From
the collection of the
zj
nTTr"^
o
Prelinger av
JLJibrary
San Francisco, California 2006
By
the
same author
A MANUAL OF PHYSICAL THERAPY12mo, 309 pages, with 118
engravings
LEA
&
FEBIGER
PHILADELPHIA
a
O
E o
ELECTROTHERAPYAND
LIGHT THERAPYWITH THE ESSENTIALS OF HYDROTHERAPY AND
MECHANOTHERAPY
BY
RICHARD KOVACS,
M.D.
PROFESSOR OF PHYSICAL THERAPY, NEW YORK POLYCLINIC MEDICAL
SCHOOL AND HOSPITAL ATTENDING PHYSICAL THERAPIST, MANHATTAN STATE,
HARLEM VALLEY STATE, COLUMBUS, AND WEST SIDE HOSPITALS; VISITING
PHYSICAL THERAPIST, NEW YORK CITY DEPARTMENT OF CORRECTION
HOSPITALS; CONSULTING PHYSICAL THERAPIST, NEW YORK INFIRMARY FOR
WOMEN AND CHILDREN, MARY IMMACULATE HOSPITAL, JAMAICA, N. Y.,
HACKEN8ACK HOSPITAL, HACKEN8ACK, N. J., ST. CHARLES HOSPITAL, PORT
JEFFERSON, L. I. ALEXIAN BROTHERS HOSPITAL,ELIZABETH, N.J.
Fifth Edition, Thoroughly RevisedIllustrated with
352 Engravings and a Color Plate
LEA & FEBIGERPHILADELPHIA
COPYRIGHT
LEA & FEBIGER1945
Reprinted
OCTOBER, 1946
PRINTED IN
U. S. A.
PREFACE TO THE FIFTH EDITIONTHEfive successive editions of
this
work
reflect
the steady expansion
of the use of physical energies for treatment during the past
fifteen years. Its contents are based on the subject matter of the
author's instruction
courses, given first under the auspices of theof
Columbia University School Medicine at the Reconstruction
Hospital in New York and since 1927 at the New York Polyclinic
Medical School and Hospital. Electrotherapyandlight
of physical
therapy have been always the main forms for office employment
treatment agents by physicians because of their fairly
simpleefficiency.
control
and
ELECTROTHERAPY AND LIGHT THERAPY was writtenon the theory and
practice of these The intervening years have brought
primarily to offer reliable information
two important therapeutic agents. about the development not only
of new phases of the original subject but also a steady increase in
the use of treatment procedures by water, exercise
and manipulation. Some of these methods require very simple
equipment or none at all except the knowledge of how to use them,
which makes itpossible to give patients their benefit at the
bedside as well as in the
In order to furnish information about these methods, with the
fourth edition of this work, the essentials of hydrobeginning
therapy and mechanotherapy were included in the
presentation.physician's office.
The
story of the progress of ''physical medicine" as part of the
practice
of medicine, in the period of the past twenty-five years
during
which the
author has been actively engaged in it, is an impressive one. In
the United States up to the time of the World War I, the few
medical men practicingas "electro therapists'5
were looked upon by
many of then* medical
brethren
with suspicion, mingled with pity. Hydrotherapy, manipulation
and were mostly exploited by poorly educated technicians. Generally
massagespeaking, there were no physical therapy departments in
hospitals where the different physical methods could be correlated
as part of a general
be carried on.after
therapeutic scheme and where clinical and laboratory research
could This situation first changed for the better during and
World War I, by the creation of broadly conceived physical
treatment departments in order to benefit those injured and
disabled in that war. In these departments all the time-honored and
many of the newmethodsof physical therapy
were practiced under the watchful eyes of
competent medical men.
After the
War
there
became available a
large
bodytheir
of
competent technicians and ain civilian practice
number
of physicians
who
continued
work
and under
this impetus,
development of
many new and efficient physical therapy methods took place.
Groups of medical men and technicians organized for mutual
cooperation and study(5)
6
PREFACE TO THE FIFTH EDITION
and the medical profession at large showed much interest in
physical therapy. The American Medical Association created in 1927
a Council of Physical Therapy which became a potent factor in
disseminating proper information, in advocating basic training in
physical therapy, and incurbing unwarranted claims and
commercialization. As a result of all these factors, in the years
up to World War II there was constant progress ineducation,
research, and in the development of
expansion of clinical application of physical therapy.
new methods and the The lines of demarcaby general
tion between physical therapy that can be effectively carried
onpractitioners,
by
specialists in various
departments of medicine and by
medicine" became gradually established. World War II thus found
physical therapy ready for further expansion and for its fullest
utilization for the benefit of war casualties. No wonder that the
number of physical therapy departments and training centers in Army
and Navy hospitals and other service and rehabilitation
centersspecialists in "physical
time high. The need for caring for the injured, convalescent and
those to be rehabilitated has made physical therapy methods the
cornerstone of this work and also by practical necessityhas reached
anall
brought occupational therapy in close correlation to it. All
this is likely to continue for many years to come. At the same
time, the term Physical Medicine became officially adopted in
connection with the greatly increased
Medical Association, in renaming in 1944
scope of physical methods for treatment and diagnosis. The
American its Council on Physical Therapy
the Council on Physical Medicine, stated: "Physical medicine
includes the employment of the physical and other effective
properties of light,heat, cold, water, electricity, massage,
manipulation, exerciseical devices for physical
treatment of disease."
and mechanand occupational therapy in the diagnosis and In the
same year a great American citizen and
humanitarian appointed the Baruch Committee on Physical
Medicine, and after its extensive survey of the needs of this
branch of medicine
he donated a fund of over a million dollars to carry out the
most Simultaneously, the urgent educational and research
requirements.National Research Council and the National Foundation
for InfantileParalysis alsoof all these
made grants for research in physical medicine. As a result new
developments, prospects for large scale increase in
instrucandclinical application of physical
tion, research
medicine in the near
future are indeed bright. In the fifth edition of this
work a concise presentationis
of all present
day
phases of physical medicine
offered, while special
emphasis on electro-
therapy and light therapy is being retained. In this volume the
newer uses and methods of electronics, of electrodiagnosis, of ion
transfer, and of ultraviolet radiation have been incorporated; the
chapter on exercise has been considerably enlarged; a
new
PREFACE TO THE FIFTH EDITION
7
chapter on hypothermy has been added, and a revised glossary
inserted,pertaining to definitions of electrotherapy and light
therapy as well as to muscle and nerve action, and mechanotherapy.
All chapters in the general as well as in the special part
seven
new illustrations The author is deeply
have been brought up to date. were added and 49 obsolete ones
omitted.grateful to
Eighty-
many
laboration. Drs. R. V.
Gorsch (now serving as Colonel
medical friends for their colin the U. S. Army),
serving as Commander in the U. S. Navy), and have revised their
special chapters. Dr. F. W. EwerDr. Hans Behrend hardt contributed
to the Glossary, Dr. Arthur L. Watkins to the chapter on
W. W. Morrison (now
Electrodiagnosis, Dr.
Jerome Weiss reviewed the chapters on physics and Dr. Robert
Schlesinger again skillfully furnished a number of schematic
drawings. A number of authors permitted reproductions of their
illustrations and the educational and technical departments of the
electromedicalindustry again assisted in furnishing technical data
and illustrations. credit for all these contributions appears in
the text.
Due
most liberal and cooperative in producing a volume profusely
illustrated and typographically excellent. R. K. NEW YORK CITY
The
publishers were again
CONTENTSCHAPTERPhysical Therapy in the Practice of Medicine
Basis of Physical Therapy Scope of Physical Therapy Place of
Physical Therapy Classification of Physical Therapy Methods
Apparatus for Physical Therapy Electrotherapy and Light
TherapyI
INTRODUCTION23 23 26 27 27 28 29
PART
I
ELECTROPHYSICSCHAPTERThe TheStructure of Matter and the Atomic
Theory Electron Theory of Matter
II
FUNDAMENTAL ELECTROPHYSICS
'.....
3031
Charge The Elementary Law of Electrophysics Conductors and
Insulators Transfer of Electrical Charges Charging by Contact and
by Induction CondensersStatic Electricity Current Electricity
Electric Current Effects of Current Electricity Thermal Effects
Electromagnetic Effects Chemical Effects Electrical Units Unit of
Current. The Ampere Unit of Resistance. The Unit of Electromotive
Force. The Volt
Electric
.
Ohm
Difference Between Amperes and Volts Ohm's Law Unit of Power.
The Watt Unit of Capacity. The Farad Measuring and Regulating
Devices Ampere Meters and Voltmeters Measuring Power in Alternating
Current.
.
:
t
Circuits
Rheostats'
.
32 32 33 34 34 34 36 38 38 39 39 40 42 44 44 44 45 45 45 46 46
47 47 49 49
CHAPTERChemical Generation of ElectricityCells
III
GENERATION, CONVERSION AND DISTRIBUTION OF ELECTRICITY
and Batteries
51 51
Mechanical Generation and Conversion of Electricity
The Dynamo The Electric Motor The Faradic Coil The Transformer
The Rotary Converter (8)
53 53 53 54 55 55
CONTENTSElectric Oscillations
956 57 57 5961,
and Waves
.
