Note: Descriptions are shown in the official language in which they were submitted.
~.2~
This application is a division of Canadian patent
application Serial No. 314,426 filed October 26, 1978.
The invention relates to gel trays and membranes pre-
impregnated with developing reagents, which can be used in
carrying out new clinical and medico-legal processes that have
been rendered practical by recently developed
microelectrophoretic equipment.
In a co-pending patent application by the present
inventor, Canadian application No. 290,310, filed on November 7,
1977, there are disclosed several improvements of
microelectrophoretic apparatus which greatly simplify and
standardize the microelectrophoretic process and which include:
~a) designs that allow the use of either a membrane or a tray
with the same basic apparatus; (b) designs which allow the two-
dimensional resolution of a protein sample placed on a gel-
filled tray; and (c) a sample applicator and accessory equipment
which permit the simultaneous and precise positioning of, for
instance, ten samples.
This apparatus can be used advantageously with various
~0 conventional devices and techniques which include
compartmentalized gel trays, as disclosed by Siebert et al in
United States patent No. 3,616,387 (Figure 5 and column 3, lines
53 to 55) and slotted membranes, as disclosed by Zec in United
States patent No. 3,317,418 (Figure 7). Also, when used in
; conjunction w1th the further refined articles that are disclosed
in the present application, it makes avaiIable ~o research
scientists and laboratory technicians new and improved
methodology for separation of specific proteins from microliter
quantities of blood. These speci~ic proteins are then
identified through use of immunologic techniques or, more
commonly, through use o~ indicator dyes which chemically unite
~ z~
with one specific type of protein and no other. These dyes make
contact with the electrophoresed samples by means of an overlay,
either cellulose acetate membrane upon gel, or gel upon
cellulose acetate membrane. The overlays have been pre-
impregnated with the appropriate specific substrate so that a
permanent visual record of the pattern is produced on the
cellulose acetate membrane, whether the membrane is serving as
the supporting medium or as the overlay. This technique is
described by Grunbaum in "An Automatic One-to-Eight Sample
Applicator for Fast Qualitative and Quantitative
Microelectrophoresis of Plasma Proteins ...", Microchem, J. 20,
~95 - 510 (1975).
This apparatus is useful in research and application
in the fields of Medicine, Immunology, Genetics, Biochemistry,
and Forensic Science. Electrophoretic procedures which greatly
increase in utility with this apparatus include determinations
of significant polymorphic enzyme systems such as lactic acid
dehydrogenase ~LDH), alkaline phosphatase (AP), and creatine
phosphokinase (CPK). It can be used for diagnostic purposes
through determination of specific antibodies of antigens in the
blood. In the forensic laboratory, it can be used in the pheno-
typing of genetic variants of enzymes and other proteins in
blood for the purpose of identification or individualization.
A partial list of the factors in blood that can be
determined using this apparatus include the following:
lactic acid dehydrogenase (LDH)
alkaline phosphatase (AP)
creatine phosphokinase (CPK)
erythrocyte acid phosphatase (EAP)
glucose-6-phosphate dehydrogenase (G-6PD)
adenylate kinase (AK)
-- 2
hemoglobin (Hb)
haptoglobin (~p)
group specific component (Gc)
lipoprotein (Lp)
adenosine deaminase (ADA)
6-phosphogluconate dehydrogenase (6-PGD)
Glyoxylase I (GLO-I)
glutamic pyruvic transaminase (GPT)
esterase D (EsD)
Glutathione reductase (GsR)
Immunoglobulins (Ig)
Methodology for the phenotyping of additional systems
is being developed.
This invention as disclosed provides specialized gel
tray and cover assemblies containing suitable gels for
electrophoresis andr in separate embodiments, one or more
specific substrates for the visualization of electrophoresed
proteins. Said trays are preferably divided into several
compartments by parallel ribs rising from their flat bo-ttom
~0 surface for use in simultaneous analysis of several parameters.
