Production from blood of cells of neural lineage

BACKGROUND OF THE INVENTION

Since the discovery of stem cells, it has been understood that they have significant potential to effectively treat many diseases [1]. Pluripotent embryonic stem cells derived from embryos and fetal tissue have the potential to produce more than 200 different known cell types, and thus can potentially replace dying or damaged cells of any specific tissue [2,3]. Stem cells differ from other types of cells in the body, and, regardless of their source, are capable of dividing and renewing themselves for long periods. In addition, stem cells can give rise to specialized cell types.

Stem cells have been identified in most organs and tissues, and can be found in adult animals and humans. Committed adult stem cells (also referred as somatic stem cells) were identified long ago in bone marrow (BM). Adult stem cells were traditionally thought as having limited self-renewal and differentiation capabilities, restricted to their tissue of origin [1, 4, 5, 6, 7]. These limits are now being challenged by an overwhelming amount of research demonstrating both stem cell plasticity (the ability to differentiate into mature cell types different from their tissue of origin) and therapeutic potential [8, 9, 10, 11, 12, 13]. For example, recent reports support the view that cells derived from hematopoietic stem cells (HSCs) can differentiate into cells native to the adult brain [1,2], providing additional evidence for the plasticity of such stem cells.

The HSC is the best characterized stem cell. This cell, which originates in bone marrow, peripheral blood, cord blood, the fetal liver, and the yolk sac, generates blood cells and gives rise to multiple hematopoietic lineages. As early as 1998 researchers reported that pluripotent stem cells from bone marrow can, under certain conditions, develop into several cell types different from known hematopoietic cells [14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25]. Such an ability to change lineage is referred to as cellular transdifferentiation or cell plasticity.

To date, the general incapacity of the central nervous system (CNS) to regenerate substantially has limited the success of neuroscientists to develop therapies for many traumatic, degenerative, inflammatory, and even severe infectious disorders of the brain. However, the possibility of the eventual use of stem cells in CNS treatments has raised hopes for CNS cell based therapy.

Bone marrow-derived stem cells (BMSCs) have already been shown to have the ability to differentiate into neurons, and other cell types such as adipocytes, chondrocytes, osteocytes, hepatocytes, endothelial cells, and skeletal muscle cells, [26, 27, 28, 29, 30].

The process of stem cell differentiation is controlled by internal signals, which are activated by genes within the cell, and by external signals for cell differentiation that include chemicals secreted by other cells, physical contact with neighboring cells, and certain molecules in the microenvironment [31, 32].

Successful attempts have been made in vitro and in vivo to induce differentiation of adult stem cells into other cells. Several groups have recently found that in vivo BM cells can give rise to astrocytes and oligodendrocytes (both cell types originate from the neuroectoderm) in the murine brain [33, 34, 35]. Indeed even neurons have been found to express markers of the transplanted bone marrow in chimeric mice [35, 36, 37, 38]. In the cerebellum, fully developed Purkinje cells expressing GFP have been reported after transplantation of GFP-marked BM stem cells [38, 39].

Tissue injury may be one of the stimulants for the recruitment of stem cells to an injured site, by causing changes in the tissue environment, thereby drawing stem cells from peripheral blood, as well as triggering tissue replacement by locally-resident stem cells. Reports of elevated levels of chemokines and chemokine receptors such as CXCR4-SDF may explain some of this in vivo stem cell recruitment [40]. Engraftment of bone marrow-derived microglial and astroglial cells is significantly enhanced after CNS injury [41, 42].

Regenerative medicine in general and especially regeneration of CNS damaged tissue is an emerging scientific field with implications for both basic and practical research. Stem and progenitor cells are applied in a form of cellular therapy for local tissue repair and regeneration [43, 44].

The apparent plasticity of BM stem cells has raised hopes for their use in cell-based repair strategies within the CNS. In mouse models of neurological disorders, the transplantation of mesenchymal stem cells (MSC) has resulted in improvement in several studies:

1. Intravenous, intracarotid and intracerebral administration of MSCs after cerebral ischemia improved behavioral recovery in mice and rats [45, 46, 47, 48]. Furthermore, bone marrow-derived cells also contributed to neovascularization after cerebral ischemia in mice [49, 50];

2. In the MPTP (methyl-phenyl-tetrahydropyridine) mouse model of Parkinson's disease, intrastriatal transplantation of MSCs has promoted functional recovery [51];

3. Rats injected with MSCs after spinal contusion and traumatic brain injury showed long-term improvement of locomotor function [52, 53];

4. MSCs were found to remyelinate the rat spinal cord after focal demyelination, and to improve conduction velocity [54].

The following references, which are incorporated herein by reference, may be of interest:

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SUMMARY OF THE INVENTION

In the context of the present patent application and in the claims, a “core cell population” (CCP) is a population of at least 5 million cells which have a density of less than 1.072 g/ml, and at least 1.5% of which are CD34+CD45−/dim. (That is, at least 75,000 of the cells are both (a) CD34 positive and (b) CD45 negative or CD45 dim.)

For some applications, at least 2% of the 5 million cells are CD34+CD45−/dim. (That is, at least 100,000 of the cells are both (a) CD34 positive and (b) CD45 negative or CD45 dim.)

In accordance with an embodiment of the present invention, a method for producing a neural progenitor/precursor cell population (NPCP) is provided, comprising (a) processing cells extracted from a mammalian cell donor to yield a CCP, and (b) stimulating the CCP to differentiate into the neural progenitor/precursor cell population. In the context of the present patent application and in the claims, “progenitor/precursor” cells are partially differentiated cells that are able to divide and give rise to differentiated cells.