.
....'...
Electronics.
-
.
/
Thermionic Emission Vacuum-electronic Devices Gas-filled
Electronic Devices . , The Electron Microscope Electrical Current
Supply in Homes and Office Measuring and Protecting the House
Supply The Role of Fuses Locating Trouble Current Outlets.
....../...PARTII
...-.-.
'.
62 62 63 63 64 65
GENERAL ELECTROTHERAPY AND ELECTRODIAGNOS1SCHAPTERGeneral
Considerations Classification of Currents Direction and Frequency
of Flow Voltage or Tension.
IV
ELECTROMEDICAL CURRENTS, APPARATUS AND ACCESSORIES.
....
.
Amperage or Volume Electromedical Apparatus Typical Features of
Apparatus Conducting Cords and Cables Electrodes Miscellaneous
AccessoriesTreatment TimersPatient's Release
Foot Switches ;...''.' Treatment Tables and Couches
...:..... ............. ...CHAPTER V
.... .... .... .... .... ....
66 67 67 68 68 68 69 6971
76 76 76 77 77
EFFECTS OF ELECTROMEDICAL CURRENTS. PASSAGE THROUGH THE BODY.
GENERAL RULES OF TREATMENTPrimary Physical EffectsIonic Effect
Thermal Effect Specific Electrical Effects Secondary Physiological
Effects Psychological Effects.
78 78 79.
.
.
.
..
82 82 82
Electric
Conduction Through the Body Resistance of the Skin Skin
Resistance to Different Currents Practical Importance of Skin
Resistance Changes in Skin Resistance Resistance of Other Tissues.
.
......,.
....,
Dielectric Conductivity Passage of Currents Through the
87
Body.
Current DensityInfluence of the Size and Position of Electrodes
. General Rules of Electrical Treatment Method of Procedure
Position of Patient Inspection of Parts Placing of Electrodes and
Cords Starting the Treatment Regulation of Current Strength
Termination of Treatment.
......
.
.
.....
.
95
10
CONTENTS CHAPTERVI97 97 97 98 100101 101 101 101
ELECTROPHYSIOLOGYBioelectric
Phenomena
Action Currents Action Currents of Skeletal Muscles Action
Currents in Nerves Injury Current Action Currents of the Heart and
the Brainof Bioelectric Phenomena Electrical Stimulation of Nerves
and Muscles Nature of Nerve Impulses
....
.
.
.
.
.
Theory
.
.
Stimulation by Direct Current Electrotonus
.102.
Nerve Block
.
.
Electrical Excitability
Strength-Duration Curves Chronaxie Progressive Currents
Intensity-Frequency Relation
....
103 104 104 104 104 105 105
CHAPTERGeneral Considerations Motor Points
VII107 108 109 110 Ill 112 113 114
ELECTRODIAGNOSISApparatus and Accessories General
TechniqueDifficulties in Testing Testing Charts Faradic and
Galvanic Test Reaction of Degeneration Course of the Reaction of
Degeneration Diagnostic Significance of the Prognostic Significance
of the Testing for the Reaction of Degeneration The Polar Formula
Diagnostic Limitations Other Changes in Electrical Reactions
Increased Excitability
RD RD
.116 .116119 120 120 121 121 121 121 123 123 125 126 127 128
Diminished Excitability
Newer Methods of Electrodiagnosis Testing by Strength-Duration
Measurements Testing by Chronaxie MeasurementTechniqueTesting by
Progressive Currents Electromyographic Diagnosis
CHAPTERHistorical
VIII134 134 138 139 139 141 143 143 143 144 146 149 149 149 150
150 150
THE GALVANIC CURRENT AND ION TRANSFERPhysics and
ApparatusPolarity Effects of the Galvanic Current Physical Effect
Physiological Effect
Upon
the
Body
Therapeutic Forms Medical Galvanism General Technique.
'
Dosage and Length of Application The Galvanic Bath Electrolysis
or Surgical Galvanism
Removal of Superfluous Hair Skin
BlemishesHemorrhoidsStrictures.
Galvanic Acupuncture
CONTENTSIon Transfer or Iontophoresis Physicochemical
Considerations Leduc's Experiments Penetration of Ions Clinical
Uses of Ion Transfer General Technique A. Applications From the
Positive Pole Heavy Metals
11151 151 151
.......
r
.
.
Vasodilating Drugs
Histamine Mecholyl Cocain EpinephrineAconitine
CalciumB. Applications Chlorine Iodine.
...... From. .
152 153 153 154 154 155 155 156 159 159 159 159 159 160 160
160161
tHe Negative Pole
.159
Salicylic Acid Dangers in Galvanism fety Rules in Galvanism
CHAPTER IXCURRENTS OF Low FREQUENCYHistorical
General Considerations Physics and Physiological Effects The
Interrupted Galvanic Current The Faradic Current The Surging
Faradic Current The Slow (Galvanic) Sinusoidal Current The
Modulated Alternating or Interrupted Sinusoidal Current
Low-frequency Apparatus Motor Generators Generators of Thermionic
Tube Types Single Types of Low-frequency Apparatus Therapeutic
Aspects of Electric Muscle Exercise Clinical Application of
Low-frequency Currents Simple Muscle Weakness Paralysis Following
Nerve Injuries or Anterior Poliomyelitis Miscellaneous Indications
Choice of Current for Muscle Stimulation Special Forms of
Low-frequency Currents The Leduc Current Galvano-faradization
Condenser Discharges by Progressive Currents General Technique of
Low-frequency Stimulation Individual Motor Point Stimulation Group
Stimulation of Muscles Dangers of Application.
...
.
163 163 164
,164
.
.....
165 167 168 169 169 170171
.
176.
177 177 179
.179179 180
...
.
Static Electricity
History Physics Physicophysiological Effects
.
...
183 184 184 184 185
CHAPTER XHIGH-FREQUENCY CURRENTS AND APPARATUSGeneral
ConsiderationsHistorical
187.
High-frequency Oscillations and Radiowaves Physics of
High-frequency Apparatus.
Basic Principles
Vacuum-tube Apparatus Power Supply Circuit
.
The The
Oscillator Circuit Patient's Circuit
Two-tube Short-wave Circuits Controls of Vacuum Tube
Apparatus
19o
12
CONTENTS197.
Spark-gap Apparatus Operating the Spark-gap Apparatus
The Oudin
Coil. .
Combination Apparatus Requirements for Acceptance of Diathermy
Apparatus Protection Against Radio Interference by Electrical
Apparatus High Frequency Treatment Methods
199 200 203 200201
232
CHAPTER XIMEDICAL DIATHERMYGeneral Considerations Experimental
Demonstrations.
Thermal Effect of Diathermy Heating by Direct ContactHeating in
the Electric Field Heating in the Electromagnetic Field Heating in
Relation to Wave LengthPhysiological Effects of Diathermy Effects
on Circulation Effects on the Nervous System Effect on Bacteria
....
205 205 206 207 208 208211
^
.....210 213.
.
.
Diathermy vs. Long- wave Diathermy Contraindications and Dangers
of Diathermy General Technique of DiathermyShort-waveGeneral
Considerations Regulation of Dosage Duration and Frequency of
Treatment Technique of Short-wave DiathermyElectrodes Electric or
Condenser Field Heating Electromagnetic or Coil Field Heating
Direct Contact Heating
Clinical Uses of
....
....
....
.....
....
Technique of Long-wave DiathermyTheir Position and Size The
Reading of the Milliampere Meter Regional Technique of Diathermy
BrainElectrodes
.....
Eyes
Head Neck
Sinuses
Dorsal and
Lumbar Spine
Coccyx Organs of the Chest and Abdomen Abdominal Organs Male and
Female Organs Rectal Diathermy Shoulder and Upper Extremity. .
.
.
^
..
Elbow , Wrist and Hand . Hip and Thigh Knee Ankle and Foot
Sciatic Nerve \ Safety Rules in All Diathermy Treatments Special
Precautions With Short-wave Diathermy Special Technique With
Long-wave Diathermy General Diathermy.
.... . .
.
.
,
.
.
.
.
..
.
v..
.
.
.
..
.
.
.
.
.
.
.
'
.
.
.
.
..
.......'
.
.
.
.
.
Autocondensation Monoterminal High-frequency (Oudin) Treatment
Combination of Low-frequency Currents With Diathermy
.
.
.
.
.
.
213 214 215 216 217 218 218 218 219 220 220 220 222 223 225 225
226 227 227 228 229 230 231 231 231 232 233 233 233 235 235 236 236
238 238 239 240 240 240 240 242 243
CHAPTERGeneral Considerations Methods of Inducing Hyperthermy
Hydriatic MethodsElectrical
XII HYPERTHERMY.
Methods
Requirements for Fever Apparatus
245 246 247 247 250
CONTENTSPhysiological Effects Bactericidal Effects Clinical Use
of Hyperthermy
13251 253 253 253 254 255 255 255 255 255 255 255 256 256 257
257
Gonorrhea andSyphilis.
Its
Complications
.
