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Description  |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention described herein relates to enhanced contrast in nuclear
magnetic resonance (NMR) imaging through the use of a paramagnetic
material in association with micellular particles such as phospholipid
vesicles.
2. Description of Prior Art
NMR imaging of humans is fast becoming a major diagnostic tool. Resolution
is now on a par with X-ray CT imaging, but the key advantage of NMR is its
ability to discriminate between tissue types (contrast) on the basis of
differing NMR relaxation times, T.sub.1 and T.sub.2. Because nuclear
relaxation times can be strongly affected by paramagnetic ions such as
Mn(II) and Gd(III) or stable free radicals, these materials have been
explored to determine their ability to provide further contrast,
specifically to test whether they alter water proton T.sub.1 and T.sub.2
values in excised animal organs and in live animals; see, for example,
Mendonca Dias et al, The Use of Paramagnetic Contrast Agents in NMR
Imaging, Absts. Soc. Mag. Res. Med., 1982, pages 103, 104; Brady et al,
Proton Nuclear Magnetic Resonance Imaging of Regionally Ischemic Canine
Hearts: effects of Paramagnetic Proton Signal Enhancement, Radiology,
1982, 144, pages 343-347; and Brasch et al, Evaluation of Nitroxide Stable
Free Radicals for Contrast Enhancement in NMR Imaging, Absts. Soc. Mag.
Res. Med., 1982, pages 25, 26; Brasch, Work in Progress: Methods of
Contrast Enhancement for NMR Imaging and Potential Applications,
Radiology, 1983, 147, p. 781-788; and Grossman et al, Gadolinium Enhanced
NMR Images of experimental Brain Abscess, J. Comput. Asst. Tomogr., 1984,
8, p. 204-207. Results reported show that contrast is enhanced by a
variety of paramagnetic agents.
However, useful compounds, due to the nature of the candidate paramagnetic
materials, may be toxic at the concentrations required for optimal effect,
and finding contrast agents for which the toxicity is low enough to make
possible their eventual use in medical diagnosis is regarded as the most
serious and difficult problem in the field, Mendonca Dias et al, The Use
of Paramagnetic Contrast Agents in NMR Imaging, Absts. Soc. Mag. Res.
Med., 1982, pages 105, 106. The invention described herein is thus
designed to reduce toxicity and increase the utility of NMR contrast
agents by associating a paramagnetic material with a micellular particle
having properties tailored to the unique demands of NMR imaging.
Another significant problem which must be addressed is that the maximum
tissue volume occupied by micelles such as vesicles generally does not
exceed about 0.1%, which means that the micelle must be capable of
affecting an image with a very small volume percentage. In this regard,
however, paramagnetic NMR contrast agents differ fundamentally from
contrast agents used as X-ray absorbers, gamma ray emitters or the like in
other imaging modalities in which the signal or attenuation is simply
proportional to the number per unit volume, no matter how they are
chemically bound or entrapped. In NMR, the agent (ion or stable free
radical) acts to increase the relaxation rate of bulk water protons
surrounding the free electron spin. The phenomenon depends on rapid
exchange of water on and off an ion or rapid diffusion of water past an
organic free radical. In such case, the net relaxation rate is a weighted
average for free and bound water.
Encapsulation of the paramagnetic material within a phospholipid vesicle,
as in one preferred form of this invention, would seem to deny access of
the paramagnetic agent to all but the entrapped water, typically less than
0.1% of the total volume. Under such conditions, the NMR image would not
be altered detectably by the presence of vesicle-encapsulated contrast
agent. Only if water exchanges sufficiently rapidly across the bilayer is
the relaxation rate of the bulk water enhanced, Andrasko et al, NMR Study
of Rapid Water Diffusion Across Lipid Bylayers in Dipalymitoyl Lecithin
Vesicles, Biochem. Biophys. Res. Comm., 1974, 60, p. 813-819. The present
invention addresses this problem by providing a formulation of micelle and
paramagnetic material that simultaneously maximizes micelle stability
while permitting adequate rates of water exchange across the membrane.
