WO2008015581A2 - Matrices physiologiques tridimensionnelles pour test oncologique et procédés pour leur production et leur utilisation - Google Patents
Matrices physiologiques tridimensionnelles pour test oncologique et procédés pour leur production et leur utilisation Download PDFInfo
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- WO2008015581A2 WO2008015581A2 PCT/IB2007/003503 IB2007003503W WO2008015581A2 WO 2008015581 A2 WO2008015581 A2 WO 2008015581A2 IB 2007003503 W IB2007003503 W IB 2007003503W WO 2008015581 A2 WO2008015581 A2 WO 2008015581A2
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N33/00—Investigating or analysing materials by specific methods not covered by groups G01N1/00 - G01N31/00
- G01N33/48—Biological material, e.g. blood, urine; Haemocytometers
- G01N33/50—Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing
- G01N33/5005—Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing involving human or animal cells
- G01N33/5008—Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing involving human or animal cells for testing or evaluating the effect of chemical or biological compounds, e.g. drugs, cosmetics
- G01N33/5011—Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing involving human or animal cells for testing or evaluating the effect of chemical or biological compounds, e.g. drugs, cosmetics for testing antineoplastic activity
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N33/00—Investigating or analysing materials by specific methods not covered by groups G01N1/00 - G01N31/00
- G01N33/48—Biological material, e.g. blood, urine; Haemocytometers
- G01N33/50—Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing
- G01N33/5005—Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing involving human or animal cells
- G01N33/5008—Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing involving human or animal cells for testing or evaluating the effect of chemical or biological compounds, e.g. drugs, cosmetics
- G01N33/5082—Supracellular entities, e.g. tissue, organisms
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N33/00—Investigating or analysing materials by specific methods not covered by groups G01N1/00 - G01N31/00
- G01N33/48—Biological material, e.g. blood, urine; Haemocytometers
- G01N33/50—Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing
- G01N33/53—Immunoassay; Biospecific binding assay; Materials therefor
- G01N33/574—Immunoassay; Biospecific binding assay; Materials therefor for cancer
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N2800/00—Detection or diagnosis of diseases
- G01N2800/52—Predicting or monitoring the response to treatment, e.g. for selection of therapy based on assay results in personalised medicine; Prognosis
Definitions
- the present invention relates to matrices, methods, apparatus and kits for the expedited design and evaluation of oncological remedies.
- Key aspects of the inventions include matrices, and especially gel matrices, which are adapted and arranged to provide conditions which permit behaviors, such as the movement of cells from a sample of target tissue, to be evaluated in a manner that produces data useful for evaluating the oncological status of the cells.
- the invention permits the in vitro testing and analyses of one or more therapies, such as therapeutic pharmaceutical compounds, or radiological therapies, with respect to specific target tissues and cells removed from a patient.
- Cancer is the loss of control of one or more of the regulatory systems which regulate the growth of cells and tissues.
- An uncontrolled growth of a particular tissue or cell type is a specific type of cancer.
- cancer There are many types of cancer.
- one or more therapeutic remedies are typically used in attempts to cure the disease or ameliorate its effects.
- Many differences exist between classes of tumors and, indeed, individual tumors of the same type.
- therapies for cancers in general. Nonetheless, most therapies do not work, or do not work to the extent necessary to provide the degree of cure, remediation or desired palliative effect for a specific cancer. Because of this, it is sometimes difficult, time-consuming and expensive to attempt to determine what therapeutic compounds may be effective to treat a particular tumor or cancer type.
- the malignant glioma cells thus cultured, disrupted and processed into cloned spheroids, which were then implanted into a gel matrix, and then subjected to one or more doses of fractionated radiation. Changes in the distance of invasion in response to single dose and fractionated radiation were measured over a period of 5 days.
- Baumann et al. researchers used the same C6 cell line and experiment-al protocols to test BCNU and dexamethasone, and to compare these results with those of radiation dosing on the transformed cells.
- C6 astrocytoma cells were subjected to disruption by trypsinization, and also subjected to centrifugal forces for 3-4 weeks in spinner flasks.
- the cells of Bauman et al were already known to be transformed to a great extent, were generations removed from the original tissue, required disruptive chemical processing, and were a subset of cloned malignant cells at the time they were subject to radiation doses.
- C6 astrocytoma cells were maintained in tissue culture as cloned representatives of malignant rat glioma cells. Indeed, the cells of the Bauman el al. experiments were removed and estabished as a cell line years before they were subjected to the experiments of Bauman et al.
- the present invention uses a sample quantity of fresh tissue taken directly from an animal, such as a human patient.
- the samples used in the present invention are not disrupted by trypsin or other enzymes, but are mechanically divided into sample portions of appropriate sizes for testing.
- the present methods maintain the cell-to-cell contact of the sample tissue as if it were still in vivo.
- An additional difference pertains to the fact that the experiments of Bauman et al. used an established cell line, that is, cells that were already known to have been transformed long before, and in an unknown way, to an extent great enough that they could be used to establish a tissue culture cell line.
- Baumann et al. One could not therefore expect the cells of Baumann et al. to behave in a manner reasonably replicative of fresh or in vivo cells.
- Yen-McGuire The cellular suspensions of Yen McGuire are provided with a defined, selective growth medium which is designed and formulated to promote the growth of epithelial tumor cells while inhibiting the growth of normal cells.
- Yen-McGuire thus teaches the use of selective nutrition to skew cellular growth and behavior. Indeed, the relative amount of cellular growth is measured to provide information regarding the sensitivity of the highly processed tumor cells.
- Yen-McGuire does not provide any analysis with respect to an original tumor sample or fragment thereof, nor does it comprehend the advantages of an in vitro system which replicates significant aspects of the three- dimensional environment of tumor tissue in vivo.
- Another object of the present invention is to provide methods and kits for testing one or more therapeutic substances to determine their efficacy against a particular tumor or type of tumor.
- a method of the invention comprises the steps of A) obtaining a sample quantity of the suspected tumor tissue or cells from the animal, wherein the tissue comprises one or more types of cells, B) implanting at least part of the sample of the suspected tumor tissue at least partially within a three-dimensional physiological matrix, the matrix being adapted and arranged for measuring one or more parameters of the behavior of the cells of the suspected tumor tissue, C) providing sufficient nutrition to the cells of the tissue or cells so that the parameters can be measured, D) incubating or culturing the tissue and the cells in an environment suitable for the growth of the cells and the tissue for a time sufficient to obtain measurements with respect to one or more parameters, and E) measuring some of those one or more parameters to obtain data regarding those behaviors.
- Methods of the present invention are further adapted such that, preferably, the implantation of the sample, or portions thereof, is effected with minimal disruption to the cells or the tissue.
- a sample quantity of a tissue is removed from a patient by way of a biopsy or surgery. The structural integrity of that tissue sample is then maintained to the maximum extent possible before its implantation.