Neurosyphilis and Wassermann-fast Syphilis Chorea
Bronchial Asthma Chronic Arthritis Multiple Sclerosis Other
Conditions Contraindications to Hyperthermy General Technique of
Hyperthermy Preparation Initial Steps The Induction Period Period
of Maintenance.
.
.
Treatment Height, Duration and Frequency Complications of
Hyperthermyof.
End
............
.
....
.
of
Fever Sessions
.
Restlessness Heat Prostration
Burns / Herpes Labialis Heat Cramps and Tetany Abdominal Cramps,
Nausea and Vomiting.
259 259 259 260 260 260 260261 261 261 261
.
.
.
.
.
.
.
........
,
.
.
Circulatory Collapse Pathogenesis of Fatal Cases
...CHAPTER.i
I
.
.
.
.
*. .. .,
262
XIII*
ELECTROSURGERYGeneral Considerations HistoryElectrosurgical
Methods Electrodesiccation
and Their Effects
N. .
.
Electrocoagulation Electrosection
Healing of Electrosurgical
Wounds.
Specific Effects on Blood-vessels Advantages of Electrosurgery
Apparatus for Electrosurgery Technique of Electrodesiccation.
....
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
Experimental Practice Operative Technique Technique of
Electrocoagulation.
.
.
.
.
.
.
'.
.
..
Electrodes
Experimental Practice The Role of the Milliammeter Operative
Technique The Use of Biterminal Electrodes Technique of
Electrosurgical CuttingElectrodes
Experimental Practice Operative Technique Hemostasis Underwater
Cutting Cpnization Bipolar Cutting.
........ ......' ............*.
264 264 265 265 265 268 268 268 269 269 272 273 273 275 275 276
277 279 279 279 280 280
.277
.
.
.
.
.
.
.
*
,
.
.
.
.....
281
Anesthesia in Electrosurgery Clinical Uses of Electrosurgery
.
.
Uses of Electrodesiccation Uses of Electrocoagulation and
ElectrosectionCritique
.
283 283 285
CHAPTER XIVELECTRICAL INJURIESAccidents During Electrotherapy
The Equation of the Operator Equation of the Patient Equation of
the Apparatus
287
289
14
CONTENTS290 290 290 290 291 291 292 292 292 292 293 293 294 295
295 297 297
Burns Pathology Burns From Heat Lamps Burns From Diathermy Burns
From Galvanism Burns From Ultraviolet Electric Shock Low-frequency
Current Passing Through Cardiac Area Accidental Contact With a
Grounded Object Transformer Breakdown Mechanical
InjuriesMedicolegal AspectsElectrical Accidents in
Homes and
in Industry
External InjuriesElectrical Shock Injuries to Eyes
Injuries
from Lightning
PART
III
LIGHT THERAPY
CHAPTER XVPHYSICS OF RADIANT ENERGYGeneral Considerations Theory
of Radiant Energy Classification of Radiant Energy'
299 300...
.301302 303 304 305 306 306 308 309
Measuring
Wave Length
Spectroscopic Comparison
Physical Phenomena The Inverse Square Law The Angulation of Rays
(Cosine Law)
Common
Measuring Radiant Energy.
Penetration
Comparative Physical Effects Comparative Physiological
Effects
CHAPTER XVIINFRARED AND LUMINOUS RADIATIONPhysical
Considerations Long-wave Infrared Short-wave Infrared Sources of
Infrared Radiation Sunlight
311 311
312 312
Heat LampsInfrared RadiatorsElectric Light Baths Physiological
Effects of Infrared and Luminous Radiation Physiological Effects of
Infrared Radiation Effect on Circulation Effect on Nerve Endings of
the Skin General Effects Physiological Effects of Visible Radiation
Clinical Use of Local Heat Radiation.
313 315316 317
.317
Choice Between Luminous and Non-luminous Radiators Technique of
Local Radiant Heat ApplicationClinical
....
320321
Precautions Use of General Heat Radiation Indications.
.321321 322
Technique
CONTENTSCHAPTER XVIIULTRAVIOLET
RADIATIONGenerationClassification
15
PHYSICS AND EFFECTS325 325 325 326 326 327 327 327 328 328 329
329 330 330 332 332 333 333 333 334 334 335
Physical Properties Physiological Effects of Ultraviolet
Radiation.
Erythema Production Degrees of ErythemaHistological Changes
Difference in Erythema Effect of Certain Wave-lengths Biological
Explanation of Erythema Erythema Reaction as a Measure of
Effectiveness of Ultraviolet Radiation
PigmentationAntirachitic Effect Bactericidal Effect Effects on
Blood Effects on Metabolism Clinical Uses of Ultraviolet
Radiation
;
Metabolic Disorders Tuberculosis Skin Conditions Miscellaneous
Conditions Contraindications to Ultraviolet Radiation
Photosensitization
CHAPTERHistorical Physics of Solar Radiation Clinical
Considerations of Heliotherapy Technique of Heliotherapy
XVIII
HELIOTHERAPY337 337.
Well People and Children Ultraviolet Transmitting Window
Glass
Sun Bathing
in
....
340 343
CHAPTER XIXARTIFICIAL ULTRAVIOLET THERAPYGeneral
ConsiderationsHistorical
Carbon Arc LampsConstruction Radiation Characteristics Relative
Advantages and Disadvantages Quartz Mercury Vapor Arcs Hot Quartz
Lamps Cold Quartz Lamps Low-pressure Mercury Arcs Electrpdeless
High-frequency Induction Lamps Combination of Hot Quartz and
Infrared Units Choice of Ultraviolet Generators and Standards of
Emission Standards of Emission.
346 346 347
350 350 350354 356 358 358 35936(36. 36(
Technique
of Ultraviolet Irradiation
Administration
DosageSpecial Techniques of Ultraviolet Irradiation Local
Irradiation
The Finsen TreatmentUltraviolet Blood Irradiation Air
Sterilization
357'
Physics of GermicidalPractical Uses
Lamps
372
16
CONTENTS
PART
IV
ESSENTIALS OF HYDROTHERAPY
AND MECHANOTHERAPY
CHAPTER XXHYDROTHERAPYGeneral Considerations Physical
PrinciplesPhysiological Principles Cold Applications Hot
Applications Applications of Slowly Increasing Temperature;.
....*...
.
Hydrothermal Measures Wet Compresses Wet
PacksAblutionsSpecial
.
*
Hot and Cold Baths Forms of Baths
374 374 375 375 376 376 377 377 377 379 379 384 384 384 385
387
Hydrokinetic Measures
..... .
Douches and Showers The Whirlpool Bath Therapeutic Pools and
TanksColonic Irrigation
... ... ....,
....
.
.
CHAPTER XXIHYPOTHERMYGeneral Considerations*
Methods
of
Hypothermy
Physical and Physiological Effects
Therapeutic Considerations Cold Injuries .. .
... ... ..... .... .
388 389 393 394
.
.
...
.
.
CHAPTER XXIIGeneral Considerations. .
....
MASSAGE
Massage Movements
........... . .
.
Physiological Effects of Massage Effects of Massage on
Pathological Conditions
..
.
.
.
.
.
.
.
.
General Technique of Massage . Uses of Massage Traumatic
Conditions .'' Arthritis and Rheumatic Conditions Disorders of the
Digestive Tract Disorders of the Nervous System Cardiovascular
Conditions .' Other Systemic Conditions..
.....
.
.
.
.'.';
.
..
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.
.......
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..'....... .
.....
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.......
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. .
..
..
; ,
.
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.
.........
.
.
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...
400 405 407 407 408 409 410 410 410 410411.
.
.
.
Contraindications to Massage
.
.
.
.
.
.
....
.
.
.411
CHAPTER XXIIIEXERCISEGeneral ConsiderationsPhysiological
Effects.
.
.
..
.
.
General Technique of Exercises Exercise in Various Conditions
Circulatory System.
.
.... .... .............. ....... .
.
.
.
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,
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.
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..
,.
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Respiratory SystemGastro-intestinal.
.
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....
~
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_....
...
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. .
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System.
.... ...
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..
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Nervous System : Injuries of Bones and Joints.
..
Peripheral Vascular Disease Arthritis and Rheumatic Conditions
Contraindications Posture Underwater Exercises.
.
.
..,...*..
.
.
.
.
412 412 414 418 418 418 420 420 420 420 420 425 425 429
CONTENTS
17
PART VAPPLIED PHYSICAL THERAPYCHAPTER XXIVCARDIOVASCULAR
CONDITIONSReviewGeneral Considerations of Physical Measures in
Cardiac Conditions Rest and RelaxationExercise.
Massage and Passive Exercise HydrotherapyElectrotherapy.
Angina Pectoris HypertensionExercise in Cardiac Patients.
.
....
.
;
.
,
\..
.
.
.
.
.
.
Hypotension Cardiac Neuroses
.
.
. r.
.
Peripheral Vascular Disease Diagnostic Considerations Review of
Physical Measures in Peripheral Vascular Disease
.
.
.
.
.
Thermal Measures Electrochemical Measures Mechanical Measures.
.
.
.
.
.
.
.
.-.-...'.
"V
.
.
.... .
.
Neurovascular Disorders Raynaud's Disease Organic Vascular
DisordersArteriosclerosis Obliterans
.
.
.
