Surgical Technology and Practice Flashcards
You use a 2-0 coated vicryl suture to close the galea during closure of a craniotomy. Which one of the following statements is correct?
a. It is a synthetic, braided absorbable suture
b. It is a synthetic, braided non-absorbable suture
c. It is a synthetic, monofilament absorbable suture
d. It is a natural, braided absorbable suture
e. It is a synthetic, monofilament nonabsorbable suture
a. It is a synthetic, braided absorbable suture
Suture choice will depend on tensile strength
required, local availability and surgeon preference. Size varies from 5 (largest; not the same
as 5-0) to 11-0 (smallest). Needle shape (e.g.
straight, half curved, ½ circle) and point geometry
(e.g. cutting needle, taper, reverse cutting) also
vary. Natural sutures include silk and catgut,
while the remainder are synthetic and have different structure (braided vs. monofilament) and
absorption (absorbable vs. non-absorbable) properties. Absorbable suture breaks down over time
in the body. The amount of time it takes a suture
to break down in the body depends on a few factors such as suture type, size and the location it is
placed. Suture absorption rates can increase in
patients with fever, infection or protein deficiency. Also, the strength to a suture will decrease
significantly prior to its complete breakdown
time. Therefore a suture with higher tissue tension will have a greater chance of failure prior
to the amount of time listed above. Braided suture
have a number of strands woven together like a
string. It is thought that non-braided sutures
cause less reactivity in the body and are not as
prone to becoming infected because they lack
the grooves and rough surface for things to
adhere. However non-braided sutures can have
a greater tendency to loosen at the surgical knot
with the lack of grip.
During the resection of an intracranial tumor your boss asks the scrub nurse to prepare the ultrasonic aspirator. Which one of the following statements are correct regarding this piece of equipment?
a. Composed of an ultrasound generator, a sucker, and an irrigator
b. Ultrasonic dissector/aspirator that is selective for tissue with high water and low collagen content
c. Fragmentation of solid tissues, relative sparing of vessels
d. It could induce false-negative results during motor brain mapping with direct electrical stimulation
e. Aspiration, ultrasonic dissection and irrigation properties can be controlled individually
d. It could induce false-negative results during motor brain mapping with direct electrical stimulation
CUSA is commonly used during surgical removal
of gliomas, meningiomas, schwannomas, craniopharyngiomas, and spinal cord neoplasms.
Briefly, it is composed of an ultrasound generator, a sucker, and an irrigator that, together, form an
ultrasonic dissector/aspirator that is selective for
tissue with high water and low collagen content.
Its usefulness and widespread use are attributable
to several advantages, comprising fragmentation
of solid tissues, relative sparing of vessels, reduction of surgical time (by combining aspiration,
ultrasonic dissection, and irrigation in a single
operation), improved safety (by adjusting settings) and supposed minimal trauma to surrounding neural brain structures. On the other hand,
the use of ultrasonic dissection also has some disadvantages, primarily related to the inadequate
and unknown control of its energy, which may
lead to sudden and sometimes unexpected events
(vascular injuries and/or neural tissue damages)
and its possible interaction with intraoperative
brain mapping. In motor testing performed
through direct electrical stimulation a positive
response is given by the active movement (or by
its recording), whereas in language testing a positive response is actually a negative event (e.g.
inability to name objects). If CUSA use negatively
interferes with electrical conduction in adjacent
tissue it could lead to the misdetection of a motor
site, reducing the sensitivity of the technique (if
CUSA and DES are used simultaneously) by
causing false-negative results and increasing the
risk of motor deficit. Equally, when the CUSA
is used during intraoperative language testing,
through its negative interference with neurological function it could show true-positive
eloquent sites.