-- 3 --
~.2~
The invention to which this divisional application is
directed pertains -to an article of manufacture, namely, a
shallow square gel-containing tray having a tight-closing cover
slidably engageable therewith~ which can be used in suitable
microelectrophoretic apparatus for simultaneous determination of
up to thirty protein samples by electrophoresis. Preferably the
tray and cover assembly contains up to 30 pairs of sample-
receiving slots in the gel, the pairs being arranged to achieve
the cross-over migration of antigen and antiserum, and the
resulting formation of visible precipitins.
Also provided are slotted membranes pre-impregnated
with specific substrates for the visualization of proteins
electrophoresed on the gel trays. These membranes may be
provided with an underlying coat of tough polyester and thus
constitute, after use, a permanent s~torable electrophoretogram.
The trays and membranes described have been designed
for use with recently developed improved electrophoretic
apparatus disclosed in the above identified co-pending patent
application.
~0 By means of such equipment it is now possible, inter
- 4 -
alia, to accurately and rapidly carry out simultaneous electro-
phoretic separations of several polymorphic protein systems of
different origin or of different nature, either on a gel or on a
membrane, and ~o develop visual records of the pat~erns produced
by contacting the electrophoresed samples with either a membrane
or a gel, as the situation requires, said membrane or gel having
been pre-impregnated with suitable specific substrate for
rendering the electrophoresed protein systems visible.
The availability of the new prepackaged gels and
membranes, both for electrophoresis and, when pre-impregnated
with specific substrates, for developing the electrophoresed
proteins, will allow a great degree of standardi~ation between
widely separated laboratories. Such an improvement. in the art,
while being certainly welcome in the medical diagnostic field,
is obviously invaluable in mass phenotyping studies that can be
used in genetic research as well as for identification purposes,
forensic or other.
In the drawings:
FIGURES 1 (A to J, ex~luding I) is an exploded view
in transverse section showing two embodiments of the basic ap-
paratus used in this invention: on the left, with a membrane
and a membrane bridge, and on the right, with a gel dish and
a gel temperature control plate.
FIGURE 2 is a transverse sectional view of an
assembled apparatus using a membrane and a membrane bridge.
FIGUR~ 3 is a front elevation of the tank of Figure 1
assembled with a gel dish and a tempera~_ure control plate.
FIGURES 4A to 4D show an exploded front elevation view
of the apparatus in Figure 2 which comprises a membrane and a
membrane bridge.
~ ~.2~
FIGURE 5 is a side elevation of a temperature control
plate for use with a gel tray.
FIGURE 6 is a de~ailed view of the applicator tip
shown in Figure 1.
FIGURE 7 is a plan view of a compartmentalized tray.
FIGURES 7A and 8 are elevated transverse sections of
the compartmentalized gel tray of Figure 7 and of a gel tray
without dividers, respectively.
FIGURE 9 is a plan view of a snap-on tight-fitting lid
for the gel trays of Figures 7 and 8.
FIGURES 10 and 11 show front elevation transverse sections
of a compartmentalized gel tray and a sliding cover adjacent to it.
FIGURES 12 and 13 show front elevation transverse
sections of another type of compartmentalized gel tray and of a
sliding cover adapted to it.
FIGURE 14 is a front elevation transverse section of an
assembled tray and cover pair, with the tray containing a gel
over which a slotted men~rane is superimposed.
FIGURE 15 is a plan view of a four-compartment dish
containing a gel and a superimposed slotted membrane.
FIGURE 16 is a front elevation transverse section of a
dish like that of Figure 15 assembled with a sliding cover.
FIGURE 17 is a plan view of a slotted sheet of filter
paper impregnated with various developing systems for
electrophoresed proteins.
FIGURE 18 is a plan view of another embodiment of the
slotted sheet o~ Figure 17 consisting of a polyester base coated
with cellulose acetate.
FIGURE 18A shows a cross section of the sheet of
Figure 17.
-- 6
~.2~
FIGUR~ 19 shows part of a developed electrophorogram
on which three protein systems have been separated in the
presence of two different concentrations each of appropriate
protein standards.