;
Thrombo-angiitis Obliterans (Buerger's Disease) Thrombophlebitis
Acute Thrombosis and Embolism Care of Feet in Peripheral Vascular
Disease. .
..
.
.
-. '--....
.
432 432 432 433 433 433 433 433 434 436 437 437 438 438 439 439
441 441 444 444 444 444 445
.
.445.
.
.
.
.
,
446 446
CHAPTER XXVRESPIRATORY, GASTRO-INTESTINAL AND METABOLIC
CONDITIONSGeneral ConsiderationsBronchitis.
.
.
,': .,
.
.
.
.
.
.........'
PneumoniaErripyemaPleurisy>
.
.
.
.
V%;
".
-
.
.
.
"*. .
Pulmonary Tuberculosis.
.
.....
;
.
.
.
.
.
.
.
:'.
.
".
.
Gastro-intestinal Conditions Gastric Neuroses.
......
.
.,
.
.
.
.
.
.
.
.
ConstipationVisceroptosis
...".,....,
.
448 448 449 450 450 450 452 452 452455
Postoperative.
and
Postpartum. \Yeakness.. ..
of
Abdominal.
Muscles Abdominal Adhesions
.*
...:
:
45.6
Intestinal Tuberculosis
.
.
.
.
.
.
.
.
.
.
.../..
.
Peritoneal Tuberculosis Diseases of the LiverCholecystitis
.
Metabolic Conditions RicketsInfantile
456 456 456 457 457
.457458 458
Tetany
Obesity
CHAPTER XXVICHRONIC ARTHRITIS AND FIBROSITISGeneral
Considerations Role of Physical Therapy 2461
462
18Classification of
CONTENTSRheumatic Diseases Rheumatic Fever Chronic Joint
Changes. ...
....
.
.
.,.
.
..". . .
.
.
.
.
"..,
.
Non-articular Manifestations Grading of Cases Physical Treatment
Measures in Arthritis.
' ."
._.
.
.
.
.
.. .
...'
.
.
.
.
.
Thermal Measures Mechanical Measures Thermal and Mechanical
Measures Counterirritant Measures Thermal and Counterirritant
Measures Spa Treatment Scheme of Physical Treatment..
....
.
.
.
.
.
.
.
.
.
.
.
. ...-.:.
.
.
....
.
.
,
.
..... .....
.
.
.
.
.
.....
,
.
.....'.
.
.
..
.,
....
.
Osteo-arthritis Rheumatoid Arthritis Gonorrheal Arthritis.
.
.....
.
.
.
.
.
,
,
..
.....
^
Spondylitis Deformans (Marie-Striimpell Disease)
Gouty
Arthritis.
Acute Arthritides Tuberculous Arthritis Traumatic
ArthritisFibrositis.
.
.
.
.
.
.
.
.
.
.
.
.
.
...
.
'.
.
.
.
.
.
.
.
.
*
.
..'.:.
PathologyDiagnosis and TreatmentPanniculitisClassification..
.
Treatment
........ .....
.
.
.
.
.
.
,
.
.
.
>.. .
462 462 462 463 463 464 465 467 469 469 470 470 471 472 472 472
473 474 474 474 474 474 474 476 476 477 478
CHAPTER XXVIIAFFECTIONS OF THE CENTRAL NERVOUS SYSTEMGeneral
Considerations Hemiplegia General Paresis Locomotor Ataxia Multiple
Sclerosis. . .
.
.
.
.
.
.
.
.
.
.-*
.>...... . .
.
.
.
.
.
.
.
.
.
.
:
Myelitis
.
.
.
Chorea MinorCerebral Palsy (Spastic Paralysis) Obstetrical
Paralysis Infantile Paralysis
The NeurosesVegetative Neurosis
Traumatic Neurosis Mental Conditions Electric Shock Therapy
.
.
.
.
.
.
'.....-.:..CHAPTER XXVIII
480 482 484 484 485 486 486 486 487 487 493 494 494 495 496
AFFECTIONS OF PERIPHERAL NERVESGeneral ConsiderationsPeripheral
Nerve Injuries Pathology and Diagnosis.. .
....'
.
..
.
',
.
.
.
,
.
.
TreatmentNeuritis
Pathology
.
...'
.
.
.
.
...'...........508.
501 501 501 503 508
.
.
.
Classification Relief of Pain in.
Acute Neuritis
"
Chronic Neuritis Special Forms of Neuritis Facial Paralysis
(Bell's Palsy) Brachial Neuritis Sciatic Neuritis Meralgia
Paresthetica. Trifacial Neuralgia Intercostal Neuralgia.
v
.
.: -
'.
................. ....
.
.
^
.
.
.
.
.
.
.
.
.j*.
.
.
...'....
,
.
.
.
.
.
.
-.;
.
:
.
.j
508 509 510 510 510 514 515 516 516 517
CONTENTSCHAPTER XXIXAFFECTIONS OF BONES, JOINTS, MUSCLES AND
TENDONSTraumatic ConditionsGeneral Considerations General Pathology
of Injuries Objects and Methods of Physical Treatment Injuries of
Joints and Muscles Contusions.
19
"...
.
,
.
'.'.'.',
519 519 519 520521 521 522 522 524 524 525 525 525 528 528 529
529 529 530 531 531 531 532 532 532 533 533 534 534 540
Strains
Sprains Dislocations
Traumatic ArthritisStiff Joints Injuries of Bones..
....
.'
.
.
.
.....
.
.
.
.
.
,
...*,.
.
.
..
Fractures
Amputations
.
.
.
.....
"..'
Back
Injuries
.
.
.
.
...
.
,
.
.
.
Coccygodynia Affections of Bones and JointsOsteomyelitis
Tuberculosis of Bones and Joints Affections of Muscles Acute
Myositis Chronic Myositis Volkmann's Ischemic Contracture
Affections of Tendons and Bursae Tenosynovitis.
Bursitis Superficial Bursae
.:.....
Deep Bursse Shoulder Affections Miscellaneous Surgical
Conditions Adenitis.
.
Burns
.... ...................
Scars Foot Conditions (By Jerome Weiss, M.D.)
'.
.
.
.
.
.
.
.
.
540 540 541 541
CHAPTER XXXGYNECOLOGICAL CONDITIONSGeneral Considerations
General Rules of TechniqueElectrodes Pelvic Heating by Diathermy
Pelvic Heating by Non-electrical Methods Pelvic Iontophoresis
Inflammatory Conditions;..
...
.
.
.
.
Gonorrheal Cervicitis and Urethritis Pelvic Inflammations
Chronic Endocervicitis . Cervical Erosion
.'
...".........
Miscellaneous Conditions Non-inflammatory Conditions Infantile
Uterus With Stenosis of Cervix
..........."...... .
.
AmenorrheaSterility
Dysmenorrhea Menopausal Syndromes Minor Surface Growths
545 545 546 547 549 551 551 551 552 553 556 556 557 557 557 558
558 558 558
CHAPTER XXXIGENITO-URINARY CONDITIONSGeneral
ConsiderationsElectrodes and Technique Nephritis Tuberculosis of
the Kidney.
....
.
..
.
.
.
...
560 560 561 562
20Renal ColicCystitis. Incontinence of Urine.
CONTENTS.562..
.
.
.
.
.-
.
.
.;
,
.
.
.
Prostatitis
and Seminal
Vesiculitis.
.
.
.
.....
Prostratism.
..
.....
.
f
-
.
Gonorrheal Epididymitis * .... .... Gonorrheal Urethritis ...'.
Tuberculous Epididymitis Calcified Deposits in Corpora Cavernosa
Stricture of the Urethra Electrosurgery in Urology (By Daniel A.
Sinclair, M.D.).
.........
.
.
.
.
.
,
.....
.
.
563 563 563 564 564 564 565 565 566 566
CHAPTER XXXIIPROCTOLOGICAL CONDITIONS
BYHemorrhoids Medical DiathermyElectrosurgery Surgical
Galvanism
R. V. GORSCH, M.D."'-
,
.
..... ..
.
.
t
.
.
.
..
.'.
.
.....'...
-.
.
.
.
.
>
..
.
.
Fistula in Ano Fissure in Ano Stricture of the Rectum and Anal
Canal Polypi of the Rectum and Colon Proctitis Pruritus Ani
,
.
-
.
.
*\..
.
.
CoccygodyniaNeuralgia, Hysteria of the Rectum, etc Tuberculous
Peritonitis, Enteritis and Anorectal Tuberculosis Cancer of the
Rectum
569 570 570 572 573 573 573 574 575 576 576 576 577 577
CHAPTER XXXIIIDERMATOLOGICAL CONDITIONSGeneral
Considerations
Acne VulgarisAlopeciaCallositas
.
.
Benign NeoplasmsCorns Dermatophytosis Eczema Seborrhoicum'.
579 581 581 581 581581 581
Erysipelas
/
Furuncles Impetigo Keloids and Hypertrophied Scars Keratoses
Neurodermatitis
Malignant Neoplasms Molluscum Cpntagiosum
.... .
Nevi Pigmented Nevi Pityriasis RoseaPsoriasis
.
.
...;
.
RhinophymaSycosis Vulgaris Telangiectases. .. .
-
.
.
