesis of vitamin D which controls metabolism of Ca and P (its lack causes rickets - rachitis), is an important positive effect of UV light. We cannot also exclude the carcinogenic effect of UV since almost 90% of skin cancer appears on uncovered areas of the skin. Sources of ultraviolet radiation Ø Sun Ø Mercury discharge tube (used in medicine) Ø Hydrogen or deuterium discharge tubes (used in research) Ø Xenon lamp Ø Electric arc, lightning etc. Ø Some lasers Penetration of UV radiation Effects of ultraviolet radiation on living organisms Ø Sunburns - erythema Ø Effects on eye: blepharospasm (uncontrollable closure of eye lids) – originates due to damage of cornea by UV radiation. Þ protection by goggles with UV filter. Lens cataract can arise (Fig.↓) Ø UV-C with wavelength below 280 nm has outstanding bactericidal action. Þ sterilisation of labs, special boxes and surgery rooms. Sources and effects of infrared light Ø All the three ranges of IR radiation have thermal effects. • IR-A is involved in sun light. It passes through glass and is only little absorbed by water. • IR-B is emitted from various lamps and discharge tubes. It passes through glass but is well absorbed by water. • IR-C is emitted from heater, hot bodies, humans…. Absorbed by glass and water. Ø Almost all IR radiation is absorbed by skin. It causes local vasodilatation and thermal erythema which looks like diffuse red patterns and, in contrary to the erythema caused by UV light, its duration is short. Pigmentation is very weak. The irradiation by IR light, however, increases skin sensitivity to the UV light. Ø A long exposure of eyes to the IR radiation can cause in some professions (glass-blowers, founders, smelters, steelmen etc.) the so called heat cataract (opacity of the lens). IR radiation heat transfer Heat action of the visible and IR light from artificial sources: Ø Lamp boxes – radiation heat in enclosed space. Skin receptors are stimulated, whole-body heating occurs. Ø IR lamps: Solux, Sirius - high-power lamps with blue or red filters, radiators of IR light. The radiation is absorbed mainly in body surface. Used mainly in dermatology, ORL and dentistry. Skin receptors are stimulated, suggestive feeling of heat, reflex vasodilatation and muscular relaxation takes place. Penetration of IR radiation Lowering light intensity to 35 % of original value Thermal Erythema Thermal erythema – erythema as a consequence of excessive use of electric pad - Summary – effects of light Non-thermal hazards of electric currents Ø The effects of alternating currents (mainly 50Hz) are more serious than the effects of direct currents. In currents above 10 kHz, the danger of non-thermal injury is small. Ø The danger of injury depends on voltage, internal resistance of the source and body resistance. Sources with large internal resistance (e.g. TV screens) are not too dangerous because the short circuit current is very low. Ø Electric network (mains) and the sources with a small internal resistance represent main hazard. In high humidity, the skin resistance decreases, and the danger of injury becomes much higher. Injuries caused by electric currents Ø The so called bipolar contact (when the circuit is formed only by source and human body) is very dangerous. Current goes through human body. Ø In the unipolar contact, insulation from the Earth (shoes) plays an important role. Current can go to the Earth through human body. Ø Brain, respiratory organs (mainly respiration centres and muscles) and heart are the most sensitive body parts. Ø The safe value of current which can without endangering our health pass through the body, is about 10 mA in alternating currents below 1 kHz, in the direct currents about 25 mA. Ø Critical value of alternating current at which it is still possible to release hold on a conductor is about 20 mA. Injuries caused by electric currents Ø Currents above 25 mA can cause respiratory failure, currents above 25 - 80 mA can cause a reversible cardiac arrest with death danger. Above 80mA, number of deadly injuries increases. Ø The currents above 1A have fully irreversible consequences (death). Ø To stimulate a muscle, the current must pass along the muscle fibres. In the heart, the fibres are oriented in many directions so that always only part of them is affected. This results in uncoordinated contractions of myocardium (extra-systoles), in higher values of currents (100-200 mA) ventricular fibrillation occurs. Author: Vojtěch Mornstein