FIGURE 20 is a plan view of a square tray containing
precast gel mixed with ampholines for use in electrofocusing,
appearing with Figures 17, 18, 18A and 21.
FIGURE 21 is a plan view of a square tray filled with
a precast gel for use in electrophoresis of haptoglobin-
hemoglobin complex, or other proteins~ ap~K~ing with Figs. 17, 18, 18A ~20
FIGURE 22 is an enlargement of the area of the trayof Figure 21 in which are located the sample-receiving cavities
in the yel.
FIGURE 22A shows the area of the tray illustrated in
Figure 22, but fitted with a removable and disposable plastic
slot template.
FIGURE 22B is a front elevation transverse section of
the tray-template assembly of Figure 22A.
FIGURE 23 is a plan view of a tray with precast gel,
~0 designed for cross-over electrophoresis, appearing with Fig. 19.
The apparatus of the above identified application shall
first be described in reference to Figures lA to lF, 2, and 4,
for an embodiment involving a membrans system, and to Figures
lA, lB, lE to lJ, and 3, for another embodiment involving a gel.
These figures shall be discussed simultaneously in order to
avoid repetition and to provide a clearer visualization of the
equipment.
With respect to the membrane system, Figures 1 and 2
show transverse sections of the apparatus--in exploded and
assembled views, respectively, while Figures 4A to 4D, on the
other hand, give an exploded front elevation view of the same
components.
The apparatus comprises a tank (10) which contains an
electrolyte solution (not shown). Within the tank are fixed
baffles (19), removable baffles (24), septum (23) and electrode
frames (26, 28) which extend from slots in inner wall (8) to
slots in inner wall ~9). A membrane holder (14) is seated on
septum (23) and two of the removable baffles (24). Channel (20)
of membrane holder (14) straddles the top of septum (23). The
membrane holder (14) is provided with tab grips (21, 22) and
teeth (18). The teeth (18) engage perforations in a membrane
(16) and keep the central portion of the membrane taut. The ends
of membrane (16) are immersed in the electrolyte solution
(not shown). The membrane must be made from a material that will
"wick" the electrolyte solution to all areas of the membrane and
keep the membrane saturated. Further, the membrane must have
sufficient strength to withstand the force of the teeth when the
membrane is wet. The membrane may, for example, be made from
cellulose acetate, paper, or Celloge~. A cellulose acetate
membrane can be kept and stored as a permanent record oE the
~0 analysis.
An applicator assembly (30) fits onto the cover (12).
The applicator assembly is fitted with two feet (33, 34). The
foot (34) has a registration pin (38) projecting from it, and
the foot (33) has a runner bar (35) projection from it. The pin
~38) and runner (35) are adapted to fit into a runner bar slot
and registration pinholes on either the coverplate (12) or a
sample holder.
The cover (12) includes male and female connectors ~11,
13) which make contact with the electrode wire (29) through
spring interlocks (15 and 17, respectively) on the electrode
~.2~
frame (26). When the cover (12) is removed from the top o
the tank (10), the elec~rical connection to the electrode wire
(29) is broken by means of the spring interlocks. The electrode
wire (29) is shown in detail in Figure lB. A platinum wire (29)
is run around the slotted periphery of the electrode frame (26).
The wire is connected to metal contacts (25 and 27), which
complete a circuit to spring interlocks (15 and 17) shown in
Figure 2. As shown in Figure 4D, two electrode frames (26 and 28)
are placed in the tank (10) which has slots in its walls to
receive the frames.
Referring now to Figures lF and 4A, the applicator
assembly comprises a plurality of applicator buttons (39) which
are adapted to hold an applicator shown in detail in Figure 6.