Which one of the following statements regarding transcranial Doppler ultrasound is LEAST accurate?
a. Doppler effect is the apparent change in frequency of a wave as the source moves relative to the observer
b. Transcranial Doppler takes advantage of reflection of sound waves off blood vessel walls
c. May be useful in distinguishing vasospasm from hyperemia
d. A Lindegaard ratio (LR) of >3 suggests vasospasm
e. Middle cerebral artery (MCA) vasospasm is suggested by a Vmean of >180 cm/s
b. Transcranial Doppler takes advantage of reflection of sound waves off blood vessel walls
Doppler effect (shift) is the apparent change in
frequency of a wave as the source moves towards
or away from the observer. According to this
principle, ultrasound waves emitted from the
Doppler probe are transmitted through the skull
and reflected by moving red blood cells within the
intracerebral vessels. The difference in the frequency between the emitted and reflected waves
(Doppler shift frequency) is directly proportional
to their speed. Physiological variables affecting
TCD measured mean blood velocity are age, gender, hematocrit, viscosity, carbon dioxide,
temperature, blood pressure, and mental or
motor activity. Four main acoustic windows have
been described: transtemporal, transorbital, submandibular and the suboccipital windows.
Although each window has unique advantages
for different arteries and indications, a complete
TCD examination should include measurements
from all four windows and the course of blood
flow at various depths within each major branch
of the circle of Willis should be assessed. Specific
arteries of the circle of Willis are identified using
the following criteria: relative direction of the
probe within a specific acoustic window, direction
of blood flow relative to the probe, depth of ultrasound (insonation), and response to carotid compression or vibration (when difficult to
differentiate anterior from posterior circulation).
The LR, defined as the ratio between the time
mean average (Vmean) velocity of the MCA to
ICA, is the most established of such ratios and
helps differentiate hyperemia from vasospasm.
Hyperemia would result in flow elevations in
both the MCA and ICA and result in an
LR<3, whereas vasospasm would preferentially
elevate the MCA flow velocity over the ICA with
LR>6. LR between 3 and 6 is a sign of mild VSP
and >6 is an indication of severe VSP. TCD flow
velocity criteria appear to be most reliable for
detecting angiographic MCA and basilar artery
vasospasm. Findings in MCA vasospasm include
MCA Vmean 180 cm/s, a sudden rise in MCA
Vmean by >65 cm/s or 20% increase within 24 h
during days 3-7 post-subarachnoid hemorrhage,
LR6, and abrupt increase in Pulsatility index
>1.5 in two or more arteries suggesting increases
in ICP and/or vasospasm. TCD is most useful in
monitoring the temporal course of angiographic
vasospasm following SAH to help guide the timing
of diagnostic and therapeutic angiographic
interventions.
Which one of the following statements regarding intraoperative ultrasound is most accura
a. It is highly useful in the brain but not spinal cord due to anatomical constraints
b. It can aid in adjusting for intraoperative brain shift and in detection of intraoperative hemorrhage or hydrocephalus
c. Its utility in identification of critical tumor margins during surgery and unintentional residual has not been shown
d. Contrast-enhanced intraoperative ultrasound cannot be performed in those with a known allergy to iodinated contrast
e. Intraoperative Doppler angiography can be used to improve accuracy of functional mapping during eloquent tumor surgery
b. It can aid in adjusting for intraoperative
brain shift and in detection of intraoperative hemorrhage or hydrocephalus
Intraoperative US offers real-time information
about the location, size, vascular relationships
and adjacent structures of brain and spinal cord
lesions. This allows adjustment for brain shift,
detection of untoward intraoperative events such
as hemorrhage or hydrocephalus, critical tumor
margins and residual tumor. It is easily available,
convenient, fast and easy to use and may provide
a more practical alternative to intraoperative MRI. Furthermore, newer technologies such as
contrast-enhanced US (i.e. microbubble contrast), or the integration of US with navigation
systems, or with functional navigation systems
as a method of assessing and adjusting for brain
shift may add additional benefits. In particular,
navigable 3D ultrasound (3D iUS) is a novel tool
that combines navigation technology with a dedicated cranial insonation probe capable of generating 2D/3D images that can be superimposed on
preoperative MR imaging and repeatedly updated
to provide a more accurate anatomic orientation,
as well as be used independently without preoperative imaging to improve gross total resection
levels to those seen with 5-ALA and intraoperative MRI. intraoperative doppler-angiography
enabled the delineation of vascular anatomy in
real-time. The specific limitations include concerns regarding image quality and difficulties
with orientation of the 2D ultrasound plane,
learning curve, artifacts during resection may
compromise image accuracy, and in particular,
hemorrhage and tissue handling have been shown
to decrease the specificity and positive predictive
value of iUS. Furthermore, there is no functional
information provided and electrophysiological
functional monitoring must still be considered
when dealing with lesions involving eloquent
structures.