Phospholipid vesicles are known to concentrate in certain tissues, so
additional enhancement will come from tissue specificity. For example,
phospholipid vesicles have been observed to accumulate in implanted tumors
of mice, Proffitt et al, Liposomal Blockade of the Reticuloendothelial
System: Improved Tumor Imaging with Small Unilamella Vesicles, Science,
1983 220 p. 502-505, Proffitt et al, Tumor-Imaging Potential of Liposomes
Loaded with In-111-NTA: Biodistribution in Mice, Journal of Nuclear
Medicine, 1983, 24, p. 45-51.
The invention also extends the use of micellular particles as contrast
agent carriers to applications where the micelles are attached to
antibodies. While it has been reported that a selective decrease in
T.sub.1 relaxation times of excised heart may be obtained using
manganese-labeled monoclonal antimyosin antibody, Brady, et al, Selective
Decrease in the Relaxation Times of Infrared Myocardium with the Use of a
Manganese-Labelled Monoclonal Antibody, Soc. Magn. Res. Med., Works in
Progress, Second Annual Meeting, 1983, p. 10, heretofore, due in large
measure to considerations such as toxicity referred to above, the
practical use of such antibodies has been significantly restricted. With
the present invention, however, increased sensitivity is obtained and
specificity is maintained by attachment of antibody to the surface of
micellular particles. The antibodies provide high specificity for cell or
tissue types, while the attached vesicle agent carriers amplify the NMR
contrast enhancement over what can be achieved with ions bound to antibody
alone.
SUMMARY OF THE INVENTION
The invention described herein is directed to preparations of micellular
particles such as small unilamellar vesicles, with which a paramagnetic
material is associated, typically paramagnetic compounds enclosed within
the vesicles. The vesicles may or may not have antibodies, such as
antimyosin, or antifibrin, attached to the surface or have other surface
modifications for which there are specific cell receptors in certain
tissue.
Examples of vesicle constituents are phospholipids such as
distearoylphosphatidylcholine (DSPC), dipalmitoylphosphatidylcholine
(DPPC), and dimyristoylphosphatidylcholine (DMPC). Examples of
paramagnetic materials are salts of transition metals and the lanthanide
and actinide series of the periodic table such as Gd(III), Mn(II), Cu(II),
Cr(III), Fe(II), Fe(III), Co(II), Er(III), nickel(II) and complexes of
such ions with diethylenetriaminepentaacetic acid (DTPA),
ethylenediamimetetraacetic acid (EDTA) and other ligands. Other
paramagnetic compounds include stable free radicals such as organic
nitroxides.
Vesicle-encapsulated contrast agents may be prepared by forming the lipid
vesicles in an aqueous medium containing the paramagnetic agent by any
suitable means such as sonication, homogenization, chelate dialysis and
the like, and then freeing the vesicles of external agent by
ultrafiltration, gel filtration or similar method. Moreover, the internal
solution of the paramagnetic material may be altered readily to maximize
the relaxation rate per unit of agent as for example, by formulation with
a charged polymeric material such as poly-L-Lysine.
DETAILED DESCRIPTION
Definitions and Abbreviations
As used herein, "micellular particle" and "micelles" refer to particles
which result from aggregations of amphiphilic molecules. In this
invention, preferred amphiphiles are biological lipids.
"Vesicle" refers to a micelle which is in a generally spherical form, often
obtained from a lipid which forms a bilayered membrane and is referred to
as a "liposome". Methods for forming these vesicles are, by now, very well
known in the art. Typically, they are prepared from a phospholipid, for
example, distearoyl phosphatidylcholine or lecithin, and may include other
materials such as neutral lipids, and also surface modifiers such as
positively or negatively charged compounds. Depending on the techniques
for their preparation, the envelope may be a simple bilayered spherical
shell (a unilamellar vesicle) or may have multiple layers within the
envelope (multi-lamellar vesicles).
DSPC=distearyol phosphatidylcholine
Ch=cholestrol
DPPC=dipalmitoylphosphatidylcholine
DMPC=dimyristoylphosphatidylcholine
DTPA=diethylenetriaminepentaacetic acid
EDTA=ethylenediaminetetracetic acid
SUV=small unilamellar vesicles
Materials and Preparation of Micelles
Complexes of paramagnetic compounds were prepared in deionized water or in
a buffer of 4.0 mM Na.sub.2 HPO.sub.4, 0.9% (by weight) NaCl, pH 7.4
(PBS).