The applicatox buttons (39) are held in place by means
of a plurality of leaf springs (45) which hold each button
individually in place. A release button (40) is provided with a
long arm (413 which e~tends across all of the parallel leaf
springs (45). When the button (40) is depressed downward, all of
the leaf springs are releases such that all of the applicator
buttons (39) are free to drop by force o~ gravity. The release
button (40) is fitted with a groove (42), such that, when it is
in the depressed position, a locking bar (44) is able to slide
into the groove (42) and hold the release button in the lower
position. When the applicator (30) is not in us~, a protective
lid (not shown) is placed over the opening in cover (12).
In Figure 6, the applicator tip (46) is shown in more
detail. The applicator tip includes a capillary opening (47) for
holding the sample fluid. The applicator tip (46) is held in
place by two spring-loaded split pins (49), such that the tip
is easily removed.
The applicator tip (46) may be modified in length or
width; for example, to vary the amount of sample held, or to
cover more than one applicator position.
Referring to Figures lD and 4C, the membrane holder (14)
is shown in detail. The membrane holder is made of one piece of
molded flexible plastic. The holder is fitted with teeth (18)
and can be bent inwardly, such that the teeth (18) grip
corresponding perforations in a membrane (16). When released,
holder (14) applies tensile force to the membrane and maintains
it taut. To avoid tearing the membrane, teeth (18) are
pererably semicylindrical projections or cylindrical projections,
and nlembrane performations (113), Figure 19, are circular.
The gel electrophoretic system can be visualized by
reference to Figures lA, lB, lF to lJ, 3 and 5, which together
show an exploded transverse section view and a front elevation
view of the assembled components (Figure 3). In this system
membrane (16) and membrane holder (14) have been replaced by gel
tray or dish (103), gel temperature control plate (80) and
blotter paper strip (107).
Temperature control plate (80) is fitted with four
retainers, two of which are shown (82, 84) for receiving and
holding in place a square dish or tray (103) containing the gel
material (104), such as agarose gel, that may be employed for
lipoprotein separation. A temperature control liquid is
circulated in the plate (80) from liquid supply (99) by means
of inlet (100) and outlet (102), as shown in Figure 5.
ln Figure 3, the temperature control plate (80) is
shown in place within the tank (10). The square tray (103)
holding gel (104) is placed on plate (80) and is kept in fixed
position by retainers (82, 84). Tray (103) is preferably made
-- 10 --
~.2~
from a material that is an electrical insulator and a good
thermal conductor. Additionally, ~he tray must be inert to the
electrolyte. As the plate is adapted to receive a square tray,
90 rotation of the gel media is possible. Greater resolution
can be obtained by performing two migrations on the gel (104).
First, the sample is pulled apart in a linear path by the
electric current. The gel tray is then rotated 90 and the
first migration is pulled apart from an orthogonal direction.
Contact with the electrolyte solution is made by means
of wicks ~lO~, 108) which rest on edge of the gel and pass down
through wick recesses (not shown) in plate (80) and into the
electrolyte solution. The tank (lO) is provided with wick-
retaining members (llO and lll) for receiving the lower end of
each wick and holding the ends in place within the electrolyte
solution. The wick-retaining members prevent the wicks from
sliding off the gel and align the wicks so tha~ they contact the
gel (104) evenly across the surface. The wick alignment prevents
a contact gradient from occurring. Wicks (106, 108) may be made,
for example, from filter paper or plastic sponge.
During the electrophoresis process, the electric
current flowing through the gel (104) causes generation of heat
in the gel. The thermal convection in the gel tends to broaden
the bands and cause errors due to poor resolution. This band
broadening is alleviated by passing a liquid through plate (80)
which has a temperature lower than the ambient temperature. For
some measurememts, for example, a plate temperature of 4C has
been found suitable. Blotter strips (i~7) made of the same
material as the wicks (106, 108) and impregnated with
electrolyte solution are plac~d along the edges of the surface
of the gel (104) to facilitate electrical contact between the
-- 11 --
gel and the wicks during electrophoresis.
The remaining figures illustrate various tray and lid
embodiments (Figures 7 to 16 and 20 to 21A) and membrane
embodiments (Figures 17 to 19) which are -the subject of the
present invention and which can be used with the equipment
-already described to perform the diagnostic and identification
processes that shall be disclosed below.