Which one of the following statements regarding high frequency focused ultrasound (HIFU) is LEAST accurate?
a. It is a minimally invasive technique
b. It utilized a piezoelectric ultrasound transducer
c. A single treatment volume can be >5 cm3
d. Tissue response is assessed by MRI at 6 weeks
e. Intraprocedural ultrasound provides better temperature mapping than
a. It is a minimally invasive technique
High-intensity focused ultrasound (HIFU) ablation is a non-invasive technique that uses a beam
generated by a piezoelectric ultrasound transducer
propagates through tissue as a high-frequency
(0.5-4 MHz) pressure wave. The beam is focused
on to the targeted tissue, and each treatment
volume is approximately 0.80.20.2 cm3
. The
energy from the beam raises the temperature of
the focused area to 60-95 °C within a few seconds
without causing damage to the adjacent tissues,
thereby leading to very localized protein denaturation and coagulative necrosis. The available
HIFU devices are generally integrated with either
MRI or ultrasound imaging in order to plan treatment and monitor response in real time. MRI has
the advantage of excellent anatomical resolution,
high sensitivity for lesion detection but temperature mapping is challenging; ultrasonography
offers real-time visualization of the targeted volume (compensates for movement) and guidance
of energy deposition within the treated area
through a hyper-echogenic cross visible during
pulse application. In addition, ultrasonography
provides a rapid real-time assessment of the volume of coagulative necrosis/temperature during
treatment by visualization of a hyper-echogenic
spot on the screen. HIFU ablation provides a completely non-invasive therapy, thus avoiding
potential complications associated with general
anesthesia and surgery. It has been used for the
treatment of liver, kidney, prostate, brain, bone
and breast cancer.
Which one of the following statements regarding the WHO surgical safety checklist is most accurate?
a. If there is a risk of >250 mL of blood loss it must be formally discussed during the signin
b. It is designed to reduce the number of surgical never events by increasing
c. Surgical site should be marked during the time out
d. VTE prophylaxis should be decided before leaving the operating room
e. Essential imaging must be displayed during the time out
e. Essential imaging must be displayed during the time out
To assist operating teams to reduce the number
of patient safety events in the surgical environment, a core set of standards have been identified
by the WHO that can be applied universally
within any healthcare setting to address issues
including correct site surgery, hemorrhage risk,
antibiotic prophylaxis, airway management and
the risk of allergies. WHO surgical safety checklist is designed to reduce the number of errors and
complications resulting from surgical procedures
by improving team communication and by verifying and checking essential care interventions. It
consists of sign in, time out and sign out stage
assessments below:
The Leksell stereotactic frame is most accurately described as which one of the following types of stereotactic system?
a. Polar coordinate
b. Arc-radius (arc-quadrant)
c. Burr-hole mounted
d. Arc-phantom target
e. Cartesian coordinate
b. Arc-radius (arc-quadrant)
Stereotactic frame-based guidance systems have
generally been based on four systems: polar coordinate, arc-radius, focal point, and phantom target. The polar coordinate system is based on
the necessity that guidance of the probe be
described with regard to the angle relative to a
skull entry point. Usually, a minimum of two
angles (in planes orthogonal to each other) is
required to characterize a unique trajectory; in
addition to these angles, the distance of the probe
to the target lesion needs to be calculated (e.g.
Spiegel-Wycis, Horsley-Clarke). The arc-radius
system (e.g. Leksell frame) is based on the concept that a probe equivalent to the radius of a
semicircular arc will reach the center of the arc
when introduced perpendicular to any point
along the arc. Adjustment of the arc (vertically
and anterior-posterior) permits targeting of different points; the base of the arc is attached to a
rigid head frame on the patient’s head which
defines the corners of a cube visible on CT. After
the geometric center of the cube is defined, the
relative location of the target can be calculated
and the semicircular arc manipulated accordingly
to place that lesion at the center of the arc. Arcphantom systems (e.g. CRW frame) allow
mounting of the arc onto a phantom base frame
to check the accuracy of the trajectory immediately before transferring it to the patient. A burr
hole-mounted system provides a limited range of
possible intracranial target points with a fixed
entry point (usually over non-eloquent brain):
provided two angular degrees of freedom (horizontal plane, vertical plane) and a depth adjustment. Cartesian geometry is the underpinning
for all frame types, and describes the location of
a point in space with three coordinates (x, y, z).
