Lec 7 Late Response PDF

Summary

This document contains lecture notes on late responses in physical therapy, specifically focusing on F-response and H-reflex. The lecture covers principles of examination, patient safety, and electrodiagnostic testing techniques. The document also includes details about required reading materials.

Full Transcript

Late Response

Dr. Dany Alphonse Anwar Habib
Lecturer of physical therapy for neuromuscular disorders and its
surgery
MUST University
Mission and Vision of the College of Physical Therapy – Misr University for Science and
Technology (MUST)
Intended Learning Outcomes of the Course (ILOs)
A- Knowledge and Understanding

A3: Realize the principles of examination specific to each treatment procedure

A4: Identify basics of patient’s safety and safety procedures during practice

B- Intellectual Skills
Not applicable
Intended Learning Outcomes of the Course (ILOs)
- continued
C- Professional &Practical skills:
C2: Conduct physical therapy examination using electrodiagnostic testing
techniques
C4: Examine patients using electrodiagnostic testing to determine the need
for consultation or referral with other members of the health team
D- General and transferable skills:

Not applicable
Required Reading:
pp: 36 - 46
 By the end of this
lecture, the student
should have a basic
understanding about F-
Response and H-Reflex
Topics will be discussed in this
lecture:

1- F-Response
2- H-Reflex
Late Responses
 Nerve conduction studies are
most often used to assess distal
nerve segments, with routine
stimulation seldom done above
the elbow or knee.
Few studies can be easily performed to
assess the more proximal nerve
segments (plexus and roots). In the
arm, surface stimulation can be
performed proximally in the axilla and
at Erb’s point, although technical
factors limit these studies, especially at
Erb’s point.
 In the electromyography (EMG)
laboratory, two late responses, the
F response and the H reflex, are
used routinely to study the more
proximal nerve segments. Each has
its advantages and limitations
 they travel the entire nerve segment
from distal to proximal and back. Thus,
they are most useful when routine
nerve conduction studies, which assess
distal segments, are normal and the
late responses are abnormal, a
situation that implies a proximal lesion.
F RESPONSE
 The F response is a late motor
response that occurs after the
compound muscle action potential
(CMAP, also known as the direct
motor [M] potential)
 FIGURE
Normal F response.
Stimulating the
median nerve at the
wrist, recording
abductor pollicis
brevis. F, F response;
M, direct motor
response (i.e.,
compound muscle
action potential).
 FIGURE
Note that to accurately
measure the F response,
the gain must be increased
to 200 µV and the sweep
to either 5 or 10 ms. With
these settings, the F
response is well seen, but
the M response saturates
the amplifier and becomes
distorted (malformed).
The F response derives its name
from the word “foot” because it
was first recorded from the
intrinsic foot muscles.
In the upper extremity, when the
median or ulnar nerves are
stimulated at the wrist, the F
response usually occurs at a
latency of 25 to 32 ms.
In the lower extremity, when the
peroneal or tibial nerves are
stimulated at the ankle, the F
response usually occurs at a
latency of 45 to 56 ms.
If the stimulator is moved proximally,
-the latency of the CMAP increases
as expected,
-but the latency of the F response
actually decreases
Normal F responses, distal and
proximal stimulation. Median F
responses recording abductor
pollicis brevis, stimulating wrist
(left trace) and elbow (right
trace). DL, distal compound
muscle action potential (CMAP)
latency; PL, proximal CMAP
latency. Note with proximal
stimulation, the proximal CMAP
latencies increase as expected,
but the F response latencies
decrease, due to the F
response traveling a shorter
distance antidromically to the
spinal cord.
 This is due to the circuitry of the F
response, which is initially
antidromic toward the spinal cord.
Thus, with more proximal
stimulation, the action potential has
less distance to travel, hence the
shorter latency.
 During a routine motor nerve
conduction study, one usually thinks
of the action potential as traveling
down the nerve across the
neuromuscular junction (NMJ) to
subsequently depolarize the muscle.
 When stimulated, however, the nerve
conducts well in both directions. The F
response is derived by antidromic travel
up the nerve to the anterior horn cell,
with backfiring of a small population of
anterior horn cells, resulting in
orthodromic travel back down the nerve
past the stimulation site to the muscle
F response circuitry. When a nerve is stimulated distally (S), depolarization
occurs both orthodromically and antidromically. The direct muscle response
(M) occurs from orthodromic travel. The F response (F) is derived from
antidromic travel to the anterior horn cell, backfiring of some anterior horn
cells, and orthodromic travel back down the nerve past the stimulation site
to the muscle.
The F response is actually a small CMAP,
representing 1 to 5% of the muscle
fibers.
The F response circuitry, both afferent
and efferent, is therefore pure motor.
There is no synapse, so it is not a true
reflex. In conditions that selectively
affect the sensory nerves or sensory
nerve roots, the F responses are
completely normal.
 Each F response varies slightly in latency,
configuration, and amplitude because a
different population of anterior horn cells is
activated with each stimulation. Presumably,
the shortest latency represents the largest
and fastest conducting motor fibers. Several
measurements can be made on the F
responses, with the most common being the
minimal (or fastest) F response latency
H REFLEX
 The H reflex derives its name from Paul
Hoffmann, who first evoked the response in
1918. The H response is distinctly different
from the F response in that it is a true reflex
with a sensory afferent, a synapse, and a
motor efferent segment. Likewise, several
other properties differentiate the H and F
responses
H reflexes are widely present in motor nerves, but
beyond the age of two, they can only be routinely
elicited by stimulating…
-The tibial nerve in the popliteal fossa and
recording the gastro–soleus muscle. Although
there are techniques for obtaining an H reflex
from the femoral nerve recording the quadriceps
muscle and from the median nerve recording the
flexor carpi radialis muscle, both of these have
significant limitations.
H reflex setup. To record the H reflex, G1 is placed over the soleus, two to
three fingerbreadths distal to where it meets the two bellies of the
gastrocnemius muscle, with G2 over the Achilles tendon. The tibial nerve
is stimulated submaximally in the popliteal fossa, with the cathode
placed proximal to the anode.
 Optimal recording location for the H
reflex. If one draws a line from the
popliteal fossa posteriorly to the Achilles
tendon where the medial malleolus flares
out and then divides that line into eight
equal parts, the optimal location for
placing the active recording electrode
(G1) is at the fifth or sixth segment
distally. This location over the soleus is
approximately two to three
fingerbreadths distal to where the soleus
meets the two bellies of the
gastrocnemius.
H reflex. Note at low stimulation
intensities, an H reflex is present
without a direct motor (M)
response. With increasing
stimulation, the H wave grows
and the M response appears. At
higher stimulation, the M
potential continues to grow and
the H reflex diminishes, due to
collision between the H reflex
and antidromic motor potentials.