- non-disruption of the sample means, as examples, that the sample is not homogenized, it is not chemically disrupted by strong acids, or by enzymes such as trypsin, nor is it comminuted, crushed or subjected to high concentrations of strongly basic compounds.
- a sample according to the invention is cut, torn or chopped into small pieces, such as chunks approximating cubes of 1.0 - 3.0 mm on an edge. While not intending to be bound by any underlying mechanism, the present inventors theorize that, by minimizing the disruption to the sample tissue and cells, their respective behaviors in relation to a physiological matrix of the invention remains similar to their corresponding behaviors in vivo.
- implantation of the samples during the methods of the invention take place as soon after " the sample is removed from the animal as is reasonably possible.
- a removed tissue sample is preferably immediately cooled by placing it in proximity to ice, for example, and implantation is most preferably accomplished within one or a few hours after removal.
- implantation is most preferably accomplished within an hour or so of sample removal, the present methods provide for later implantation when circumstances dictate as much, such as when the sample must be transported some distance to a laboratory for preparation.
- implantation should most preferably take place within four hours of removal of the sample tissue, or more preferably within 24 hours of removal, and less preferably within 48 hours of removal of the tissue from the subject animal.
- the effects, of the delay in implantation and evaluation of a tissue sample may depend upon many factors, including the type of tissue, its oncological status, and the conditions under which it has been stored. Thus, it may be possible to delay implantation for many hours or many days.
- the present means and methods provide data for physicians and other evaluators to make determinations or estimates regarding the oncological status of a tissue and its cells. Thus, from the data obtained, a determination can be made regarding whether the tissue and cells are abnormal, precancerous or cancerous.
- the present means and methods permit the testing of many types of therapies, including pharmaceutical compounds and non- chemical therapies. The present means and methods can therefore be used to provide data useful for tailoring specific individual therapeutic regimens directed toward the precise tissue being evaluated.
- some preferred embodiments of the present invention further comprise the step of transmitting the data to at least one evaluator.
- an evaluator is any person, group of people, or network of people, or any machine, computer or device adapted and arranged for evaluating the data garnered through use of the present means and methods.
- Evaluators include, but are not limited to the group comprising technicians, technicians, physicians, physician's staff members, physician's assistants, hospital employees, clinic employees, the patient, technologists, technical assistants, laboratory assistants, oncological analysts, nurses, nurses' assistants nurse practitioners, computers, computer-aided devices, computer- facilitated devices, and human or computerized agents for any of the foregoing.
- the removed sample quantity of tissue is divided into a plurality of portions, and each of the portions is subjected to the some or all steps of the invention.
- tests and evaluations of the tissue and cells can be performed in multiples, and one or more therapies can be tested concurrently in relation to the specific sample if desired.
- Step E is performed more than once, or a plurality of times with respect to the separate portions of the sample.
- these measurements are effected during the culturing or incubating of the tissue and cells as in Step D above.
- means and methods of the invention can be used on virtually any type of animal, including human medical patients, and can be used also to evaluate tissue from other animals.
- Other animals include, but are not limited to non-human primates, equines such as horses and donkeys, bovines such as cows and deer, canines such as dogs and wolves, felines such as lions and domestic house cats, murines such as mice and moles, porcines such as pigs and peccaries, avians such as birds and penguins, amphibians such as salamanders and turtles, and reptilians such as snakes and alligators.
- the animals mentioned herein comprise an exemplary listing, and not an exclusive one.
- Methods of the invention also include where the measurements taken, as in Step E, are performed more than once with respect to each of the separate portions of the sample, and wherein the measuring is effected during the culturing or incubating of Step D.
- a significant aspect of the invention concerns the physical relationship between the tissue sample portion and the three-dimensional matrix in which it is implanted.
- the tissue portion is disposed either partially submerged in the matrix, or completely submerged therein. It is important that the tissue be in intimate contact with the matrix.
- the physiological matrix replicates to some extent the three-dimensional environment in which most tissues function in vivo. Tissue samples, or portions thereof, may be implanted in any method, manner or way, which yields the desired results
- the matrices of the invention which are typically gels or other permeable solids or semi-solids, can be provided in shapes which facilitate the implantation of one or more types of tissues and cells, and which facilitate the provision of nutrition to the cells and tissue.
- any type of depression such as a hollow, cavity, slit, chamber or slot can be provided within the matrix itself, and can be adapted and arranged to receive the tissue or cells for implantation, or can be adapted and arranged to hold nutrition for the cells and tissue.
- a gel matrix according to the invention may comprise a hollow, cavity, slit, chamber or slot of an appropriate volume and disposition to receive an aliquot, such as a .2 ml. aliquot of 1OX media, as nutrition for the implanted cells and tissue.
- Such depressions can also serve as receptacles or reservoirs for drugs to be tested.
- the tissue or cells are implanted in the matrix as the matrix is being formed into a gel or other permeable solid or semi-solid, f ⁇ these embodiments, the tissue and ceils are mixed along with the components of the matrix and are thus partially or completely submerged within the matrix by the time it gelates or hardens into a semi-solid or solid.
- the tissue or cells can be implanted in the matrix by physical insertion after it has formed into a gel, solid or semi-solid.
- solutions for forming matrices of the invention should be essentially free of bicarbonate.
- the gels or semi-solids of the invention advantageously form at room temperatures and are thus capable of being mixed and formed in a manner that is convenient, user friendly, and adaptable to many laboratory and non-laboratory environments.
- sufficient nutrition is provided to the cells and tissue to be evaluated or tested, either as a component of the matrix as it is being formed, or as nutrition added after the matrix is formed, or both. The nutrition must be sufficient to grow the cells and tissue for a sufficient length of time to obtain the desired results.
- the sufficient or additional nutrition preferably comprises one or more fluids, wherein the one or more fluids are selected from the group comprising tissue culture medias, concentrated tissue culture medias, and any culture or nutritional medias which are suitable for the tissue sample.
- the means and methods of the present invention thus include wherein the concentrated medias are one or more selected from the group comprising 1OX medias, and any other concentrated medias.
- the three-dimensional physiological matrix comprises the sufficient nutrition as a component of the matrix itself as it is being mixed and formed or allowed to gel.
- a step of providing at least one source of additional nutrition to the tissue and the cells is provided.
- the tissues and cells may avail themselves of one or both of the sufficient nutrition and of the additional nutrition to the extent necessary so that the parameters can be measured.
- the at least one source of additional nutrition may comprise one or more of tissue culture medias, concentrated tissue culture medias, and any culture or nutritional medias which are suitable for the tissue sample.
- the at least one additional source of nutrition may be supplemented with one or more components selected from the group comprising sera, proteins, sugars, salts, lipids.
- the measuring step is performed at periodic intervals such as one or more intervals selected from the group comprising every six hours, every 12 hours, every 18 hours, every 24 hours, every 36 hours, every 48 hours, every 72 hours and every 96 hours.
- other intervals are one or more selected from the group comprising every day, every second day, every third day, every fourth day, and every fifth day.
- the data obtained by the measurements of the invention is recorded in a fixed media.