Which one of the following statements regarding frameless stereotaxy is most accurate?
a. Does not require manual mapping of coordinate space of preoperative image onto surgical field
b. Point-pair registration is generally less reliable than point-pair registration
c. Accurate optical tracking requires the patient’s head to be immobilized in a clamp
d. Surface-contour registration usually requires fiducial markers
e. Electromagnetic frameless stereotaxy is not suitable in pediatric neurosurgery
c. Accurate optical tracking requires the patient’s head to be immobilized in a clamp
For both frame-based and frameless systems the
relationship between the coordinate space for
the preoperative images and that for the surgical
field must be established. In frame-based systems,
by using the same frame for both preoperative
image acquisition and performing the surgery,
the relationship between the two coordinate systems is known and no further transformation is
required. For frameless systems, point-pair registration or surface contour registration can be used to establish the relationship between the preoperative images and that for the surgical field.
Point-pair matching requires a set of at least three
non-colinear points to be defined in the coordinates of the images. These ‘fiducial points’ can
consist of either natural anatomic landmarks
(i.e. nasion, lateral canthus, or tragus), skinapplied markers, or bone-implanted markers.
These same fiducial points are defined again
within the coordinate system of the surgical field
in the operating room. Software is then used to
establish the relationship between the coordinates of the fiducial points in the image space
and their counterpart in the surgical space.
In surface contour registration, mapping a
radiographic surface can be achieved by touching
a number of multiple random points (termed
cloud of points) or by scanning a surface with
laser registration. These surface-based algorithms allow the use of imaging obtained before
the intent to operate, but are less accurate compared to the combination of natural landmarks
and skin-applied fiducial markers. Once the
spatial relationship is established with either
point-pair registration or surface contour registration, it is used throughout the remainder of
the operation to map anatomic targets of the
patient to that of the preoperative images. This
thus requires that the patient’s head be immobilized with a head clamp and the operating table
not be moved during surgery. To overcome the
error that may be induced with patient or operating table movement, tracking units attached to
the patient’s head or a surgical head clamp can
be used. Electromagnetic (rather than optical)
tracking is the latest development in frameless
stereotaxy and is used in pediatric neurosurgery
as it avoids the need for head clamping (not possible in those without fused skull sutures).
Which one of the following statements regarding airflow systems in operating suits is most accurate?
a. Laminar air flow has been consistently shown to reduce surgical infections
b. Positive pressure ventilation is usually used in isolation rooms
c. Negative pressure ventilation is usually used in operating suites
d. Bacterial contamination of surgical wounds is most commonly from shedding
e. Bacterial content of air in laminar flow systems is lower than in conventional ventilation systems
e. Bacterial content of air in laminar flow systems is lower than in conventional ventilation systems
The goals of the ventilation system are comfort of
patient and staff, removal of pollutants/aerosols,
temperature and humidity control, and control
air movement to minimize the transfer of airborne contaminants from less clean to clean areas.
Airborne contaminants may enter an operating
room via the following routes: (a) through the
supply air; (b) shed by operating staff; (c) through
surgical activities; and (d) transferred from adjacent spaces. A recirculating system is one that
recirculates some or all of the inside air back to
the OR suites or some other part of hospital,
whereas in a non-recirculating system, all air
brought to the room is conditioned, outside air.
When a recirculating system is used, the air
return duct should have a high efficiency particulate air (HEPA) filter built into the system. In
an OR where inhalational anesthetics are used,
there should be separate systems for ventilation,
vacuum (patient and surgical suction), and waste
anesthetic gas disposal. Studies have demonstrated that most of the causes of wound contamination in the operating suite are the result of the
patient’s skin flora and bacteria shed on airborne
particles from the personnel. Room ventilation
affects the distribution of these airborne particles
in four ways: total ventilation (dilution), air distribution (directional airflow), room pressurization
(infiltration barrier), and filtration (contaminant
removal). As the air flows of the room increases,
the greater the dilutional effect on airborne particles. However, resultant turbulent flow also
increases microbial distribution throughout the
room. Low-velocity unidirectional (laminar) flow
minimizes the spread of microbes in the room.