In Figure 7, there can be seen a plan view of a novel
electrophoresis tray or dish (120) which is essentially a
shallow square container comprising a flat surface (128)
surrounded by a peripheral wall (122). A number of parallel
straight dividing ribs (121) separate the dish surface area into
compartments which are permanently labelled by having one letter
printed in each compartment (160). The peripheral wall may be
provided with a top ridge (123) which forms a shoulder (129)
for accommodating a similar peripheral ridge on a lid. The
compartmentalized dish (120~ just described can be seen in
elevated cross section in Figure 7A. In Figure 8, on the other
hand, there is shown again in elevated cross section, an
embodiment of a conventioral gel tray or dish (103), filled
~ith a layer of gel (104).
Figure 9 illustrates one type of lid for gel trays
~103, 120), consisting essentially of a thin flat sheet (127)
provided with a peripheral ridge (126) adapted to fit tightly
within peripheral ridge (123) on shoulder (129) of gel trays
(103, 120). An assembled tray and lid system is shown in
Figure 14, which comprises tray (120), lid (125), gel layer
(104) and slotted membrane (95) shown in elevated cross section.
The tray and snap-on lid embodiments described in Figures 7 to 9
and 14 may further be provided with various conventional means
- 12 -
or fastening the assembly more tightly and for stacking.
Figures 10 to 13 show further embodiments of the trays
and lids of the present invention wherein either the lid tl35)
slides into a track formed by the walls of the tray (130), or the
tray (140) slides into a track formed by the walls of the lid
(145). Effective sealing of the assembled systems can be
achieved in a number of ways. For example, both the tray (140)
and the lid (145) can be provided with one end wall (not shown),
perpendicular to the track walls (131, 132) and at opposite ends,
so that the ends of the assembly be closed. Also, flat
horizontal surfaces (not shown), or shoulders, may be provided
in the end wall areas of the trays which can fit closely with
the lid surfaces and form additional seals.
Figure 15 shows a tray in plan view which is similar to
that of Figure 14, except that the tray has only three dividing
ribs (121). Circular holes (113) are designed to engage teeth
(18) of membrane holder (14) shown in Figures lD and 4C. In
this drawing and in the elevated cross section of the tray shown
in Figure 16, there can be seen a four-compartment tray (130)
~o comprising three dividing ribs (121), which has been covered in
Figure 16 by sliding lid 1135) between tracks ~131). The
compartments are filled with a gel (104) on which electrophoresis
of various blood enzyme and protein systems has been run and a
slotted membrane (95) comprising four strips marked by letters
A, B, C, and D tl60) separated by slots (96), has been super-
imposed upon the gel in order to contact the proteins on the gel
with the enzyme substrates or color reagents with which the
membrane has previously been impregnated. In this manner, a
blood serum sample containing the isoenzymes of the lactic acid
dehydrogenase (LDH) system has been applied to the gel ~104) in
- 13 -
~.2~
compartment A o~ tray (130), and, after electrophoretic system
separation the gel has been contacted wi~h strip A of membrane
(95) previously impregnated with the tetrazolium dye and other
conventional components used to develop visible
electrophoretogr~ms from this particular enzyme system.
Similarly, the other compartments and strips (B, C, D) were used
to detect and i~entify the components of differen~ blood
polymorphic enzyme or other protein systems either from the same
blood sample or from samples of different origins. In this
manner, as shown in the drawing of Figure 15, creatine
phosphokinase (CPK), alkaline phosphatase (AP) and total protein
were run and de~eloped simultaneously in the remaining
compartments and strips (B, C, and D), respectively.
Figures 17 and 18 show plan views of parts of two
different slotted membranes preimpregnated with the substrates
or other color producing reagents required by the protein
systems indicated on the drawings.