- Such fixed media can be any type so long as it is capable of holding the obtained data in such form as to be useable later.
- a human observer a still camera, a video camera, an automated still camera, an automated video camera, an infrared camera, and an automated infrared camera can be used to obtain the desired data.
- the cuituring of tissues and cells according to the invention occurs in a period of time sufficient to obtain the desired parameters and values.
- the periods of time during which the cuituring of tissues and cells is effected includes those of at least 10 hours, at least 36 hours, at least 72 hours and at least 125 hours, or even longer depending on the conditions of the tissue and how the method is being conducted
- the sufficient nutrition is provided to the tissues and cells by placing the sufficient nutrition in contact with the matrix after the sample has been placed in the matrix and the matrix has equilibrated to room temperature, and to a semi-solid or gel.
- the room temperature is in the range of from 10 to 30 degrees Celsius.
- the sufficient nutrition may be provided to the tissues and the cells by placing the it in contact with the matrix after the sample has been placed in the matrix, and the matrix has equilibrated to a gel at room temperature.
- the sufficient nutrition may be provided to the tissues and the cells by continuous or intermittent perfusion or flow over, around, or through the matrix.
- the three dimensional quality of the matrix of the invention can be formed itself to comprise the sufficient nutrition.
- the environment for incubating or cuituring the cells and the tissue preferably includes a temperature range of from 30 to 40 degrees Celsius, a carbon dioxide tension of from 2 to 13%, and a relative humidity of from 50% to 100%.
- methods of the invention can be conducted wherein the sample quantity is preferably divided into portions, and each of these portions is subjected concurrently and separately to the method, wherein the matrix comprises a gel, and wherein the gel is suitable for measuring the one or more parameters to obtain the desired values.
- multiple equivalent matrices may be formed in multiple containers, such as multiple containers comprising a multi-well apparatus, such that multiple portions of the sample can be evaluated concurrently.
- the present invention includes where a particular tissue can be evaluated at multiple times, with respect to multiple portions of the sample, and with respect to multiple therapies.
- the present invention can be used to measure or obtain data with respect to one or more parameters regarding the behavior of the cells and tissue.
- Those parameters include one or more of the distance which individual cells migrate from the tissue sample, the average distance of migration of a group or population of the cells from the tissue sample, the distance which individual cells migrate from the tissue sample with respect to time, the average distance of migration of a group or population of the cells from the tissue sample with respect to time, the velocity of migration of one or more designated individual the cells per selected time period, the velocity of migration of a group or population of designated the cells per selected time period, the number of migrational cells per unit area of a microscopic visual field, the speed of proliferation of the cells, the speed of unidirectional migration of " the cells, the speed of bi-directional migration of the cells, the speed of tri-directional migration of the cells, the frequency of directional change of the migrating cells, the number of directional changes per unit time of the migrating cells, the rate of mitosis of the migrating cells, the number of cells migrating per unit time, the number of cells in a unit area of a portion of the gel, the change in the number of cells in a unit
- the three- dimensional physiological matrices for use with the invention can be adapted and arranged to have whatever pH value or range necessary to culture and evaluate the specific target tissues and cells.
- the pH range for testing most tissues is from 5.0 to 8.0, and, more preferably, from 7.0 to 7.5.
- the physiological matrix preferably has a pH which is adapted to a range suitable for one or more of a particular tissue, a particular cell type or types, or to a particular tumor.
- a three dimensional matrix of the invention comprises at least one natural or synthetic fiber, for example, one or more fibers selected from the group including type I collagens, type II collagens, type III collagens, type IV c ⁇ llagens, fibrin, fibrinogen, extracellular matrix proteins derived from one or more animals, laminin, fibronectin, a ⁇ ti-laminin, and other natural or synthetic fibers or cables suitable to the formation of a matrix mesh or network capable of supporting cell support, movement and growth.
- one or synthetic fiber selected from the group including type I collagens, type II collagens, type III collagens, type IV c ⁇ llagens, fibrin, fibrinogen, extracellular matrix proteins derived from one or more animals, laminin, fibronectin, a ⁇ ti-laminin, and other natural or synthetic fibers or cables suitable to the formation of a matrix mesh or network capable of supporting cell support, movement and growth.
- a physiological matrix according to the invention preferably comprises a gel, the gel being suitable for measuring at least one or more of the parameters necessary for evaluating the tissue, the cells, possible therapies, and is also adapted and arranged for measuring the efficacy of one or multiple therapeutic compounds.
- a physiological matrix of the invention is adapted and arranged for measuring the efficacy of one or more therapeutic compounds, such as known and unknown single compounds, and known and unknown therapeutic cocktails.
- one or more therapeutic compounds for use or evaluation in the context of the invention may be selected from the group comprising anti-tumor agents, DNA damaging agents such as alkylating agents, antibiotics which affect nucleic acids, platinum compounds, anti-mitotics, cell cycle stimulators, anti -metastatic agents, anti-metabolites, camptothecin derivatives, hormone therapies, biological response modifiers, interferon, anti-invasives, anti- invasion agents, anti-migration agents, anti-angioge ⁇ esis agents, and apoptotic agents, radiosensitizers, radiation, and any known, theoretical or experimental therapeutics directed against cell growth, cell invasion or cell viability, pro-tumor agents, pro- mitotic agents, pro-metastatic agents, pro-invasion agents, pro-migration agents, pro- angiogenesis agents, and anti-apoptotic agents.
- DNA damaging agents such as alkylating agents
- antibiotics which affect nucleic acids
- platinum compounds anti-mitotics
- cell cycle stimulators anti -meta
- the three-dimensional physiological matrices of the invention may be adapted and arranged for measuring the efficacy of one or more therapeutic compounds, such as those selected from the group comprising Temozolomide (TMZ), Irinotecan, Procarbazine, Methotrexate, Carboplatin, Adriamycin Cisplatin, Vincristine, Paclitaxel, l-(2-chloroethyl)-3-cyclohexyl-l-nitrosourea (CCNlJ), carmustine (BCNu), Cyclophosphamide, Docetaxel, fluorouracil (5FU), Cytarabine, doxorubicin,
- TTZ Temozolomide
- Irinotecan Procarbazine
- Methotrexate Carboplatin
- Adriamycin Cisplatin Vincristine
- Paclitaxel l-(2-chloroethyl)-3-cyclohexyl-l-nitrosourea
- BCNu carmus
- a physiological matrix of the invention is adaptable for measuring one or a cocktail of therapeutic compounds comprising one or more, or at least uvo compounds selected from one or more of CAF (Cyclophospha- mide/Adriamycin/ Fluorouracit); CMF (Cyclophosphamide/ Methotrexate Fluorouracil); CMFVP (Cyclophosphamide/ Methotrexate/Fluorouracil/ Vincristine/ Prednisone): PCV (Procarbazine/CCNU/ Vincristine); ICARBO-E (Ifosfamide/ Carboplatin/Etoposide); TAP (Taxol/Adriamycin/ Cisplatin); EMA-CO (Etoposide/ Methotrexate/Actinomycin/ Cyclophosphamide/ Vincristine); VBP (Vinblastine/ Bleomycin/Platinol (Cisplatin)); B
- non-chemical therapies subject to being evauated or tested in the context of the present invention include one or more selected from the group comprising radiation therapies, braehiotherapies, herbal therapies, naturopathic therapies, experimental therapeutic compounds, and new therapeutic compounds.