Directional flow can be from the outside into
the OR (negative pressure), or from the OR to
the outside (positive pressure). Negative pressure
ventilation is used for highly infective rooms in
the hospital (e.g. isolation rooms for tuberculosis
patients) and positive pressure ventilation is used
for protective environments (e.g. ORs and rooms
with immunocompromised patients). This is
described as an entire body of air within a designated space (theatre suite) moving with uniform
velocity in a single direction along parallel
flow lines. True laminar flow is only achieved
when approximately 100% HEPA filter coverage
occurs. Laminar flow ventilation comprises a
continuous flow of air with bacteria less than 10
colony-forming units/m3
. Despite this, infection
rates for joint replacement surgery have actually
been show to increase in laminar flow versus conventional theatre ventilation (reasons remain unclear).
Which one of the following statements about operating microscope optics is most accurate?
a. The higher the magnification, the smaller the width of field
b. The higher the magnification, the smaller the depth of field
c. The higher the magnification, the smaller the working distance
d. The higher the magnification, the smaller the interpupillary distance
e. The higher the magnification, the higher the focal length of the objective lens
a. The higher the magnification, the smaller
the width of field
Resolving power of an optical system is its ability
to make clear and distinguishable two separate
entities. The resolving power of the unaided
human eye is only 0.2 mm. Most people who view
two points closer than 0.2 mm will see only 1
point. Moving closer to an object increases
resolution up to a point, but objects closer than
10-12 cm go out of focus. Optical aids (e.g.
loupes, OMs, surgical headlamps, fiberoptic
handpiece lights) can improve resolution by many
orders of magnitude. For example, a common
OM can raise the resolving limit from 0.2 to
0.006 mm (6 μm), a dramatic improvement. Stereopsis, or 3D perception, is critical to achieving precision surgery, and is an advantage over
2D endoscopes. Several factors are important
for increasing resolution without compromising
ergonomics, eyestrain, head/neck fatigue:
Which of the labels in the picture of an operating microscope shown below is the beam splitter?
A. Light fiber;
B. objective lens;
C. magnification changer;
D. teaching binoculars;
E. eyepiece;
F. main binoculars;
G. beam splitter
The surgical microscope is a complicated system
of lenses that allows stereoscopic vision at a
magnification of approximately 4-40 with an
excellent illumination of the working area. The
separation of the reflected light into two beams
within a microscope is what produces the stereoscopic effect that allows the clinician to see depth
of field. The light beams fall parallel onto the retinas of the observer so that no eye convergence is
necessary and the demand on the lateral rectus
muscles is minimal. The optical unit consists of:
* Eyepieces—magnify the interim image
generated in the binocular tubes. Eyepiece
selection not only determines the magnification, but also the size of the field of view.
* Binoculars—the precise adjustment of the
interpupillary distance (by adjusting the distance between binocular tubes holding the
eyepieces) is the basic pre-requisite for the
stereoscopic view of the operation area.
Longer the focal length of binoculars, the
greater the magnification and narrower
the field of view. Many microscopes now
include a beam splitter and a second set of
teaching binoculars (non-stereoscopic as
they split light from a single objective).
* Magnification changer (binocular objectives)—one cylinder, into which two
Galilean telescope systems with various
magnification factors are built. The combination of the magnification changer with
varying objective lenses and eyepiece yields
an increasing magnification line when the
control is adjusted.
* Objective lens—its focal length determines
the working distance between the lens and
the surgical field.
* Lighting unit as optimal illumination is
necessary with high magnifications. Surgical microscope uses coaxial fiber-optic illumination producing an adjustable, bright,
uniformly illuminated, shadow-free, circular spot of light that is parallel to the optical
viewing axis.