Tuberculodermas Verruca Vulgaris Ulcers and WoundsHypertrichosis
Epilation by Electrolysis. .
.
"
583 583 584 585 585 585 586 586 586 586 587 588 588 588 589 589
589
.589.
.
...
Equipment
.
.
.
.
.
.
.
Preparation of Electrolysis Setting of Current Flow The
Operation
,
.
.
590 591 592 592 593 594 594
CONTENTSHypertrichosis Epilation bv Electrolysis Technique With
Insulated Needles Test Treatment Complications and Dangers
Postoperative Treatment.
21
.
.
.'.....;Treatments
:
'.
.
.
.
.
.
.
Number and FrequencyEpilation
of
by High-frequency Current
.
.
.
.
The Operation
596 597 597 597 597 598 598
CHAPTER XXXIVDISEASES OF THE EAR, NOSE AND THROAT BY WALLACE
MORRISON, M.D.p General Considerations . . ; Diseases of the Ear
The Pinna and External Auditory Canal Acute Dermatitis of the Pinna
and External Canal Subacute and Chronic Dermatitis of the Pinna and
External Canal Furunculosis of the External Canal.
;
*.
.
.'
.
.
.
.
600 600 600 600 600601 601 601
The Middle Ear and Mastoid
Process
Acute Non-suppurative Otitis Acute Suppurative Otitis Media and
Mastoiditis Chronic Suppurative Otitis Media Chronic Catarrhal
Otitis Media, Otosclerosis and Auditory Nerve Deafness Diseases of
the Nose and Nasal Accessory Sinuses The External Nose and Nasal
Vestibule Acute and Chronic Dermatitis Furunculosis..
....', Media
602 602 603 604 604 604 604 604 604 605 605 605 607 607 607 607
607 607 608 608608 609 609
.................ChronicAtrophicRhinitis
The Nasal Chambers
Acute Rhinitis Chronic Generalized HypertrophicRhinitis Chronic
Localized Hypertrophies Vasomotor Rhinitis and Hay Fever
..-.- and..
Nasal SynechiaeEpistaxis..
....
Lupus and True Tuberculosis of the Nose Benign and Malignant
Growths of the Nose and Sinuses
The Nasal AccessoryAcute Sinusitis Nasal Polyps
Sinuses.
Granulation Tissue Diseases of the Pharynx
Acute Pharyngitis Chronic Pharyngitis Hypertrophied and Infected
Lymphoid Tissue Hypertrophy of the Adenoid Hypertrophied Remnants
of the Adenoid Acute Tonsillitis Chronic Tonsillitis and
Hypertrophy of the Tonsils.
'
.
.
.
.
........
609 609610 612 612
Electrosurgical
Peritonsillar Elongation of the Uvula Hypertrophy of the Lingual
Tonsil.
Removal of the Tonsils and Retropharyngeal Abscesses. .
.....
.
.
Varicose Lingual Veins Diseases of the Larynx
.
.
.
...
.
.
.
Acute Laryngitis Chronic Laryngitis
"
.
.
.
....
.
.
.
....
.
.
Laryngeal Tuberculosis Benign and Malignant New Growths of the
Mouth, Pharynx and Larynx
614
CHAPTER XXXVDISEASES OF THE EYEGeneral Considerations . Eyelids
and Conjunctiva Cornea, Uveal Tract and Retina..
.
.............. . .
615
'.
Electrosurgery of the
Eye
619
22
CONTENTSCHAPTER XXXVIPHYSICAL THERAPY IN OFFICE PRACTICE
General Considerations Planning Physical Treatment.
.
...
.
.....-.'.
.
Frequency of Treatment Judging Results The Treatment Habit
Selection of Apparatus Office SpaceOffice Assistants
621 622 622 623 623
624 624 626
CHAPTER XXXVIIPHYSICAL THERAPY IN INSTITUTIONAL PRACTICEGeneral
Considerations Relation to Other Departments The Director of
Physical Therapy Location and Floor Space
.... . ..
EquipmentRecordsPhysical Therapy Library....
.
.
.
.
;
.
.
1
.
Appendix.Glossary
Electrodiagnostic Charts.>.
and Tables..
....
....
627 627 628 633 634 635 637
640654669
Author's IndexSubject Index
.
.
.
.
.
672
ELECTROTHERAPY AND LIGHT THERAPYCHAPTERI
INTRODUCTIONPHYSICAL THERAPY IN THE PRACTICE OF MEDICINEall life
on earth. The warming of the sun, the flow of water, the electrical
charge in some of the rays bodies around us, all form parts of
Nature's inexhaustible and all-powerful
PHYSICAL forces furnish the basis of
properly mastered are of help to increase circulation, enhance
local and general body metabolism, relieve nerve irritation or
stimulate nerve function, inhibit growth of germs or destroy them
altogether. As a result of all these effects, physical agents may
speed up repair of injured or diseased tissues, restore disturbed
function, relieve pain and improve the condition of the entire
body. Basis of Physical Therapy. The human body is a complex
transformer of energy. Chemical energy stored up in food or in
drugs is split into component molecules and serves to keep up or
modify physiological functions in the body. Some of these chemical
processes create physical energy such as heat, electrical action
currents either as a by-product or as an essential object. Physical
energy can also be conveyed to the body from the outside by various
methods and thus serves to stimulate physiological processes. Any
form of physical energy applied to the human tissues exerts a
primary physical or physico-chemical action and this in turn
affects cellular activity. These "secondary" physiological effects
serve to influence a pathological condition either locally or
system ically and thusif
array of forces. The same physical forces inestimable value in
the art of healing. They
may
create therapeutic effects.
Most of the procedures and effects of physical measures are
applied through the skin. The skin is not merely a protective
covering of the body but also a complex structure of perception,
absorption and excretion. It is capable of a variety of reactions
to stimuli from the outside and from within. Most of the reactions
brought about by physical forces are nonspecific in character. It
has been shown that stimuli of different nature, such as heat,
manipulation, chemical or electrical agents may cause
similarvascular response in the skin, consisting of dilatation of
blood-vessels, increased permeability of the vessel walls and
increased circulation. The nervous reflex effect of
"counter-irritation" through the skin upon deeper parts may be
alike and this explains the seeming paradox of similar
therapeutic effects on painful conditions by physical agents of
apparently There are definite reflex reactions between certain
cutaneous areas and the gastro-intestinal tract. In general,
internal organs are reflexly related to the skin directly overlying
them, and the effectdifferent nature.
(23)
24
INTRODUCTION
produced by reflex is the same as that seen in the cutaneous
area treated. Cold applications to the cutaneous area produce a
related effect on the organ beneath, i. e., a tonic or stimulating
procedure. Applications of heat cause relaxation, increased blood
supply and increased activity. (Fig. 1.)
Manycanal,
may
visceral disorders, particularly disorders of the
gastro-intestinal be beneficially influenced by appropriate
stimulation of the
corresponding cutaneous areas. There are, on jthe other hand,
specific reactions in the skin, such as those caused by ultraviolet
radiation, which cannot be produced by any other agency. With
physical agents capable of penetrating the protective covering of
the skin and other tissues, specific effects on inner organs can be
expected. This part of physical medicine offers at present a large
field for clinical research.TABLE1.
PRINCIPAL PHYSICAL AGENTS AND SOME OF THEIR EFFECTSPrimary
physicalSecondary physiologicaleffectseffect
Physical agent
Hot water Hot airRadiant heaters Incandescent lampsC
HyperemiaSedation of sensory or motor irritation Attenuation of
germs
Thermal
j
Diathermy Sun Sun Heated metals Carbon arc Mercury
vaporRoentgen-ray
[
(
ErythemaPigmentationActivation of ergosterol Effects on
blood
Photochemicalarc
I
j
[
RadiumGalvanic current
PhysicochemicalT-, Electrochemical,
Contraction of tissues Molecular disintegrationPolar; vasomotor
stimulation
,
i
metabolic
Low frequency, interruptedand alternating currentsVibration
Electrokinetic
Massage
Kinetic
Muscle stimulation Increase of venous and lymph flow, stretching
of tissue, reflex stimulation
The strength, duration and extent of application determine the
local or general sedative, stimulative or destructive effects of
any physical agent.It is evident that a definite diagnosis arrived
at by all known methods, or at least an acceptable working
diagnosis, is essential before any form
of therapeutics is instituted. If physical treatment is being
considered, either as a primary line of attack, or as an adjunct to
other appropriate treatment, the question should not be "What kind
of apparatus shall be
The query should be rather: "What type of physical agent, or
combination of agents, will be best suited to overcome the
anatomical or functional disorders in this individual patient?"
must strenuously resist the conception fostered by commercial
interests that, for treating a given condition, a certain make of
apparatus is necessary. The object of physical therapy is the
bringing about of certain physiological responses and the student
of this branch of therapeutics must learnapplied?"
We
to choose from the available methods, according to the
circumstances. He should have no difficulty to make his choice once
he had sufficienttheoretical grounding
and acquired
clinical experience
under competent
guidance. For the efficient and safe application of any physical
measure, the following basic knowledge is essential 1. What is the
physical nature of the form of energy employed?:
PHYSICAL THERAPY IN THE PRACTICE OF MEDICINE2.