- the method may further comprise the step of determining the oncological status of the cells of the removed tissue from the data thus obtained.
- the methods may further comprise the step of recording the data in some fixed media so that it can be analyzed, communicated to others, and used as a record of the procedures and their results.
- methods for evaluating the efficacy of one or more therapeutic compounds with respect to one or more tissues comprising cells from an animal are provided.
- Methods of the invention are particularly relevant with respect to tissue and cells which are suspected of being abnormal, cancerous or pre-cancerous.
- the present means and methods are especially adaptable to testing or evaluating one or multiple therapeutic compounds with respect to specific tissue and cells.
- the present methods for evaluating one or multiple therapeutic compounds comprises the steps of A) obtaining a sample of the suspected tissue from the animal, wherein the tissue comprises one or more types of cells, B) implanting a portion of the sample of the suspected tissue at least partially within a three-dimensional physiological matrix, the matrix being adapted and arranged for measuring one or more parameters of the behavior of the tissue and the cells, C) providing sufficient nutrition to the cells and the tissue so that the parameters can be measured, D) providing at least one of the one or more therapeutic compounds to the cells and the tissue, E) incubating or culturing the tissue and the cells with the one or more therapeutic compounds in an environment suitable for the growth of the cells and the tissue, and for a time sufficient to obtain measurements with respect to the one or more parameters, and F) measuring one or more of the parameters to obtain data regarding the behaviors with respect to the one or more therapeutic compounds.
- the methods may further comprise the step of, from the data thus obtained, determining the efficacy of the one or more therapeutic compounds with respect to the tissue and the cells.
- methods of the invention may further comprise the step of recording the data in some fixed form, and may further comprise the step of transmitting the data to at least one cvaluator. Evaluators and the recordatio ⁇ of data obtained by the present means and methods are also discussed herein.
- the invention is also especially adapted for circumstances wherein the sample quantity is divided into portions, and each of the portions is subjected concurrently and separately to the method, wherein the method includes the use of one or more controls adapted for evaluating the one or more therapeutic compounds.
- the present methods can include the use of one or more controls adapted for evaluating the one or more therapeutic compounds with respect to the particular tissue, and with respect to specific conditions created by the test or testing lab or clinic.
- Methods of the invention also include where Step D is performed during Step E, and wherein the measuring of Step F is performed more than once with respect to each of the separate portions of the sample, and wherein the measuring is effected during the culturing or incubating of the tissue and cells.
- the tissue portion is disposed either partially submerged in the matrix, or completely submerged therein.
- the physiological matrix replicates to some extent the three-dimensional environment in which most tissues function in vivo.
- Tissue samples, or portions thereof may be implanted in any method, manner or way, which yields the desired results. Means and methods of the invention can be used also where the implanted tissue is obtained from one or more of a liquid tissue, a ceil suspension, cells or groups of cells which have been palletized, and wherein the tissue or cells are implanted in the matrix after the matrix has formed into a gel or other permeable solid or semi-solid.
- Means and methods of the invention can be used with virtually any animal tissue as described herein. Moreover, it is important to note that matrices of the invention should be essentially free of bicarbonate when the matrix is being formed into the gel, semisolid or permeable solid. As an additional advantage, methods of the invention can be practiced with respect to one or more therapeutic compounds, for example where a single compound is tested and the method is performed with at least one set of controls. As one skill in the art of testing oncological remedies will appreciate, any number of controls, therapeutic substances, therapeutic methods, experimental compounds, or other cancer treatments such as radiation, radiotherapy or any other actual, theoretical or experimental therapy of method can be tested with the present invention in in vitro conditions.
- therapeutic compounds can be provided to the tissues and cells as a component of the sufficient nutrition. More therapeutic compounds are provided to the cells and the tissue as a component of the physiological matrix. As a component after the sufficient nutrition is provided to the cells and tissues or wherein the one or more therapeutic compounds include two compounds and the method is performed with at least one set of controls, ft is similarly possible to use the present invention and methods to test three or more therapeutic compounds preferably with respect to at least one set of controls.
- Methods of physiological matrix is adapted and arranged for measuring the efficacy of one or more therapeutic compounds, and wherein the one or more therapeutic compounds are selected from the group comprising DNA damaging agents such as alkylating agents, antibiotics which affect nucleic acids, platinum compounds, anti-mitotics, cell cycle stimulators, anti-metastatics, anti-metabolites, camptothecin derivatives, hormone therapies, biological response modifiers, interferon, anti-invasives, radiosensitizers, radiation, and any established, theoretical or experimental therapeutics directed against cell growth or cell invasion.
- DNA damaging agents such as alkylating agents, antibiotics which affect nucleic acids, platinum compounds, anti-mitotics, cell cycle stimulators, anti-metastatics, anti-metabolites, camptothecin derivatives, hormone therapies, biological response modifiers, interferon, anti-invasives, radiosensitizers, radiation, and any established, theoretical or experimental therapeutics directed against cell growth or cell invasion.
- a physiological matrix of the invention is adapted and arranged for measuring the efficacy of one or more therapeutic compounds comprises at least two therapeutic compounds. And where at least two therapeutic compounds are selected
- physiological matrices according to the invention should be essentially free of bicarbonate, for example wherein the matrix is formed from components that are essentially free of bicarbonate, and the final gel form of the matrix is thus essentially bicarbonate free.
- one or more parameters can be obtained regarding the behaviors of one or more therapeutic compounds, and the behaviors of the cells themselves.
- Parameters thus measured yield data.
- such data can be used to evaluate the performance of the cells, or the performance of one or more therapeutics, or the performance of one or more other types of therapies with respect to the tissues and cells tested.
- the measuring step E is performed at periodic intervals, and wherein the periodic intervals are appropriate to one or more of the cells, the tissue and the therapy or therapies being tested or evaluated.
- the measuring of Step E is performed at periodic intervals for a period of time of between one hour and 15 days. More preferably, the periodic intervals are one or more selected from the group comprising every six hours, every 12 hours, every 18 hours, every 24 hours, every 36 hours, every 48 hours, every 72 hours and every 96 hours. Moreover other intervals such as every day, every second day and every third day, every fourth day, every fifth, day every sixth day, every seventh day, every eighth day, and every ninth day. Methods of the present invention wherein the measuring of Step E is performed at non-periodic intervals, and wherein the non-periodic intervals are appropriate to one or more of the cells, the tissue and the therapy or therapies being tested or evaluated.
- the data obtained by the measurements of the invention is recorded in a fixed communications media.