Which one of the following statements regarding fluorescein sodium is LEAST accurate?
a. It emits light in the 600-700 nm range
b. It is preferentially taken up by neoplastic cells
c. It relies on breakdown of the blood-brain barrier
d. It can guide where laser scanning confocal microscope should be focused
e. It can assess patency of EC-IC bypass and at risk vessels during aneurysm surgery
a. It emits light in the 600-700 nm range
Fluorescein sodium has an excitation maximum of
494 nm and an emission maximum of 521 nm. It
readily crosses capillaries, provides fluorescent
contrast in the extracellular matrix, and has a urine
clearance of 24-36 h after intravenous injection.
The amount of fluorescein delivered to a tumor
site is increased by the breakdown of the normal
blood-brain barrier. Fluorescein has been used
in cerebral angiography to detect arteriovenous
malformations, assess superficial temporal arteryMCA anastomoses patency, and to aid in treating
cerebral aneurysms. Fluorescein is not a tumorspecific agent, but it is excellent for visualizing
regions of compromised neurovasculature. The
presumption in its use for neuro-oncology is
that these areas correspond to the enhancing
regions, which also correspond to bulk tumor.
Rates of 100% GTR have been achieved for
non-eloquent tumors using microscope was developed equipped with dichroic mirrors specific
for fluorescein-guided resection of malignant gliomas. Fluorescein-guided laser scanning confocal
microscopy in humans had been able to provide
assessment of tumor grade, tumor histology, and
tumor margins for a variety of tumor subtypes.
The results from these two studies demonstrate
the feasibility of this technology as a diagnostic
and therapeutic tool, as it can help identify many
of the pathognomonic cytoarchitectural features
of various brain tumors and aid in the intraoperative diagnosis and resection of various central nervous system tumors. Fluorescein in this case can
both guide the operator grossly to areas to be
viewed with LSCE and provide the contrast to
allow cellular visualization. Fluorescein is FDA
approved and is widely used in the field of ophthalmology as well as in GI studies. Most fluorescein
clinical studies in neurosurgery report no serious
adverse effects with use of the fluorophore.
Which one of the following statements regarding indocyanine green (ICG) is LEAST accurate?
a. It emits light in the 700-850 nm range (far red/infrared)
b. It has better cellular penetration than 5-ALA
c. It has higher levels of non-specific binding in tumor surgery
d. It can be used for intraoperative cerebral angiography
e. Tumor visualization is most specific between 1 and 2 h post injection
e. Tumor visualization is most specific between 1 and 2 h post injection
ICG is a near-infrared fluorescent agent with
maximal excitation at 778 nm and emission
spectra range of 700-850 nm in serum. It is fairly
water-soluble, which allows it to be given intravenously and cleared through renal and bile excretion. ICG concentration within a tumor site is
enhanced by breakdown of the normal bloodbrain barrier. ICG has a greater tissue penetrance
than visible-wavelength fluorophores, such as 5-
ALA and fluorescein. ICG is an anionic, amphiphilic, tricarbocyanine probe, which allows it to
have a high affinity for proteins, such as albumin,
and allows visualization of solid tumors, but may
also cause higher levels of nonspecific binding.
Similar to fluorescein, ICG provides nonspecific
contrast in areas of permeable neurovasculature.
ICG has been given intravenously for blood vessel
angiography, identifying extrahepatic bile ducts
and detecting liver metastases. It can also be given
subcutaneously for sentinel lymph node mapping
for breast, anal, and GI cancer as well as assessing
lymphatic drainage for lymphedema. ICG was able
to contrast the fluorescent glioma tumor tissue
within 1 mm of the histological tumor margins
in an animal model. However, this technique is
not effective in distinguishing between malignant
cells and other areas of the brain that may incidentally uptake the injected dye. Cellular visualization
using ICG contrast with an infrared LSCE may
overcome these limitations. In contrast, macroscopic detection is more subjective to the surgeon.
Intravenously administered ICG is immediately
localized to a tumor site, and the fluorescent signal
remains in the tumor up to 1 h after injection, with
constant imaging, demonstrating limited photobleaching and clearance. The delivery of the dye
to the site of the tumor relies on binding to serum
proteins and the damaged vasculature primarily
located at the site of the tumor. However, with
time the dye will diffuse into surrounding tissue.