25
What
are
effects3.
its primary on the body?
physical,
and
its
secondary physiological,it
In what pathological or functional changes doesuseful?
prove
clinically
4.5.
What What
is
are
the correct technique of its employment? its possible dangers
and contraindications?
Schematic diagram to illustrate the interrelation of vasomotor,
secretory and caused by sensory stimulation through the reflex arc.
Afferent pathIt can thus be seen how radiant heat on left, efferent
pathways on the right. the skin surface can cause reflex
vasodilatation of deeper structures and change in muscle tone. Also
it is apparent how visceral stimuli can elicit muscle spasm and
referred pain.1.
FIG.
myo tonic phenomenaways on the
(After Wiggers.)
It is evident that any physical measure capable of doing good is
also capable of doing harm if it is incorrectly applied. Likewise
there is a threshold of intensity and duration where therapeutic
efficiency begins; and there is a danger zone when that threshold
is exceeded. The quantita-
26tive or
INTRODUCTION
measured conception of physico-physiological effects is
established clinical and laboratory research work and is the main
factor in gradually elevating physical therapy procedures from an
empirical
by painstaking
stage to that of a well-defined scientific procedure.
Scope of Physical Therapy. A frequent Abjection voiced by the
uninformed is that physical therapists concern themselves with all
too many pathological conditions, instead of remaining within a
well-circumscribed domain. No such objection is voiced against the
similar wide use of drug1 therapy in all departments of medicine.
Sollrnan states, "Although drug therapy and drugless therapy may
seem direct antipodes to the superficial thinker, they involve the
same principles, evoke the same phenomena, accomplish the same
results. They differ only in the means which they employ, of which
sometimes the one, sometimes the other is better adapted to secure
the desired end. Indeed, the differences between physical therapy
and pharmaco-chemical therapy are no greater than those between
radiant
and
direct heat, or
Physical therapyof conditions.
local and general anesthetics." neither a causal nor a specific
therapy in the majority It serves in acute disease conditions to
relieve symptoms
betweenis
and speed up recovery. Simple thermal and hydriatic measures
have been part of standard nursing procedures for a long time. In
local and general infections, ultraviolet radiation and heat
measures are of considerable importance. In certain acute systemic
infections such as gonorrhea and its complications and a few
others, artificial fever therapy has an almostspecific effect.
In acute traumatism, the
efficient application of physical
measures
Theand
essential for early recovery. most important field for physical
therapy lies in the treatment ofis
chronic disease conditions.safe for relieving pain
In these, physical agents are quite dependable and offer often a
definite chance for recovery
by bringing about gradual
resolution of chronic inflammatory processes. General thermal or
hydriatic agents acting through the skin as an organ will stimulate
general circulation and elimination. Local thermal agents can
stimulate the function of any organ or body region and speed up
absorption of products of inflammation or trauma. Mechanical,
electrical and photochemical stimuli can promote local chemical
interchange which in turn affects the whole system; they also may
act by active exercise or nerve reflex upon deeper situated parts
or organs. Ultraviolet irradiation is a specific treatment for
rickets. High-frequency electricity and surgical
galvanism are valuable methods for the destruction of minor
new-growths tissue; major electrosurgery has made possible
important advances in surgical technique. Among the many conditions
in which physical measures prove of definite value are traumatism,
both acute and chronic; the various forms of arthritis and the
rheumatic states, many kinds of paralysis and other organic and
functional affections of the nervous
and diseased
system, chronic digestive disturbances, chronic diseases of the
heart and blood-vessels, acute and chronic inflammatory conditions
of the genital organs, nose and throat and many skin lesions. There
are some obvious advantages in employing physical remedies. Usually
they can be directly applied to the affected parts and in acute
conditions, as a rule, they give immediate relief. In chronic
conditions, patient and systematic application is essential, but
there is no danger of habit-forming as is the case in
PHYSICAL THERAPY IN THE PRACTICE OF MEDICINE
27
the use of certain drugs. In some instances physical measures
will enable the clearing up of lesions apparently requiring an
operation. Place of Physical Therapy. Physical therapy is not a new
system forrecognizing and treating disease.of medicineIt
rightfully
forms part of the practice
and will be of most value in the treatment of disease and injury
when employed by or under the immediate supervision of the
physician
who has
learned
why
there
is
a
scientific basis for the
use of
some physical energy or its combination with others and who
knows when and how to apply it. Physical therapy cannot be
practiced apart from general medicine and surgery, for it must be
applied with a broad knowledge of clinical diagnosis. As a matter
of fact its methods serve as a diagnostic aid in a number of
conditions; hence its newer designation as physical medicine.
Conversely medicine and surgery should not be practiced without
physical therapy, a valuable adjunct, when coordinated with other
indicated therapeutic measures, and, at times, a primary method of
treatment. There is ample need and opportunity for the systematic
use of physical measures by all medical men. However, the best
interests of patients will be most satisfactorily secured if the
possibilities and limitations of each group of physicians employing
physical therapy are clearly understood. The general practitioner
should be able to utilize simple thermal and hydriatic measures
both at his office and at the bedside, and should be able to
prescribe and demonstrate exercise for traumatic, arthritic, and
other every-day conditions. He should employ elaborate pieces of
equipment only after he has had competent clinical instruction in
their use. Specialists in various fields of medicine, such as
surgery, orthopedics, gynecology, and nose and throat diseases will
all derive great satisfaction from such physical measures as are
applicable to their respective fields, once they have had proper
theoretical grounding, and at least the rudiments of clinical
training in their employment. There is need in every large center
of population, and certainly in all large hospitals, for medical
men with special training in general physical therapy to be able to
render service with all modern resources, such as fever therapy,
under-water exercise, and the various electric and light
treatments. It requires training
and aptitude, as well as
official
support, to carry on clinical and experi-
mental research work, and to check on the claims for the
ever-increasing number of new devices. Properly trained technicians
are indispensable for administering physical therapy in
institutions, and in most physicians' offices. But it is not fair
to expect technical aides who have been trained to employ physical
measures only according to instruction, to be responsible for the
ordering of treatments, and the judging of their efficiency. This
will be the case if a department is only nominally in charge of a
physician or a group of physicians who have neither special
interest nor training in the subject. No fountain can rise above
its source and no physical therapy department can render the best
possible service unless it is headed by a physician thoroughly
familiar with the methods and scope of modernphysical
treatment.Classification of Physical
Therapy Methods.
The
classification of the
for no matter various physical measures is on what basis it is
done, there will be overlapping, For didactic purposes and for
institutional classification, heading under each physical agent
a somewhat involved problem
28
INTRODUCTION
such as electrotherapy, hydrotherapy, etc., as shown in Table 2
has proven practical. In such a classification the same agent,
according to its form of application, may exert a variety of
physical and physiologicaleffects. For an intelligent conception of
basic effects and prescribing, a grouping of physical measures
according to the primary thermal, mechanical or chemical effect is
more desirable, as has been shown in Table 1. This brings together
physical agents of a different nature electricity, water, but shows
that their physiological effect is based on a similar primary
light
physical effect.
TABLE1.
2.
METHODS OF PHYSICAL MEDICINEElectrophoresis
Electrotherapy Galvanic or direct current
Low-frequency currents Electrodiagnosis High-frequency currents
ElectrosurgeryStatic electricity2.
Light therapy Photo thermal radiations Visible and infrared rays
Photochemical radiations Ultraviolet rays
Heliotherapy3.
4.5.
Hydrotherapy Hydrothermal measures Hydrokinetic measures
Hyperthermy and Hypothermy Mechanotherapy Massage and manipulation
Medical gymnasticsOccupational therapy
Roentgen-ray or roentgen therapy although employing an agent
ofphysical nature does not appear in the above classification
because by well-established custom it forms part of another large
special field of medicine. Apparatus for Physical Therapy. It is by
no means necessary to possess
a large array of machinery to produce the few basic physical and
physiological effects Simple hot and cold applications, active and
passive exercise can do a world of good by themselves. There is
danger in too much and too complicated apparatus for therapy, just
as there is danger of too much:
apparatus for diagnostic purposes when one's five senses and
clinical experience, unaided should be adequate to solve many
problems. On the other hand, modern mechanical and electrical
progress offers many types of efficient apparatus, with the saving
of expenditure of one's own energy, of time in accomplishing
results, and with the possibility of accurate dosage and location
of the physical energy to be applied. The advantages of modern
electrical apparatus over some of the older crude methods are just
as evident as those of the modern methods of transportation over
the time-honored mode of walking and pushcarts. Those who
grudgingly admit that they believe in massage and exercise, but do
not care three figs for all this apparatus, the glittering
machinery of practice, simply handicap themselves very sadly. They
limit their speed and confine their radius of action to a narrow
segment of what it might be.
For the ever-increasing scope of physical therapy, apparatus is
quite indispensable, and will tend to become more so in the future.