Gd(III)-citrate. A stock solution of 1.0 mM Gd(III)10.0 mM citrate was made
by dissolving 10.0 .mu. moles GdCl.sub.3.6H.sub.2 (99.999%, Aldrich) in 9
ml deionized water and adding 100 moles Na.sub.3 citrate (analytical
reagent, Mallinckrodt). The pH was adjusted to neutrality and the volume
brough to 10.0 mL in a volumetric flask.
Mn(II)-citrate. A stock solution of 1.0 mM Mn (II)10.0 mM citrate was made
by adding 10.0 .mu. moles MnCl.sub.2.4H20 (Baker analyzed) and 100 .mu.
moles sodium citrate to 9 ml water. The solution was neutralized and made
up to 10.0 ml in a volumetric flask.
Gd(III)-DTPA. A stock solution of 200 mM Gd(III)-210 mM DTPA was made by
dissolving 2.10 mmoles DTPA in minimum 6 N NaOH in a 10 ml volumetric
flask. 2.0 mmoles GdC13.6H20 were added and the pH adjusted to 7.4 with 6
N NaOH, after which the sample was made up to 10.0 ml in the flask.
La(III)-DTPA. A stock solution of 200 mM La(III)-210 mM DTPA was made up in
a manner analogous to the Gd(III)DTPA stock using LaCl.sub.3.7H.sub.2 O
(99.999%, Aldrich).
Er(III)-EDTA. Stock solutions were prepared in a manner analogous to
Gd(III)-DTPA.
Poly-L-lysine hydrobromide of approximate average molecular weights 25,000
and 4,000 were obtained from Sigma Chemical Co.
Cholesterol (98%) was from Mallinckrodt. DSPC was synthetic material from
Cal-Biochem.
DSPC/cholesterol vesicle-encapsulated NMR contrast agent. 16 mg DSPC and 4
mg cholesterol were dissolved in 2 ml CHC13. 10 .mu. 1 of a solution of
0.16 mM cholesterol [u-14C] (56.5 mCi/mmole) in CHC13 were added for
purposes of quantitating lipid concentrations in the final preparations.
The lipid solution was evaporated to dryness in a vacuum dessicator and
stored in the same, if not used immediately.
Small unilamellar vesicles (SUV) were formed in a solution of 200 mM
Gd(III)-DTPA by adding 2.0 ml of the stock ion complex to the dried lipid
tube. The mixture was complex to the dried lipid tube. The mixture was
sonicated using an Ultrasonics, Inc. probe with a microtip at a power
level of 56 W. The tube was cooled by partial immersion in a water bath,
and N.sub.2 was flowed over the sample during sonication. Total time of
sonication was 15 min. or more until the solution was slightly opalescent.
Paramagnetic agent outside the vesicles was separated from the SUVs by
passage through columns of Sephadex G-50 swollen in PBS, that had been
loaded into 3 ml plastic syringe bodies and precentrifuged. The vesicle
solution was placed at the top of the syringe and centrifuged with a glass
tube positioned to collect the eluate. 300 .mu. 1 PBS was used to elute
the vesicles from the columns. The procedure was repeated a total of 3
times to reduce the outside concentration of free agent and to exchange it
for PBS.
Vesicle concentration in the final preparation was measured by counting an
aliquot of the solution in the scintillation counter, using a standard
cocktail. Average vesicle size was measured in a laser particle sizer
Model 200 (Nicomp Instruments). The vesicle size was measured to be 600,
.+-.100, A.degree. in all experiments.
NMR Relaxation time measurements.
Unless otherwise indicated, measurements of T.sub.1 and T.sub.2 were made
at 20 MHz with a pulsed NMR spectrometer (IBM PC/20) interfaced to a
microcomputer (IBM PC). T.sub.1 was measured by the inversion-recovery
method (Farrar, T.C., Becker, E.D., Pulse and Fourier Transform NMR, 1971,
Academic Press, New York.) and T.sub.2 by the Carr-Purcell sequence (Carr,
H.Y., Purcell, E.H., Effects of Diffusion on Free Precession in NMR
Experiments, Phys. Rev., 1954, 94, p. 630-633.), as modified by Meiboom
and Gill (Meiboom S., Gill D., Modified Spin-Echo Method for Measuring
Nuclear Relaxation Times, Rev. Sci. Instrum., 1958, 29, p. 688-691.)