- Such fixed media can be any type so long as it is capable of holding the obtained data in such form as to be useable later.
- paper, voice recordings, video recordings, photographs, photomicrographs, digital recordings, any fixed digital data means, any computer network-facilitated means, infrared recording, ultrasound recordings, and magnetic resonance recordings.
- a human observer a still camera, a video camera, an automated still camera, an automated video camera, an infrared camera, and an automated infrared camera.
- the culturing and/or incubating of tissues and cells according to the invention occurs for a period of time sufficient to obtain data regarding the desired parameters and values. For most tissue and cells to be tested, that period of time is between one hour and 15 days. More specifically, the culturing or incubating of the tissue and the cells typically occurs for a period of time of at least 1 hour, or at least 10 hours, or at least 24 hours, or at least 36 hours or at least 72 hours, or at least 125 hours, or at least 175 hours, or at least 200 hours, or at least 250 hours or at least 300 hours.
- the environment for incubating or culturing the cells and the tissue includes a temperature range of from 26 to 43 degrees Celsius, a carbon dioxide tension of from 2.0% to 13.0%, and a humidity range of from 50-100 %.
- the sufficient nutrition comprises one or more fluids, and wherein the one or more fluids are selected from the group comprising tissue culture medias, concentrated tissue culture medias, and any culture or nutritional medias which are suitable for the tissue sample
- the concentrated medias are one or more selected from the group comprising 1OX medias, and any other concentrated medias.
- the sufficient nutrition is provided to the tissues and cells by placing the sufficient nutrition in contact with the matrix after the sample has been placed in the matrix
- the method of the invention further comprises the step of J) providing at least one source of additional nutrition to the tissue and the cells so that the parameters can be measured.
- at least one source of additional nutrition comprises one or more of tissue culture medias, concentrated tissue culture medias, and any culture or nutritional medias which are suitable for the tissue sample and wherein least one additional source of nutrition is supplemented with one or more selected from the group comprising sera, proteins, sugars, salts, lipids.
- the sufficient nutrition is provided to tissues and cells by placing the sufficient nutrition in contact with the matrix after the sample has been placed in the matrix and the matrix has equilibrated to room temperature, wherein the room temperature is in the range of from 10 to 30 degrees Celsius.
- the present invention can be used to obtain data regarding one or multiple parameters of the behaviors of the tissue and cells being evaluated or tested as discussed herein.
- Significant among those parameters are the distance which individual cells migrate from the margins of the tissue sample, the average distance of migration of a group or population of the cells from the margins of the tissue sample, the distance which individual cells migrate from the tissue sample with respect to time, and the number of migrational cells per unit area of a microscopic visual field, that is, cell density in a portion of the gel.
- methods of "the invention may include those for evaluating the efficacy of one or more therapies with respect to at least one tissue from an animal, the tissue comprising cells, and the tissue being suspected of being abnormal, pre-cancerous or cancerous, the method comprising the steps of A) obtaining a sample of the tissue from the animal, wherein the tissue comprises one or more types of cells, B) implanting the sample at least partially within a three-dimensional physiological matrix, the matrix being adapted and arranged for measuring one or more parameters of the behavior of the cells of the tissue or cells, C) providing sufficient nutrition to the cells of the tissue of the portions so that the parameters can be measured, D) subjecting the cells and the tissue to at least one of the one or more therapies, E) incubating or culturing the tissue and the cells of the portions in an environment suitable for the growth of the cells and the tissue for a time sufficient to obtain measurements with respect to the one or more parameters for each of the portions, and with the one or more therapeutic compounds, F) measuring, with respect to each of the
- a three-dimensional physiological matrix suitable for culturing at least one tissue from an animal, the tissue comprising cells, is provided.
- the tissue or cells of the sample are suspected of being abnormal, cancerous or pre-cancerous.
- the physiological matrix comprises A), at least one natural or synthetic fiber means, wherein the fiber means is adapted and arranged such that the cells, if abnormal, cancerous or precancerous, are enabled to grow away from the sample into the matrix when the sample is implanted at least partially in the matrix, B), a sufficient amount of at least one additive comprising sufficient hydroxyl or hydrogen groups to bring the effective pll range of the matrix into an acceptable range, and C), sufficient nutrition to sustain the cells and the tissue in the matrix.
- Tt is important to note that the matrices of the invention and the sufficient nutrition should be essentially free of bicarbonate when they are being formed.
- the three-dimensional physiological matrix is mixed from components and formed into a solid, a semi-solid, or a gel, and the matrix is adapted and arranged to permit migration of the cells away from the margins of the tissue and into the matrix. Moreover, the matrix is formulated, adapted and arranged to accept the sample as soon as the solid or gel is formed, or during its formation.
- a three-dimensional physiological matrices of the invention comprise at least one natural or synthetic fiber, for example, one or more selected from the group comprising type I collagens, type II collagens, type III collagens, type IV collagens, fibrin, fibrinogen, lam in in, anti-laminin, positively charged poly(L-lysine) amino acid chains, positively charged poly(D-lysine) amino acid chains, and extracellular matrix proteins derived from one or more animals.
- the matrix comprises at least 90% Type I collagen.
- the gel comprises at least 95% Type 1 collagen.
- the pH of a three-dimensional physiological matrix of the invention is brought into an acceptable range by means of one or more additives preferably selected from the group comprising NaOH, KOH and other strongly basic compounds.
- a matrix of the invention may further comprise additional nutrition to be added after the formation of the matrix into a solid, semi-solid or gel.
- the sufficient nutrition comprises one or more fluids, preferably selected from the group comprising tissue culture media, concentrated tissue culture media or any culture or nutritional media which are suitable for the tissue sample to be evaluated.
- Suitable concentrated medias include one or more selected from the group comprising 1OX media, and other concentrated media.
- the sufficient nutrition is provided to the tissues and cells by placing the sufficient nutrition in contact with the matrix after the sample has been placed in the matrix and wherein one additional source of nutrition is supplemented with one or more selected from the group comprising sera, proteins, sugars, salts, lipids, and the matrix has equilibrated to room temperature, wherein room temperature is in the range of from 10 to 30 degrees Celsius.
- a three-dimensional physiological matrix for use in the context of the invention can be adapted or arranged to have whatever pH value or pH ranges necessary to culture and evaluate the specific tissues and cells.
- the pH range for testing most tissues is from 5.0 to 8.3, more preferably 6.4 to 7.9 and even more preferably from 7.4 to 7.6.
- the tissue to be evaluated or tested is implanted or disposed completely submerged within the three- dimensional matrix.
- a matrix is preferably adapted and arranged to be in sufficient proximity to at least one additional source of nutrition, wherein the matrix is permeable to the additional source of nutrition to the extent necessary that the sample tissue and cells receive nutrition sufficient to enable them to grow into the matrix to the extent necessary to measure the one or more parameters.
- the at least one additional source of nutrition may preferably include one or more additives or supplements selected from the group comprising serums, proteins, sugars, salts and lipids or any culture media that is suitable for the cell or tissue type.