The finer and more varied the control, the larger the range of
power, the more
PHYSICAL THERAPY IN THE PRACTICE OF MEDICINE
29
accurate the measurement of energy input, the more varied and
the more dependable will be the subsequent physiological and
clinical results. Electrotherapy and Light Therapy. From the
standpoint of the generalpractitioner, electrotherapy and light
therapy open up many new vistas in medicine and surgery and
although not entirely replacing some of the simple methods of
application of heat, massage and exercise, enable a
and more extended application of physical energies. With simple
and inexpensive equipment, the general practitioner comparatively
can produce results in many conditions in which treatment by
medication and surgery alone is not quite satisfactory. The
rational use of such measures should be part of the office work of
most progressive physicians because it increases the efficiency of
the medical service rendered. A striking illustration of the
changed conception of the place and future of electrotherapy is
contained in an editorial of the New York Times, 2 written apropos
the First International Conference of Fever Therapy: "Twenty-five
years ago the physician who clamped a pair of electrodes on a
patient and passed an electrical current through the body either to
heat tissues according to the principles of diathermy or twitch
muscles or stimulate the flagging system was regarded either as a
self-deluded enthusiast or as a quack who could not be restrained
because he had a Now the First International Conference on Fever
Therapy is license. held under the high patronage of such medical
eminences as Nobel being Prize winner Wagner-Jauregg, Volhard and
Bessemans. No longer is there any doubt about the cures of the
electrotherapist. Venereal diseases, general paralysis of the
insane, arthritis and a score of other diseases are now treated
electrically and successfully without causing the professors in the
medical colleges to lift their eyebrows. "In French a physicist is
still called a physicien. The justification for doing so is more
apparent than ever in these days of waves and highfrequency
currents applied in medicine. Many of the men who practice the new
electrotherapeutics are so well grounded in physics and electrical
engineering that they have made striking technical improvements.
This new science needs their combination of electrical and medical
knowledge. It still lacks measurements, still lacks standards. But
empirical as it still is it supplies evidence that the old pill box
is obsolescent. Medicine today belongs to the chemist, the
electrotherapist, the bacteriologist, the radiation expert.
Gradually it is acquiring the precision that we associate with real
science. And the electro therapists who were once regarded as
little better than charlatans helped to bring about the
change."well-controlled
REFERENCES1.
SOLLMAN,
2.
Address of Welcome to the 19th Annual Convention of the American
Congress of Physical Therapy, Arch. Phys. Ther., 21, 561, 1940. New
York Times, March 31, 1937.J.:
PART
I
Electrophysics
CHAPTER
II
FUNDAMENTAL ELECTROPHYSICSThe StructureMatter and the Atomic
Theory. The Electron Theory of Matter. The Elementary Law of
Electrophysics. Conductors and InsuTransfer of Electrical Charges.
Charging by Induction. Condensers. lators. Electric Potential.
Static Electricity. Electric Current. Thermal,
Electro-magElectrical Units: the Ampere, the Ohm, the Volt. netic,
and Chemical Effects. Difference Between Amperes and Volts. Ohm's
Law. The Watt and the Farad. Measuring and Regulating
Devices.of
Electric Charge.
No
fairly well
one can apply electrotherapy efficiently and safely unless he is
grounded in the physics of electricity and has acquired
practical
experience in the therapeutic employment of the various
electromedical currents. The physician must be familiar with the e
very-day use of electricity and the construction and control of
every piece of apparatus he employs. It would seem a poor exhibit
of efficiency should a busy physician's officework come to a stop
while someone scurries around to get an electrician to remedy such
common troubles as a blown fuse, or a broken
connection in a conducting cord or socket plug. The Structure of
Matter and the Atomic Theory. The modern theory of the structure of
the atom holds that electricity forms an integral part in the
structure of all matter. Anything which has weight and occupies
space is called matter. Matter is composed of some ninety-two
primary substances, known as elements, which cannot be split up
into bodies of a different kind without changing their
characteristics. Some of these are solids, like zinc, iron,
sulphur, others are liquids, like bromine, mercury;
some are gases, like hydrogen, oxygen and nitrogen. All complex
forms of matter, all minerals, all tissues in animal or vegetable
life are formed by the combination of these elementary substances.
It is obvious that, while masses can be split up into smaller and
smaller particles, there must be an ultimate particle of any
element that cannot be divided, and which forms the basis of the
element as a stable unit. According to Dalton's classical theory,
proposed in 1802, such a particle is called an atom (from the Greek
a-tomos: indivisible). The atom, the most minute unit of matter,
takes part in chemical changes by uniting either with the other
atoms of the same kind to form appreciable quantities (molecules)
of the same element or with atoms of other elements to
formfinally,
compounds. A molecule may consist of two or more atoms, the
atoms being for instance, all hydrogen or all oxygen, or the all of
the same elementmolecule may consist of different elements for
instance, a molecule of water is composed of 2 atoms of hydrogen
and 1 of oxygen (H^O). The unit of atomic weight is the lightest of
atoms, the hydrogen atom.(30)
THE ELECTRON THEORY OF MATTER
31
The Electron Theory of Matter. Experimenting with electrical
discharges from glass tubes having a high degree of exhaustion, J.
J. Thomson, later Lord Kelvin, of Cambridge, England, discovered,
in 1897, a stream of extremely minute particles projected from the
negative electrode or cathode. He proved that the particles forming
these "cathode rays" have each a mass amounting to about 1/1800
that of a hydrogen atom and that each carries a negative charge. He
named these particles electrons (from the Greek elektron: amber,
the substance which can be electrified by friction) and Millikan,
the American physicist, succeeded in measuringandisolating
them.
electron theory supposes that every atom of matter in the
neutral state is made up of a certain number of elementary positive
units and an equal number of electrons. The charge on the electron
is negative but thisis
The
only an accident; the choice of what was to be positive
electricity and
originally quite arbitrary and it happens to have made the
electron negative. Electrons have become universally accepted as
the smallest known particles of matter and have now almost become
an article of commerce. In radio tubes electrons are given off as
readily as hot water gives off steam. The electron is the unit of
electricity and represents a universal element of structure of all
matter, whether flowing along slowly in an electric current or
hastening through space at an extremely high rate as a cathode ray,
whether it is emitted in radioactive disruption or in a
photoelectric process, whether it is "jumping" in our lamps, etc.
It is always the same physical unit, proving its identity by
exhibiting the same charge and the same mass, in particular by
keeping the ratio of charge to mass constant. Rutherford's
experiments with radioactive elements established the second
universal constituent of the atom called the proton. The proton has
an electrical charge of the same value as the electron, though of
opposite charge but its mass is quite different, being 1800 times
as heavy as that of the electron. Every atom is believed to consist
of an extremely small nucleus in which is packed all the positive
electricity and around which the negative electrons are arranged in
some definite order but with wide spaces
what negative was
between them. The atoms of all elements are thus believed to
contain as constituents both positive and negative electricity. In
the hydrogen atom there is only one proton and one electron
present, but in all other atoms there are more protons than
electrons in the nucleus, which thus possesses a positive charge.
This is balanced by the addition of electrons surrounding the
nucleus. The atom of oxygen contains sixteen protons and sixteen
electrons.(Fig. 2.)
Modern physical research has made numerous new discoveries about
the structure of matter. Anderson in 1932 found the positron a
positively charged, rather unstable elementary particle of the same
weight as the electron. Chadwick in the same year discovered the
neutron, an electrically neutral particle of the same weight as the
proton. Research in radiation energy has added another primary
constituent of matter, that of thephoton or light quantum, about
which more will be said in Part III. Recent work with atoms through
the use of the cyclotron and similar atom smashing devices causes
atoms to give up other than electron particles; in fact, actually
transforming or transmuting the atom to one of a different ele-
32
FUNDAMENTAL ELECTROPHYSICSetc.,
are
mental character. Electrons, protons, neutrons, positrons,
dueterons, all fragments of atomic destruction.
H1
16+
1
16 +8
26Schematic illustration of electron theory. Each atom contains
an equal number of protons and electrons. Protons are represented
by + sign and electrons by dots. In the hydrogen atom there is only
one proton and one electron present, while the oxygen
atomFIG.2.
contains 16 protons and 16 electrons.
(After Gibson.)
Electric Charge.electrical
The
electron theory
is
the basis of explanation of
all
phenomena. The binding together of electrons and protons into
atoms represents large amounts of energy. An object containing a
normal balance of electrons and protons shows no electrical
properties. If the atomic structure is disturbed by an external
force of sufficient strength, such as friction, heat or chemical
action some of the electrons of the atomsbe driven away. Charging a
body consists of taking away or adding A negatively charged body is
one which contains more electrons than its normal number; a
positively charged body is one which contains less electrons than
its normal number. The Elementary Law of Electrophysics. The basic
law which underlies all considerations in electrophysics is: bodies
charged with the same kind of electricity repel each other while
those charged with a different kind of electricity attract each
other. In other words, like charges repel and
may
electrons.
body one may use an electhread from a glass support or the
wellknown gold leaf electroscope, two strips of thin gold leaf
attached to an insulated brass rod and hung in a glass jar. (Fig.
3.)troscope, a pith ball
unlike charges attract. For detecting the condition of an
electrified
hung by a
silk
CONDUCTORS AND INSULATORSConductors and Insulators.