Least-squares best fits of the data to single exponential recoveries were
done automatically by the computer. Values of T.sub.1 and T.sub.2 reported
are for a probe temperature of 38.degree. C. T.sub.1 values are estimated
to have an experimental uncertainty of .+-.10% and a reproducibility of
.+-.5%. T.sub.2 values are generally accurate to within .+-.20 % and
reproducible to .+-.5%. This precision is sufficient clearly to
demonstrate the effects claimed. Some values of T.sub.1 were measured with
a Praxis II NMR spectrometer operating at 10 MHZ and a probe temperature
of 25 C.
Animal Studies
EMT6 tumor tissue was transplanted subcutaneously into the flank of male
Balb/c mice and allowed to grow for 10 days. On the 10th day, mice were
injected i.v. with 200ul of vesicle solution or control buffer. Mice were
sacrificed at intervals, and the tumors were dissected. In some
experiments liver and spleen were also dissected. The tissue was rinsed in
PBS, lightly blotted, weighed, and wrapped in air tight plastic bags. NMR
relaxation measurements were made within 1/2 hr of dissection to limit
water loss and consequent changes in T.sub.1 and T.sub.2.
DESCRIPTION OF DRAWINGS
FIG. 1 is a plot of longitudinal relaxation rate as a function of added
paramagnetic ion concentration. Aliquots of the stock solutions were added
to PBS buffer. T.sub.1 measurements were made at 10 MHz using the
90.degree.-90.degree. method. Probe temperature was 25.degree..
Concentration scale for Er-EDTA is in mM units while for Mn-citrate the
units are .mu.M.
In FIG. 2, the dependence of 1/T.sub.1 on added Gd ion in various forms is
illustrated. Aliquots of stock solutions were added to water (Gd/citrate)
or PBS (Gd/DTPA and Gd/DTPA in vesicles) to give the total concentration
of ion indicated.
FIG. 3 illustrates internal paramagnetic ion complex concentration effects
on 1/T.sub.1 and 1/T.sub.2. DSPC/cholesterol vesicles were prepared with
increasing concentrations of Gd-DTPA in PBS encapsulated inside. The lipid
(vesicle) concentrations were all adjusted with PBS to be equal at 8.3
mg/ml total lipid final concentration.
FIG. 4 illustrates relaxation rates of mouse tissue and tumors. Balb/c mice
were injected with 200 .mu. 1 of 200 mM Gd-DTPA in DSPC/cholesterol
vesicles (10 mg/ml lipid) (Gd Ves), 200 mM La-DTPA in DSPC/cholesterol
vesicles (La Ves), 2.0 mM Gd-DTPA in PBS (Gd Buf) or PBS(Buf). After 16
hrs, the mice were sacrificed and the tissues dissected. Relaxation times
are the average for at least 3 animals.
FIG. 5 shows the effect of added poly-L-lysine on relaxation rates of
Gd-DTPA solutions. Dry weighed aliquots of poly-L-lysine were dissolved in
2.0 ml of 2.0 mM Gd-DTPA in H.sub.2 O. T.sub.1 and T.sub.2 were measured
as described in the text.
FIG. 6 illustrates the time course of 1/T.sub.1 for mouse tumors.
Preparations of 10 mg/ml lipid vesicles containing 200 mM Gd-DTPA inside
were injected (200 .mu. 1) into the tail vein of Balb/C mice having 10 day
old EMT6 tumors from previous implants. The mice were sacrificed at
intervals and T.sub.1 of the tumors measured immediately after dissection.
Controls were either no injection (0) or 200 .mu. 1 of 2.0 mM Gd-DTPA in
PBS (.quadrature.). Three separate experiments are collected in this
graph. For the .circle. .circle. and .quadrature. data, the points each
represent T.sub.1 for a single tumor. For the .DELTA. data, 2 or 3 T.sub.1
values were occasionally measured for a single tumor.