- the density of the fiber in a formed matrix of the invention is between 1.3 and 3.3 mgs/ml, more preferably from 2.0 to 2.8 mgs/ml, and even more preferably between 2.3 and 2.5 mgs/ml.
- the present invention can be adapted and arranged to be suitable for measuring at least one parameter of the behavior of cells from the tissue, and at least one parameter relating to the suspected cancerous or abnormal status of the cells or the tissue. These parameters are listed hereinbefore.
- a three-dimensional physiological matrix of the invention includes at least one natural or synthetic fiber selected from the group comprising Type I collagen, wherein the Type T collagen comprises at least 70% of the total fiber of the formed matrix, or at least 80% of the total fiber, at least 90% of the total fiber and at least 95% of the total fiber.
- a three-dimensional physiological matrix of the invention comprises at least one natural or synthetic fiber means of primarily Type 1 collagen, and at least one additive sufficient to bring the pH of the matrix into an acceptable range, such as a sufficient amount of 0.1 N NaOH, and wherein the sufficient nutrition is a bicarbonate-free 1OX media.
- a three-dimensional physiological matrix of the invention comprises eight parts by volume of the natural or synthetic fiber, the at least one additive comprises one part by volume of the O.i N NaOH, and the sufficient nutrition comprises one part by volume of the bicarbonate-free 1OX media.
- a physiological matrix according to the invention may comprise at least one first hollow, cavity, slit or chamber, and the first hollow, cavity slit or chamber may be adapted and arranged to receive one or more tissues samples, wherein the one or more tissues samples are in the form of one or more of a solid, a liquid, a suspension, and combinations thereof.
- a three-dimensional matrix of the invention may comprises at least one second hollow cavity, slit or chamber, wherein each of the second hollows, cavities, slits or chambers is adapted and arranged to receive at least a portion of the additional source of nutrition.
- the three-dimensional matrix of the invention matrix comprises a gel, the gel being suitable for measuring at least one of the one or more parameters and of producing resulting data.
- the physiological matrices of the present invention are adapted and arranged for measuring the efficacy of one or a plurality of therapeutic compounds, many of which are exemplified herein.
- means or methods of the invention can be adapted and arranged to test the efficacy of non-synthetic chemical therapies, wherein the non-synthetic chemical therapies are one or more selected from the group comprising radiation therapies, brachiotherapies, herbal therapies, naturopathic therapies, experimental therapeutic compounds, and new therapeutic compounds, hyperthermal therapies, hyperbaric therapies, hypobaric and photosensitizing therapies.
- the non-synthetic chemical therapies are one or more selected from the group comprising radiation therapies, brachiotherapies, herbal therapies, naturopathic therapies, experimental therapeutic compounds, and new therapeutic compounds, hyperthermal therapies, hyperbaric therapies, hypobaric and photosensitizing therapies.
- An additional benefit of the present invention pertains to its amenability to kit form.
- the invention may include a kit for testing the efficacy of therapeutic compounds on an expedited basis, the kit comprising a means for collecting at least one tissue comprising cells from an animal, the tissue being suspected of being abnormal, cancerous or pre-canccrous, at least one three-dimensional physiological matrix for culturing the tissue sample in three dimensions for a sufficient length of time to obtain measurements of at least one parameter of the behavior of the cells and the tissue, a means for measuring the parameters to determine a set of possible therapeutic compounds which might be efficacious for treating the tumor or abnormal tissue, and a means for testing the therapeutic effect of the determined therapeutic compounds.
- the behavior of cells at multiple sites is measured to obtain data regarding the behavior of the tissue or cells.
- readings made using microscopy and video-microscopy include the actions or steps of measuring directly the migratory distance, speed, cell density and direction of movement of the cells or tissue with respect to the matrix, upon which they are placed or cultured.
- the suspect tissue and matrix are then processed and treated so that they can be snap frozen, paraffin embedded, sectioned, and then assessed with respect to one or more parameters, including, but not limited to, mitotic index/cell division, cell growth, necrosis, apoptosis, anoikis, adhesion, cellular signaling and invasion-related protein expression. Any number of protein and genetic parameters can be analyzed with respect to their usefulness in determining the oncologic state of the cells or tissues.
- the matrix may be of any configuration or material which permits the evaluation of the effect of therapeutic compounds on the cells or tissues.
- the matrix preferably comprises a collagen gel, the gel being suitable for measuring the one or more parameters.
- Matrices could include any protein or glycoprotein or sugar components of extracellular matrix, for example, including but not limited to, fibronectin, laminin, hylaronin, growth factors and integrins.
- the typical matrix element of the invention comprises a gel.
- a matrix of the invention comprises protein in its native, non-denatured state, in the amount of 1.0 to 2.1 mg/ml.
- One preferred protein is, for example, Type I Collagen.
- Other proteins are amenable to use or adaptation as components of matrices of the invention.
- a matrix of the invention possesses a final pH preferably in the range of from 6.0 to 8.5, more preferably in the range of from 6.5 to 8.0, and most preferably in the pH range of from 6.8 to 7.5
- a matrix of the invention is incubated and used in an air atmosphere having carbon dioxide preferably in the range of 1.0 to 18.0%, more preferably in the range of from 2.0 to 14.0%, and most preferably in the range of from 4.0 to 9.0%.
- a carbon dioxide incubator is useful for incubation processes according to the invention.
- the parameters of matrix composition, carbon dioxide tension, and other conditions vary according to tumor type. For example, for most categories of tumors, temperatures for incubation of the matrices combined with tissue or cells are generally kept within approximate physiological ranges, preferably of from 30 - 44 degrees Celsius, more preferably of from 33 - 41 degrees Celsius, and most preferably of from 35 - 39 degrees Celsius.
- a matrix may comprise one or more constituents provided to adapt the matrix for use with a particular tumor, or a particular class of tumors.
- Possible constituents to a matrix according to the invention may include growth factors such as VEGF or HGF, which tends to alter the invasion patterns of the tissue cells into the matrix and enhances cell growth.
- growth factors such as VEGF or HGF
- Other possible constituents include structural proteins, for instance, extracellular matrix proteins like laminin, fibronectin, and the various collagens, for example Collagen IV.
- Immunoglobulins may also be included or added to a matrix of the invention in order to stabilize it in various respects.
- anti-laminin may be included in the matrix.
- lipids such as human or bovine brain extract, solids like human dura, and plant extracts such as phytostimulants and inhibitors may also be included in a matrix of the invention in order to vary its characteristics and adapt it to specitlc use.
- other living cells may be included. Exemplary cells include melanoma cells, fibroblasts and endothelial cells
- Matrices of the invention may include inert additives also.
- glass or plastic shapes, such as cylinders may be provided within tissue culture wells to act as structural forms for the gel so that the matrix gel can be molded to create a tiny well or indentation useful for adding cell suspensions such as leukemia or lymphoma cells to the matrix in a pre-determined area in the matrix gels.