33
currents) any enough atomic change to permit a flow of
electrons, and hence under sufficient electrical stress there is no
sharp demarcation between conductors and
non-conductors.insulator
Substances which lead off the electric charge quickly are called
conductors; those which prevent the escape of an electric charge
are called non-conductors or insulators. Most substances conduct a
little and under powerful influence (high voltage
may
suffer
it
Detecting an electric charge. A goldleaf electroscope is charged
by approaching with an electrified vulcanite rod. The negative
charges are driven toward the two leaves which show an electric
charge by repelling each other.FIG. 3.
Metals are the best conductors. In all metallic substances there
are always a number of electrons free from their atoms and as soon
as these free electrons are pushed along in the conductor, a flow
of electricity willlarger the number of free electrons in any
substance, the greater conductivity. The substances which are good
conductors of electricity are also good conductors of heat. Watery
solutions of acids, bases and salts are known as electrolytes (from
elektron and lutos: soluble)
begin.will
Theits
be
and
also conduct well.is
The
difference
between metallic and
electrolytic
conductors
that in the latter a flow of electricity brings about
chemical
changes. A substance in which there are no free electrons and
the resistance of which to the flow of electricity is high is
called an insulator. There are solid insulators such as hard
rubber, mica, glass, amber, porcelain and silk and fluid
insulators, such as oils, paraffme and pure distilled water.
Lubricating oil placed over parts of electrical apparatus through
which the current has to flow will prevent its passage instead of
facilitating it. To prevent leakage of electricity electric light
wires and terminals of electromedical apparatus are mounted on
glass, porcelain or hard rubber,3
34
FUNDAMENTAL ELECTROPHYSICSPartial conductors are substances
which ordinarily resist the flow of but under certain conditions
will become conductors.
electricity
TABLEInsulators
3.
INSULATORS AND CONDUCTORSGood conductorsMetals
Partial conductors
AmberGlass
Dry woodPaperAlcohol Tap water
CarbonGraphite
Hard rubberParaffine
Watery
solution of salts
and acids
Dry
air
PorcelainDistilled water
Moist air Kerosene
Wet wood
Important examples of partial conductors are: (1) Distilled
water is an insulator, if sufficiently pure, containing no
dissociated molecules; as soon as it contains a slight trace of
salts, however, electrolytic dissociation takes place and the water
becomes a good conductor. Ordinary tap water, always holding an
admixture of salts, is therefore considered a partial conductor.
(2) The tissues of the human body; they are good conductors on
account of their saline ingredients, but the horny substance in the
superficial layers of the skin serves as a fairly good insulator.
By moistening the surface of the skin w e overcome its insulating
property. In applying some forms of electricity to the body, part
of our technique is directed toward overcoming skin resistance, so
as to secure a free passage of current to the well-conducting
tissues beneath. In conduction of so-called hightension or
high-voltage forms of electricity skin resistance plays only a
minor role. (3) Dry air is an insulator, while moist or ionized air
is a partial conductor. The high-tension charge of static machines
leaks off when the atmosphere is humid, while on dry days the
charge is easily retained. Perfect vacuum is an insulator; in the
so-called glass vacuum electrodesr
used in treatment the air is only rarefied, so that they are
fairly good conductors of high-tension current. Transfer of
Electrical Charges. For transferring electrical charges conductors
such as wires or metal plates are used; at the same time, these
must be insulated from other conductors by non-conducting material,
hence the covering of copper conducting wires by an insulating
layer of silk or rubber, and the mounting of electrodes on
insulating handles. Electricity of high tension, such as the static
current or the monoterminal discharge of a high-frequency machine,
is difficult to insulate, and its tendency to leak off to a neutral
body or the ground in the form of sparks must be guarded against by
long insulating handles and by holding it at a safe distance from
all grounded objects. Charging by Contact and by Induction. This is
easily explained by the When a positively charged body is brought
near an electron theory. insulated conductor, the free electrons in
the conductor are attracted from all parts of the conductor to the
end nearest the positively charged body and this end thus becomes
negatively charged. As these electrons were drawn away from the far
end of the conductor, it has less than its normal
number
of electrons
and
is
therefore positively charged.
condenser consists of two opposing surfaces of metal by some
insulating substance (glass, mica or air) on which separated
electric charges can be collected (or condensed) because the
reciprocal attraction across the separating insulation annuls the
repulsion. Capacity is the relative power of holding the ratio of
the electricity held captive to
Condensers.
A
CONDENSERS
35
the tension that arises; it depends on the size of the plates,
their distance and the kind of insulating substance between them. A
dielectric (unelectric) substance is one which offers great
resistance to the passage of electricity
by conduction, but through which
electrical force
may
act
by induction.
Charging by contact. A Leyden jar is held by the hand, and thus
grounded; brought in contact with a source of frictional charge,
such as the positive terminal of the static machine; the positive
charge on the outer layer will be repelled to the ground and the
earth will supply the outer layer with an amount of charge
sufficient to counterbalance the charge on the inner layer.FIG.
4.its
knob
is
Condensers may be likened to water tanks and are necessary for
the holding of a definite amount of electrical energy ready for
immediate flow in certain types of apparatus, such as
high-frequency machines and electronic devices. If the plates of
the condensers are connected, the positive and negative charges are
united and the condenser is "discharged." Such
FIG. 5. Charging by influence or induction. Bringing a charged
body near but not in actual contact with an insulated conductor
will cause a separation of the electrical charges; the opposite
charges are repelled to the far end of the conductors, and if they
are led off by another conductor a definite charge is left on the
first conductor.is usually "oscillatory" in the form of electric
waves and is accompanied by a sound. (See next chapter.) The Leyden
jar is the earliest and best known form of a condenser and consists
of a wide-mouth glass jar coated by a metal, such as tinfoil, to
about two-thirds of its height, both on the inside and the outside.
A brass
discharge
36
FUNDAMENTAL ELECTROPHYSICS
rod extends through an insulated stopper; the lower end of the
rod is connected with the inside coating by means of a brass chain
and terminates in a knob on its upper end. Modern electrical
apparatus is usually equipped
Copper orfoil
tin.
/
mica or paper/Copper orfoiltin,
/
/mica or paper/
JarFIG. 6 FIG. 7of
FIG. FIG.
6.
Diagram
Leyden
jar, its
discharge through a "spark gap."
7.
Plate condenser.
with plate condensers, consisting of a number of flat metal
(copper) sheets separated by insulating material (mica). The
alternate layers of the conducting material are connected to the
terminals of an electrical source. A large capacity can be built up
in these plate condensers.
FIG.
8.
Electric repulsion.
A
from a static machine; the charge spreading and as a result each
hair repels its neighbor.
person seated on an insulated platform receives a charge all
over the body electrifies each hair similarly
Static or frictional electricity is the first known form Static
Electricity. the Greek name of which of electricity. The Greeks
observed that amber
STATIC ELECTRICITYis
37
attract light objects, such as feathers, Gilbert, physician to
Queen Elizabeth, discovered that glass, sulphur, resin and some
other substances possessed the same property as amber and he coined
the name electricity (electricitas) from the Greek
elektron
when rubbed, would
or bits of paper.
word.dissimilar substances, preferably non-conductors of
electricity, some substances take on an excess of electrons, while
others are left with a deficit of electrons. Those with an excess
of electrons are
When
are rubbed
considered to possess a negative charge, while the ones deprived
of their electrons are considered to be charged
positively.Electricity produced by friction is held on an insulated
conductor in a state of tension, ready to flow away, and is called
"static" electricity, in contrast to "current" electricity which
flows all the time.
N
FIG. 9. Primitive static machine (Tcepler-Holtz type). R-R',
contact brushes; N, diagonal bar for neutralizing charges; J-J',
small Leyden jars to increase capacity of apparatus.
Lightning may be explained by the separation of electric charges
on the heavy raindrops from the thunderclouds by the violent air
currents. The negative charges remain on the finest particles blown
high into the air while the heavy positively charged raindrops are
left behind. Thus an electric field of enormous tension is created
and, due to the overpowering pull of the lines of force, the
charges rush forward, ionize the air (making it a conductor) and
there is a lightning flash. The static machine is a miniature
generator of lightning. In its primitive form it consists of two
circular glass discs mounted on a spindle, with only a small space
between them. When rotated by a handle, or by motor power, at high
speed, a separation of electric charges takes place and metallic
brushes draw off the positive and negative charges from the
revolving disc, leading them to two metallic "prime" conductors or
ter-
38
FUNDAMENTAL ELECTROPHYSICS
minals. When the difference of potential between these two
terminal conductors becomes sufficiently high an electric discharge
occurs in the form of a spark.
CURRENT ELECTRICITYElectric Current.is
A stream of loose electrons passing along aToestablish or
maintain
conductor
called a current of electricity.itis
an
electric
current
necessary that there be a source of energy generating an
FIG. 10 FIG. 10. Electric circuit. FIG. 11. Short circuit.
low-resistance by-pass.
FIG. 11
An
accidental overflow of current due to an establishment of a
electric charge and there be a- complete electrical circuit
maintained between the higher and lower level of electrons. The
path of the current from the generating source through the various
conductors back to the generating source is called an electric
circuit. As the electric current flows, the circuit is said to be
"closed;" if an interruption or a break occurs the circuit is said
to be "open' and the current ceases to flow. This terminology'
O