Referring now in more detail to the figures of drawing, the improved
results of the present invention will be discussed. In FIG. 1, relaxation
rates of Er-EDTA and Mn citrate solutions are shown. Values of 1/T.sub.1
are plotted as a function of ion concentration at 10 MHz and 25C. The
average value of 1/T.sub.1 for mouse soft tissue is indicated on the
graph. The concentration scale for Er-EDTA is millimolar while that for
Mn-citrate is micromolar. Addition of 18 mM Er-EDTA complex to a PBS
solution increases 1/T.sub.1 to the mouse tissue value of 2.4 s-1. The
same relaxation rate is achieved with only 0.17 mM Mn-citrate complex. The
weak complex of Mn is 100 times more efficient for relaxation enhancement
than the strongly complexed Er-EDTA, reflecting the intrinsically stronger
relaxation power of the Mn(II) ion as well as the greater accessibility of
the Mn to water.
In FIG. 2, the relaxation effects of Gd(III) are shown. At 20 MHz the
addition of Gd-citrate to H?20 increases 1/T.sub.1 to a value of 8.1 s-1
at 1.0 mM. When complexed to DTPA, the ion has one-half the relaxation
effect. This reduction occurs because of displacement of water binding
sites by the DTPA functional groups, partly balanced by an increased
rotational correlation time of the complex. With the Gd-DTPA complex
encapsulated in DSPC-cholesterol vesicles, the solution 1/T.sub.1 is still
increased to a value of 2.5 s-1 for 1.0 mM total Gd-DTPA. While less
efficient than free Gd-DTPA per unit ion, the vesicles still have a
substantial effect on water relaxation.
The effect of internal paramagnetic ion complex concentration on relaxation
rates for vesicle-encapsulated Gd-DTPA is shown by FIG. 3. 1/T.sub.1 and
1/T.sub.2 for vesicle solutions increase linearly up to 150 mM internal
Gd-DTPA concentration. Using the equation,
##EQU1##
wherein b is for inside the vesicle and a is outside, T.sub.1 b is the
lifetime of water protons inside, T.sub.1 b is the net relaxation time of
water inside (made small by the paramagnetic agent), and Pb is the
fraction of water inside the vesicle, predicts a linear dependence of
1/T.sub.1 on paramagnetic ion concentration until the value of T.sub.1
becomes on the order of or less than T.sub.1 b. The results shown by FIG.
3 suggest that up to 150 mM Gd-DTPA concentration, T.sub.1 inside the
vesicles is greater than the exchange lifetime, T.sub.1 b.
Relaxation effects on mouse tissue and tumors are illustrated in FIG. 4.
The T.sub.1 values of Balb/c mouse liver, spleen, kidney and EMT6 tumor
tissue are compared 16 hrs after injection of paramagnetic agents or
controls. Vesicle-encapsulated Gd-DTPA promotes a significant reduction in
T.sub.1 for spleen and for EMT6 tumors compared to the control of the
diamagnetic lanthanide ion complex of La-DTPA in vesicles (spleen) or PBS
buffer and PBS buffer plus 2.0 mM Gd/DTPA (tumor). In the case of
Gd/DTPA-vesicle treated mice, the T.sub.1 values averaged 17% less than
controls without injected agent.
The foregoing data allow an estimate of the minimum Gd/DTPA or other
paramagnetic species concentrations inside vesicles which provide contrast
enhancement. There is a complex set of interrelating factors, such as
proton exchange rate across membranes of the tumor cells, wash out rate of
free Gd/DTPA from lipid vesicles, and altered rotational correlation time
of the complex in a macromolecular environment, which contributes to the
T.sub.1 proton relaxation rate and subsequent contrast enhancement. The
amount of accumulated vesicles in a particular tissue to be imaged
dictates the minimum concentration of encapsulated paramagnetic material.
For this Murine tumor model, it has been inferred that approximately 0.1%
of the tumor volume is occupied by intact vesicles.
While the quantity of paramagnetic material to be encapsulated will vary,
depending upon the specific material used as well as the factors mentioned
above, in general, the paramagnetic material will be at least
approximately 50 mM in the vesicles. The maximum quantity will be dictated
by considerations of cost, toxicity and vesicle formulation, but
ordinarily will not be above about 1 M encapsulated concentration.