These properties allow real-time, in vivo assessment that differentiates glioma tissue and normal
brain. In contrast to visible wavelength fluorophores, ICG provides visualization of deeper tissue
structures due to its infrared excitation and emission spectra. However, depth of imaging still
remains limited to a few hundred microns deep
to the imaging surface. ICG is considered to have
fewer risks than other FDA approved intravenous
fluorophores.
Which one of the following statements regarding 5-ALA is most accurate?
a. It emits light in the 400-500 nm range
b. It is normally produced from protoporyphyrin IX in the heme synthesis pathway
c. 5-ALA based fluorescence does not occur
in red blood cells
d. Neoplastic cells preferentially take up 5-ALA
e. Photosensitivity is a recognized side effect
c. 5-ALA based fluorescence does not occur
in red blood cells
Produced in the mitochondria, 5-ALA is a natural
precursor for the production of protoporphyrin
IX (PpIX) in the heme synthesis pathway found
in all cells. PpIX is a fluorescent molecule that
binds membrane lipids and has an excitation
range of 375-440 nm and emission range of
640-710 nm in vivo. Overloading this pathway
with exogenous 5-ALA causes the collection of
PpIX to fluorescently detectable levels in cells.
As the production of PpIX occurs in situ in mitochondria, fluorescence is limited to cells.
This decreases fluorescent signal in blood or
edematous regions of the operative field. Furthermore, neoplastic cells demonstrate preferential
uptake of exogenous 5-ALA and increased collection of PpIX, making the fluorescent signal more
robust in these abnormal tissues and making
intraoperative visualization feasible, especially in
intracranial tumors of higher grades. Photobleaching occurs with PpIX fluorescence level
dropping to 36% after 25 min under violet light
or 87 min under white light. It can be limited
by allowing excitation and white light to penetrate as small an area as possible in the surgical
field. Phototoxicity is limited with 5-ALA, since
fluorescent microscopes do not produce sufficient energy for significant ROS production.
Currently, the FDA has approved 5-ALA and
19 SURGICAL TECHNOLOGY AND PRACTICE e27
its derivatives for research diagnostic applications
in endoscopic, photodynamic detection of bladder cancer and residual glioma, as well as the
treatment of basal cell carcinoma and actinic
keratosis. 5-ALA macrofluorescence predicts
malignant glioma tissue with 90% accuracy,
showing residual tumor better than post-op
MRI, and the level of residual solid tissue fluorescence was shown to correlate with patient survival. In an RCT, its use improved gross total
resection rates and overall progression-free
survival time. In low-grade glioma, macroscopically detectable fluorescence does not occur but
hand held intraoperative confocal microscope
allowed visualization of 5-ALA-induced fluorescence of low-grade glioma tumor and tumor
margins in vivo that corresponded with standard
histopathology. Some controversy still exists as to
the biology of 5-ALA metabolism in low-grade
gliomas and the need for complete resection by
MRI. Though 5-ALA administration is considered
safe,minor systemic side effects have been reported,
including nausea, vomiting, and hypotension as
well as increased sensitivity to sunlight up to 48 h after administration. As with other fluorophores,
these side effects are limited with lower dosing.
You are setting up the stereotactic frame in
the operating room. Your consultant asks
you to adjust the anterior-posterior measurement using the Vernier scale for submillimeter accuracy. What reading is currently shown in the example below?
a. 3.0 mm
b. 2.1 mm
c. 2.0 mm
d. 3.1 mm
e. 1.1 mm
b. 2.1 mm
The top scale is a simple rule scale in cm and mm,
the other is a Vernier scale with ten divisions.
Whilst one of these scales is fixed, the other is able
tomovewith the stage.The Vernier scale’s ten divisions are equal to nine small divisions on the rule
scale. Therefore each Vernier division is equal to
0.9 mm. The difference between a rule scale division and a Vernier division is thus: 19/10¼
0.1 mm. Hence, the instrument can be read to an
accuracy of approximately 0.1 mm. To take a
reading, note the division on the rule scale immediately prior to the 0 of the Vernier scale (this will
provide your first decimal place), then look along
the Vernier scale until you find a mark on it
which is in line with a mark on the rule scale-this
provides your second decimal place. As such, the
reading is 2.1 mm in the example. Vernier scales
are seen on stereotactic frame axes and inaccuracies
in set up can significantly alter targeting in
3D space.