Thus, Figure 17 shown five strips labelled, A, B, C, D,
and E ~160) of a membrane (115) separated by slots (96) which
extend to continuous border surfaces (116). The entire membrane
(115) can be made of filter paper with border areas (116)
impregnated with paraffin and the strips each impregnated with
the substrates or other developing reagents required by the
enzyme and protein systems indicated, namely LDH(A), CPK(B),
plasma protein(C), hemoglobin(D), and any other system--XYZ(E).
After development, the dried membrane can be preserved as a
permanent replica of the electrophoretogram.
An impermeable type of membrane is shown in Figures 18
and 18A. Again, the membrane (136) is divided into strips by
slots (96) with each cellulose acetate strip (A, B, C, D)
- 14 -
impregnated with a particular enzyme substrate and/or color
developing system as indicated, namely CPK, LDH, phosphoglucomu-
tase (PGM), and any other system (XYZ~ on strips A, B, C, and D,
respectively. One feature of this particular membrane, howe~er,
is that the cellulose acetate strips (138) are carried ~y an
inert, resistant and non-porous sheet of polyester (137~ such as
Myla ~polyester, as can be clearly seen in Figure 18A, a
cross-sectional elevation view of the membrane of Figure 18.
Other polymeric substances such as polyamides, ~olyimides,
polyethylene, halogenated polyethylenes and the like, can be
used as inert non-porous support instead of polyester, if
desired.
` Figure 19 illustrates the type of pattern that may be
seen on a membrane after separation and color development.
Three strips (200, 201, 202~ of a membrane (95) are shown,
separated by slots (96)~ Each resulting compartment of strip
has three columns labelled A, B, and C, (160). On each strip
has been applied a different polymorphic blood enzyme system
sample which was subsequently caused to electrophoretically
~0 migrate away from the original application point, i.e., the
first bar(I) below position A, to yield the bars appearing at
distances II, III, IV, V, and VI. Standard preparations of the
polymorphic systems are run with each unknown sample in two
different concentrations (B, C) to assist in the identification
and quantification of the unknown samples. In comparing the
components of the unknown in column A of section 20G with its
neighboring B and C columns, it becomes evident that the level IV
component of the sample appears in higher concentration than
normal (B, C). So does the level VI component of the sample
3~ in section 202. For the sample in 201, on the other hand, it
- 15 -
6~
can be seen that the level V component is missing, while a level
VI component appears which is not present in the standard
preparation (B, C). This then is the type of one-sheet
simultaneously prepared record that can be made with the
equipment and processes of this invention, identifying and
quantifying up to 10 different or similar protein systems from
one blood sample or from up to ten blood samples. With such
profiles, the task of diagnosing several clinical conditions or
identifying classes of individuals, for example, is greatly
simplified due to the quantity of information which can be
prepared and observed simultaneously on one electrophoretogram.
Figure 20 is a top plan view of the basic square tray
or dish (103) earlier disclosed, filled with a polyacrylamide gel
~104) into which there are dispersed ampholines, i.e., the type
of isomers of polyaminopolycarboxylic acids conventionally used
for the high resolution electrofucusing process. Upon
application of an electric field by means of special electrodes
(not shown~ placed directly on the surface of the gel, a linear
pH gradient is formed and protein molecules electrophoresed in
such a gradient concentrate in very narrow zones in which the
net electrical charge on a given ~olecule is æero. In such a
system, the only variable affecting the separation is the
isoelectric point of a given protein. No buffer need be placed
in the tank (10) of the basic apparatus ~Fig. lA). Cooling of
the gel with plate 80 (Fig~ 3 and 5) is essential since a very
high voltage is applied which creates a high amperage and
consequently a large quantity of heat which must be dissipated
instantaneously. The present apparatus allows the electrodes
to be applied in any direction~ Furthermore, it offers a simple
30 easily standardi~ed alternative to the difficult preparation of
- 16 -
gels immediately before use, an alternative that is superior in
terms of handlingr transport and storage, to the flexible sheets
heretofore available commercially.