FIG. 5 illustrates the enhanced relaxation rates through addition of a
polymer. The relaxation effect of Gd-DTPA can be enhanced by the addition
of the positively charged polymer, poly-L-lysine. FIG. 5 shows the result
of adding poly-L-Lys of average MW 25,000 to a solution of 2.0 mM Gd-DTPA
in H20. A 40% increase in relaxation rate 1/T.sub.1 is obtained and an 30%
increase in 1/T.sub.2. The effect of added poly-L-lysine plateaus above 3
mg/ml showing a "weak binding" situation. This leveling off also shows
that the increased relaxation rate is not due to an increase in viscosity,
since the effect there would be linear in added poly-Lys over the whole
concentration range. Smaller molecular weight poly-L-Lys is less effective
on a weight basis. Gd-DTPA is a negatively charged complex which binds
reversibly to the positive charge of the poly-Lys. The large size and
consequent slow tumbling of the macromolecule made relaxation of the
paramagnetic ion more efficient. This effect can be used by
co-encapsulating Gd-DTPA and poly-Lys or some like positively charged
macromolecule to increase the effect per unit ion of Gd and thus decrease
net toxicity of the preparation.
Time course of relaxation effect on EMT6 tumors is shown in FIG. 6. The
maximal effect of vesicle-encapsulated Gd-DTPA is achieved 3-4 hrs after
injection of the agent. The average effect at 4 hrs is approximately equal
to that at 16 hrs postinjection, suggesting that a steady-state condition
obtains where the rate of uptake by tumor is matched by loss of agent to
the circulation.
Three different liposome formulations were tested at doses higher than used
for data of FIG. 6 for their relaxation effects on EMT6 tumors
subcutaneously implanted in Balb/c mice. The mice were injected
intravenously with the agent and then sacrificed at intervals. Tumor and
liver T.sub.1 values were measured within 1/2 hour of sacrifice of the
animal. The results are set forth in Table I for tumors and in Table II
for liver. Animals receiving only buffer had an average tumor T.sub.1
value of 960.+-.41 ms (n=25) and an average liver T.sub.1 value of
392.+-.31 ms (n=24). The tumor relaxation time decreased to 665.+-.28 ms
(n=4) at 24 hours post injection for the 1:1 DSPC/CHOL formulation, while
the livers of these animals had average T.sub.1 values of 370.+-.13 ms
(n=4). The T.sub.1 change of 44% for the tumors is substantially larger
than that for the liver (6%).
With many liposome formulations in common use, liver (and spleen)
accumulate the largest fraction of the vesicle dose. The particular
formulation of the present invention is thus far more specific for the
tumor, at least in its effect on NMR relaxation times. The
vesicle-encapsulated paramagnetic complex of the present invention
accordingly fulfills the requirement of an NMR imaging contrast agent;
that is, it leads to reduced values of T.sub.1 in selected tissues. In
this case, the original long T.sub.1 of the tumor before contrast agent
(average 960 ms) will leave the tumor dark in an NMR image, while, after
injection of agent, the tumor would appear brighter in the scan.