- the one or more parameters to be measured comprise one or more of: the speed of proliferation of the cells, the speed of unidirectional migration of the cells, the speed of bi-directional migration of the cells, the speed of tri-directional migration of the cells, the rate of mitosis of the cells, the rate of change of migrational direction of the cells, the proportion of cells which change migrational direction during the test period, the speed of migrating cells in a particular visual field, the density of migrating cells per microscopic visual field, the migrational distance of individual migrating cells per microscopic visual field, the average migration-al distance of a group or population of migrating cells per microscopic visual field, and the number of migrating cells per microscopic visual field direction.
- the "Test Period” is that period of time during which the one or more tissues or cells are cultured and tested with respect to their oncological behaviors
- the “Evaluational Period” is that period of time during which the one or more therapeutic compounds are evaluated with respect to efficacy in treating the specific tissue samples or cells, and other parameters.
- the one or more therapeutic compounds or treatments are selected from the group comprising, but not limited to, DNA damaging agents, anti-mitotics, cell cycle stimulators, anti-metastatics, anti-invasives, radiosensitizers, radiation, and any established, theoretical or experimental therapeutics against cell growth and cell invasion.
- Methods of the invention include the evaluation of one or more therapeutic compounds, individually, combined with one another, as one or more cocktails, or in any sequence, in order to determine their likely efficacy against the suspected tumor tissue and cells.
- the methods of the invention include testing one therapeutic compound, or a pair of therapeutic compounds, or three therapeutic compounds, or four therapeutic compounds, or more than four therapeutic compounds, or any number of compounds in a cocktail of compounds, or provided at different times or sequences to the tissue being evaluated.
- the culturing of the tissue and the cells during the test and evaluational periods is for a length of time sufficient to obtain the values required to make a determination of the efficaciousness of one or more potential therapeutic compounds.
- the culturing of the tissue and the cells occurs for a period sufficiently long enough to obtain the needed data.
- the culturing of the tissue and the cells occurs during the one or more test and evaluational periods, and thus during a period of time of preferably less than 10 days, more preferably of less than 8 days, even more preferably of less than 6 days, and most preferably of less than 4 days.
- all readings typically occur within 10 days from the time of removal of the tissue or cells from the mammal.
- Basic microscopic readings of distance, direction and density are taken manually or by automated systems, preferably at predetermined intervals depending on the nature of the suspected tumor, the nature and amount of the tissue and the nature and number of cells or cell types being evaluated.
- the predetermined interval is one or more hours, for example, every 4 hours, or every 8 hours or every 16 hours or every 24 hours.
- Video monitoring of the tissues and cells may also be provided in order to gather and record additional information.
- the video monitoring is preferably provided on a continuous basis at intervals. The intervals are selected based upon the nature of the tissue and cells, the nature of the suspected tumor or tumors, and the estimation of likely behavior of the tissue and cells on a matrix. Tn some preferred embodiments of the invention, video monitoring is provided on a continuous basis, at 30-second intervals, or at 60-second intervals or at 90-second intervals or at 120-second intervals, or at 150-second intervals.
- Methods of the present invention include also those of testing the efficacy of therapeutic compounds on an expedited basis, testing the efficacy of therapeutic compounds with respect to a specific individual mammal, such as a human, and testing the synergistic efficacy of two or more therapeutic compounds on an expedited basis.
- the present invention includes also one or more kits for testing the synergistic efficacy of therapeutic compounds on an expedited basis, the kit comprising i) means for collecting at least one tissue comprising cells from a mammal, the tissue being suspected of being transformed into cancerous or pre-cancerous tissue, ii) means for culturing the tissue comprising cells for a sufficient length of time to obtain desired values, iii) means for evaluating the values to determine a set of possible therapeutic compounds which might be efficacious for treating the tumor, and iv) means for testing the therapeutic effect of the determined therapeutic compounds.
- FIGURES 1 -8 are photographic and photomicrographic images which show, by way of example, use of the means and methods of the present invention with respect to a tissue sample removed from a patient.
- Patient Sample GS-640 comprising kidney tissue, was removed from the patient by a surgeon during surgery.
- Tissue analysis and screening in accordance with the invention were requested by the surgeon, and proper consent was obtained from the patient prior to surgical removal of a sample quantity of tissue from the RHS Kidney.
- the patient was diagnosed with renal cell carcinoma.
- a tissue sample of approximately 1 gram in quantity was removed from the patient during surgery, and was placed into a 25 ml sample jar, and immersed in sterile saline.
- the tumor tissue was kept at 4 degrees centigrade until processed for the screening of therapeutic compounds in accordance with the means and methods of the invention. All procedures were performed under sterile conditions in a bio-safety laminar flow hood.
- FIG 1 is a photographic image showing the mechanical division of the sample into portions to be tested.
- the sample has been prepared by dissecting away any non viable tissue and blood prior to mincing into 1-2 mm pieces using sterile disposable scalpels.
- FIG. 2 is a photographic image showing tumor sample portions which have been placed into each well of a 48 well plate, and been submersed in a gel matrix mixture according to the invention. After insertion of the portions, the mixture was allowed to form into a gel at room temperature for approximately 30 minutes. Once the gel formed around the fully immersed tumor fragments, nutrient rich media was added as a liquid overlay that permeated the entire gel and tumor fragment.
- FIG. 3 is a photomicrograph ic image which shows the tumor sample at
- FiG 4 Figure 4 is a photomicrographic image which showing a patient control sample (no treatment) after 3 days incubation @ 37 0 C and 5% CO 2 . Noteworthy is the migration of cells away from the solid tumor mass in a halo around the tumour fragment.
- FlG 5 Figure 5 is a photomicrographic image which shows a patient control sample after 5 days. Noteworthy is the halo of cells and increased cell density as compared with the results shown at Day 3 of the test. The lines on the images have been drawn to show the distance measurements within which approximately 95% of the migrating cells have migrated away from the margins of the tissue sample.
- FIG. 5 also shows the presence of fibroblasts which sometimes appear at the later time points.
- Fibroblasts are noticeably different in numbers and appearance than migrating tumor cells. For example, fibroblasts appear in the surrounding gel matrix as much larger cells than the migrating tumor cells, and with significantly larger cytoplasm, as well as the classic elongated spindle fibroblast appearance. Fibroblasts also stain positively upon immuno-histochemical analysis for antibodies to fibroblast markers such as fibroblast growth factor. Thus, fibroblasts may be differentiated from tumor cells in a straightforward manner.
- FIG 6 Figure 6 is a photomicrographic image demonstrating the effect of treatment with TaxolTM.
- the image of Figure 6 shows a sample well at 5 days after treatment with TaxolTM .
- Noteworthy is the change in behavior of the cells exposed to TaxolTM. Specifically, a drop in both the distance and the number of cells that have grown and invaded away from the solid tumor fragment is seen on the lower left hand side of the image.