Figure 21 is a top view of a tray (103) containing a
precast gel (104) in which a line of ten rectangular sample-
receiving cavities (148) have heen made. The part of the tray
containing the sample-receiving cavities (148) is illustrated on
a large scale in Figure 22 in order to show sufficient detail
to facilitate visualization of the tray-template assembly shown
in top view of Figure 22A and in cross section, in Figure 22B.
In these ~igures, it can be seen that peripheral wall
(122) of tray (103) is provided with two cylindrical recesses
(149) designed to accept pins (151) which serve to fasten a
removable and disposable plastic insert or template (150) to the
tray, The template shown (150) is provided with ten tongues
(154) which serve to shape gel cavities (148) when the gel (104)
is first poured into the tray (103), and to keep the cavities
free of liquid between the time of fabrication and use. In
other words, the tray with precast gel shown in Figure 21 is
prepared by affixing insert or template (150) to an empty tray
~103) by inserting the pins (lSl) in recess (149). A liquid
gel making preparation is then poured into the tray to form gel
~104) upon cooling, and the resulting assembly closed by a
suitable cover (not shown), can be shipped or stored without
deterioration until needed for electrophoresis. At that time, ~'
the plastic insert or template (150) is removed, and protein
samples and standards can be placed in the gel cavities (148)
for electrophoresis. The type of tray just described is used
mainly for the genetic typing of polymorphic proteins such as
those from the haptoglobin-hemoglobin complex, but can be used
- 17 -
for the separation of many protein mixtures requiring the
relatively high resolu~ion medium of acrylamide gel. The
polyacrylamide gel in the tray can have either a fixed
cencentration of polymer throughout, or the concentration may
vary to produce either linear gradient or a step gradient.
The polyacrylamide molecules act as a mechanical sieve, aiding
both separation and resolution.
Figure 23 shows a-square tray with precast gel
designed to employ specific antisera in cross-over electro-
phoresis for the analysis of Australian antigen (infectioushepatitis), syphilis, and other infections diseases. The tray
and the method can also be applied to species identification in
the investigation of fresh or dried blood or other
physiological fluids. As can~be seen from the drawings, the
precast gel tray (103) is basically similar to that of
Figure 21, except that the gel sheet (104) is provided with
three pairs of lines of ten cavities (148) each, said lines
being labelled 1, 2, 3, 4, 5, and 6 (160). The trays are
prepared in the same manner as that of Figure 21, except of
course that six plastic templates are used instead of the single
one (150) employed for the tray of Figures 21 to 22B. The
template pins (151, Figures 22A and 22B) snap into cylindrical
recesses ~149) and the tray is then filled with gel tlO4) as
earlier described. Before use, the templates are removed,
leaving open cavities (148) for receiving antigen and antiserum
samples. The gel cavities are used in pairs, with the antigen
sample being pl?ced in the cavity located on the electrically
negative side of the pair ~rows 1, 3, and 5), as indicated by
the minus sign (-) printed on the lefthand portion of the tray's
peripheral wall (122), while the specific antiserum sample is
- 18 -
placed in the cavity located in the positive side of the pair
(rows 2, 4, an~ 6). When voltage is applied to the up to 30
samples in the tray, the antigen and antiserum proteins migrate
toward each other and react upon crossing-over or meeting to
create a visible line of precipitin. Nine such lines (205)
can be seen in the drawing, havlng formed between certain pairs
only. The absence of a precipitin line between a pair of
cavities indicates the absence of the specific antigen in the
sample that was placed in the lefthand cavity of that pair.
It should be noted that in the preparation of the
various precast gel trays and membrane described so far, it is
possible to delay addition of any unstable substrate and
reagents to the precast gel or membrane until the moment of use.
In the case of membrane, however, some of the unstable
ingredients may be safely incorporated at the time of membrane
manufacture by resorting to the technique of freeze drying.
A better realization of the possibilities of the
equipment and processes of the present invention may be
obtained by reference to the medical, genetic and forensic
literature for review of the polymorphic protein systems
already mentioned and assessment of the information that they
can reveal.
- 19 -