TABLE I
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TUMOR RELAXATION RATE
EMT6 Tumor in Flank of Balb/c Mouse
(10 day tumor growth)
Vesicle-encapsulated NMR Contrast Agent
Values are T.sub.1 (in ms) .+-. standard deviation
n = number of mice
Post-injection Time (hr)
Formulation*
1-2 2-5 5-8 24 Notes
__________________________________________________________________________
PBS Control
962 .+-. 24
974 .+-. 50
920 .+-. 19
926 Global
n = 9 n = 11
n = 4 Average
960 .+-. 41
n = 25
DPPC/CHOL 2:1
869 .+-. 28
840 .+-. 30
845 .+-. 40
Gd/DTPA 200 mN
n = 14
n = 13
n = 13
DSPC/CHOL 2:1
812 .+-. 45
768 .+-. 30
769 .+-. 28
GD/DTPA 200 mMl
n = 8 n = 8 n = 4
DSPC/CHOL 1:1 710 .+-. 19
720 .+-. 21
665 .+-. 28
Gd/DTPA 200 mM n = 2
n = 3 n = 4
__________________________________________________________________________
*Injection volume = 250-300 ml Lipid concentration generally 20 mg/ml
TABLE II
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LIVER RELAXATION RATE
Tumor bearing Balb/c Mouse
Post Contrast Agent Injection
Vesicle-encapsulated NMR Contrast Agent
Values are T.sub.1 (in ms) .+-. standard deviation
n = number of mice
Post-injection Time (hr)
Formulation*
1-2 2-5 5-8 24 Notes
__________________________________________________________________________
PBS Control
400 .+-. 39
380 .+-. 26
411 .+-. 6
412 Global
n = 8 n = 12
n = 3 n = 1 Average
392 .+-. 31
n = 24
DPPC/CHOL 2:1
379 .+-. 35
377 .+-. 29
375 .+-. 34
Gd/DTPA 200 mN
n = 11
n = 11
n = 11
DSPC/CHOL 2:1
349 .+-. 17
345 .+-. 13
379 .+-. 29
GD/DTPA 200 mMl
n = 11
n = 11
n = 7
DSPC/CHOL 1:1 330 .+-. 32
342 .+-. 11
370 .+-. 13
Gd/DTPA 200 mM n = 2 n = 3 n = 4
__________________________________________________________________________
*Injection volume = 250-300 ml Lipid concentration generally 20 mg/ml
For an NMR imaging contrast agent to be most useful, it must yield the
maximum increase of 1/T.sub.1 possible with minimum toxicity, and have
specificity for tissue type. The invention provides these features. A
macromolecular assembly can increase the relaxation effect per unit ion,
as demonstrated by the effect of added poly-Lys on 1/T.sub.1 and 1/T.sub.2
of Gd-DTPA solutions (FIG. 5). Low toxicity is gained by associating the
normally toxic paramagnetic ion with a strong chelate in a macromolecular
assembly (e.g. encapsulation in a vesicle) which keeps the ion out of
circulation. NMR relaxation is enhanced by formulating the vesicle to
maximize access of H.sub.2 O protons to the ion. This was accomplished as
shown by the strong relaxation effect of encapsulated Gd-DTPA (FIG. 2).
Tissue specificity is provided by the complex nature of the micellular
assembly for which biological recognition processes cause the
macromolecule to distribute to certain sites. This is demonstrated for
phospholipid vesicles by the differential influence on tissue relaxation
rates (FIG. 4, tables I and II) and by the specific effect on tumor
relaxation of Gd-DTPA encapsulated in vesicles versus approximately the
same total concentration of Gd-DTPA free in solution (FIGS. 4 and 6).
It has been described herein that antibodies can be bound to vesicles to
obtain tissue specificity, Martin et al, Immunospecific Targeting of
Liposomes to Cells, Biochemistry, 1981, 20, p. 4229-4238, the disclosure
of which is specifically incorporated herein by reference. Antimyosin has
potential for NMR imaging of infarcted heart muscle. Moreover preparation
of antifibrin has recently been reported; Hui et al, Monoclonal Antibodies
to a Synthetic Fibrin-Like Peptide Bind to Human Fibrin but not
Fibrinogen, Science, 1983, 222 p. 1129-1131. This antibody would be
expected to concentrate at the sites of blood clots, where fibrin has been
formed. Vesicle agent carriers attached to antifibrin could provide NMR
contrast for imaging clots and thrombin in blood vessels. There are,
however, other surface modifications which provide for cell recognition
that are known to alter the biodistribution of the vesicles. For example,
carbohydrate receptor analogues bound to the vesicle surface have been
shown to target vesicles. (Mauk, et al., Targeting of Lipid Vesicles:
Specificity of Carbohydrate Receptor Analogues for Leukocytes in Mice,
Proc. Nat'l. Acad. Sci. USA 77, 4430-4434 (1980); Mauk, et al., Vesicle
Targeting: Timed Release for Leukocytes in Mice by Subcutaneous Injection,
Science 207, 309-311 (1980).) Such targeting by surface modifications are
directly applicable for altering the biodistribution of paramagnetic ion.
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