- FIG 7 is a photomicrographic image which demonstrates the effect of treatment with DocetaxolTM.
- the image of Figure 7 shows a sample well wherein the tumor tissue has been treated for 5 days with DocetaxolTM while showing a moderate response to the drug. This moderate response is evidenced by the fewer number of invading cells than the control but those treated with DocetaxolTM have a longer migratory distance than treatment with TaxolTM.
- FIG 8 is a photomicrographic image which shows the carcinoma patient sample treated for 5 Days with CisplatinTM. This image thus shows an example of a failed chemotherapy, being identical in appearance and cell numbers to the control sample (figure 5) at the same 5 day time point.
- the present invention is adaptable to be used with many possible therapeutic substances, and combinations thereof, including those shown in the accompanying Table Of Exemplary Therapeutic Compounds.
- the attached Table provides only an exemplary list of therapeutic compounds which may be evaluated with the present methods and means. Virtually any other compound or combination of compounds with potential therapeutic value may be tested and evaluated with the present invention.
- the means and methods of the present invention are adaptable and useful for testing any compound or combination of compounds with respect to their potential therapeutic value, regardless of whether those compounds have been involved in the drug approval process.
- the present invention provides means and methods for initially testing and evaluating compounds with respect to possible efficacy against many tumors and tumor types without the necessity of using animal or human subjects.
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Abstract
L'invention concerne des matrices physiologiques tridimensionnelles, des procédés, un appareil et des kits pour la l'élaboration, le test et l'évaluation rapide de médications oncologiques. Les matrices constituent l'aspect clé de l'invention, notamment les matrices en gel, incluant une ou plusieurs fibres physiologiques, adaptées et agencées pour fournir des conditions permettant d'évaluer des comportements, tels que le l'éloignement de cellules des marges des échantillons de tissu cible à travers la matrice, et d'obtenir des données utiles pour l'évaluation de l'état oncologique et des caractéristiques des cellules. Dans un autre aspect clé, l'invention permet de tester in vitro et d'analyser une ou plusieurs thérapies classiques, expérimentales ou théoriques sur des tissus ou des cellules cibles spécifiques. De telles thérapies incluent des composés thérapeutiques et des combinaisons de ceux-ci, des thérapies par rayonnement, des combinaisons de composés thérapeutiques et par rayonnement ainsi que de nombreuses autres applications possibles.
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CA2698338A CA2698338C (fr) | 2007-06-13 | 2007-06-15 | Matrices physiologiques tridimensionnelles pour test oncologique et procedes pour leur production et leur utilisation |
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US-- | 2004-11-11 | ||
US60/813,686 | 2006-06-15 | ||
US92912207P | 2007-06-13 | 2007-06-13 | |
US60/929,122 | 2007-06-13 |
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WO2008015581A2 true WO2008015581A2 (fr) | 2008-02-07 |
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PCT/IB2007/003494 WO2008012696A2 (fr) | 2006-06-15 | 2007-06-15 | Procédés et trousses pour tester l'efficacité de composés thérapeutiques et d'autres thérapies destinés à des cellules et des tissus tumoraux dans une matrice tridimensionnelle |
PCT/IB2007/003697 WO2008020337A2 (fr) | 2006-06-15 | 2007-06-15 | Procédés et kits destinés à évaluer et à mesurer le statut oncologique de prélèvements de tissus dans des matrices physiologiques en trois dimensions |
PCT/IB2007/003503 WO2008015581A2 (fr) | 2006-06-15 | 2007-06-15 | Matrices physiologiques tridimensionnelles pour test oncologique et procédés pour leur production et leur utilisation |
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PCT/IB2007/003494 WO2008012696A2 (fr) | 2006-06-15 | 2007-06-15 | Procédés et trousses pour tester l'efficacité de composés thérapeutiques et d'autres thérapies destinés à des cellules et des tissus tumoraux dans une matrice tridimensionnelle |
PCT/IB2007/003697 WO2008020337A2 (fr) | 2006-06-15 | 2007-06-15 | Procédés et kits destinés à évaluer et à mesurer le statut oncologique de prélèvements de tissus dans des matrices physiologiques en trois dimensions |
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CA (2) | CA2698338C (fr) |
WO (3) | WO2008012696A2 (fr) |
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Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO1990002796A1 (fr) * | 1988-09-08 | 1990-03-22 | Marrow-Tech Incorporated | Systeme tridimensionnel de culture cellulaire et tissulaire |
US5712161A (en) * | 1993-12-30 | 1998-01-27 | Nitta Gelatin Inc. | Method for culturing animal cells in collagen drops on a support |
-
2007
- 2007-06-15 WO PCT/IB2007/003494 patent/WO2008012696A2/fr active Application Filing
- 2007-06-15 CA CA2698338A patent/CA2698338C/fr not_active Expired - Fee Related
- 2007-06-15 WO PCT/IB2007/003697 patent/WO2008020337A2/fr active Application Filing
- 2007-06-15 WO PCT/IB2007/003503 patent/WO2008015581A2/fr active Application Filing
- 2007-06-15 CA CA2691044A patent/CA2691044C/fr active Active
Patent Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO1990002796A1 (fr) * | 1988-09-08 | 1990-03-22 | Marrow-Tech Incorporated | Systeme tridimensionnel de culture cellulaire et tissulaire |
US5712161A (en) * | 1993-12-30 | 1998-01-27 | Nitta Gelatin Inc. | Method for culturing animal cells in collagen drops on a support |
Non-Patent Citations (4)
Title |
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COSTELLO, P ET AL.: 'Screening for tumor therapy sensitivity using an ex vivo invasion assay.' NEURO. ONCOL. vol. 8, October 2006, page 440 * |
COSTELLO, PC ET AL.: 'Determination ofhuman brain tumour therapy response using an ex vivo invasion assay provides a potential step toward individualized treatment.' J. CLIN. ONCOL. vol. 24, no. 18S, 20 June 2006, page ABSTR.11509 * |
KOSHIDA K. ET AL.: 'ln vitro chemosensitivity test for human genitourinary tumors using collagen gel metrix.' INT. J. UROL. vol. 12, January 2005, ISSN 0919-8172 pages 67 - 72 * |
TAKAMURA Y. ET AL.: 'Prediction of chemotherapeutic response by collagen gel droplet embedded culture-drug sensitivity test in human breast cancers.' INT. J. CANCER. vol. 98, 20 March 2002, ISSN 0020-7136 pages 450 - 455 * |
Also Published As
Publication number | Publication date |
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CA2698338C (fr) | 2015-11-24 |
WO2008015581A3 (fr) | 2011-02-24 |
CA2691044C (fr) | 2016-09-27 |
CA2691044A1 (fr) | 2008-01-31 |
WO2008012696A2 (fr) | 2008-01-31 |
WO2008012696A3 (fr) | 2011-03-17 |
CA2698338A1 (fr) | 2008-02-07 |
WO2008020337A2 (fr) | 2008-02-21 |
WO2008020337A3 (fr) | 2011-03-17 |
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