While for some applications described herein the density of the cells in the CCP is less than 1.072 g/ml (as described), for some applications, the CCP has at least 5 million cells having a density of less than 1.062 g/ml.

In the context of the present patent application and in the claims, an “elemental cell population” (ECP) is a population of at least 5 million cells which have a density of less than 1.072 g/ml, at least 1.5% of which are CD34+CD45−/dim, and at least 30% of which are CD14+.

Typically, but not necessarily, at least 30% or 40% of the cells in the ECP are CD14+. Alternatively or additionally, at least 40%, 50%, 60%, or 70% of the cells are CD31+.

Typically, but not necessarily, at least 2% of the cells in the ECP are CD34+CD45−/dim. For some applications, the ECP has at least 5 million cells having a density of less than 1.062 g/ml. It is typically but not necessarily the case that a CCP is also an ECP. It is noted that although for simplicity embodiments of the present invention are described herein with respect to procedures relating to a CCP, the scope of the present invention includes, in each instance, performing the same procedure in relation to an ECP.

For some applications, the CCP-derived progenitor cells are used as a therapeutic cell product (e.g., for cancer therapy, for tissue regeneration, for tissue engineering, and/or for tissue replacement), as a research tool (e.g., for research of signal transduction, or for screening of growth factors), and/or as a diagnostic tool and/or for gene therapy. When the CCP-derived progenitor cells and/or when CCP-derived partially-differentiated cells are used as a therapeutic cell product, they are typically administered to a patient, in whom the progenitor cells mature into the desired cell types themselves (e.g., neurons, astrocytes, glial cells, oligodendrocytes, photoreceptors, etc.). Alternatively, CCP-derived fully-differentiated cells are used as a therapeutic cell product, and are typically administered to a patient, in whom they can regenerate damaged tissue structure and/or function.

In an embodiment, a result of a stage in a process described herein is used as a diagnostic indicator. For example, pathology of a patient may be indicated if an in vitro procedure performed on extracted blood of the patient does not produce a CCP, when the same procedure would produce a CCP from cells extracted from a healthy volunteer. Alternatively or additionally, a pathology of a patient may be indicated if an in vitro stimulation procedure performed on an autologous CCP does not produce a desired number of a particular class of progenitor cells, when the same procedure would produce the desired number of a particular class of progenitor cells from a CCP derived from cells of a healthy volunteer.

When hematopoietic stem cells are used as source cells to create the CCP, the resultant CCP is typically, but not necessarily, characterized in that at least 30% or 40% of the cells in the CCP are CD14+, at least 40%, 50%, 60%, or 70% of the cells in the CCP are CD31+, and/or at least 2.2% or at least 2.5% of the cells are CD34+CD45−/dim.

Typically, but not necessarily, the process of stimulating the CCP takes between about 3 and about 15 days, or between about 15 and about 60 days. Alternatively, stimulating the CCP takes less than 3 days, or more than 60 days.

The mammalian cell donor may be human or non-human, as appropriate. For some applications, the mammalian cell donor ultimately receives an administration of a product derived from the CCP, while for other applications, the mammalian cell donor does not receive such a product. Stem cells that can be used to produce the CCP may be derived, for example, from one or more of the following source tissues: umbilical cord blood or tissue, neonatal tissue, adult tissue, fat tissue, nervous tissue, bone marrow, mobilized blood, peripheral blood, peripheral blood mononuclear cells, skin cells, and other stem-cell-containing tissue. It is noted that the stem cells may typically be obtained from fresh samples of these sources or from frozen and then thawed cells from these source tissues.

The CCP is typically prepared by generating or obtaining a single cell suspension from one of these source tissues. For example, mobilized blood mononuclear cells may be extracted using a 1.077 g/ml density gradient (e.g., a Ficoll™ gradient, including copolymers of sucrose and epichlorohydrin). (It is noted that such a gradient is not used for all applications, e.g., for applications in which a single cell suspension is generated from a non-hematopoietic source such as olfactory bulb, mucosal or skin cells.) The output of this gradient is then typically passed through a second gradient (e.g., a Percoll™ gradient, including polyvinylpyrrolidone-coated silica colloids), suitable for selecting cells having a density less than 1.072 g/ml or less than 1.062 g/ml. These selected cells are then typically increased in number, in vitro, until they become a CCP. As appropriate, other density gradients may be used, in addition to or instead of those cited above. For example, an OptiPrep™ gradient, including an aqueous solution of Iodixanol, and/or a Nycodenz™ gradient may also be used.

The CCP is typically stimulated to generate neural progenitor cells of one or more of the following cell classes:

CNS neurons;

oligodendrocytes;

astrocytes;

peripheral nervous system (PNS) neurons; and

retinal cells (including, but not limited to photoreceptors, pigment epithelium cells, or retinal ganglion cells).

For some applications, the CCP is transfected with a gene prior to the stimulation of the CCP, whereupon the CCP differentiates into a population of desired progenitor cells containing the transfected gene. Typically, these progenitor cells are then administered to a patient. Alternatively or additionally, a gene is transfected into the neural progenitor/precursor cell population for use for gene therapy.

To stimulate the CCP to differentiate into a desired class of progenitor cells, or in association with stimulation of the CCP to differentiate into a desired class of progenitor cells, the CCP is typically directly or indirectly co-cultured with “target tissue” from an organ representing a desired final state of the progenitor cells. For example, the target tissue may include brain or similar tissue when it is desired for the progenitor cells to differentiate into brain tissue. Other examples include:

(a) co-culturing the CCP with peripheral nerves (and/or culturing the CCP in conditioned medium derived therefrom), to induce differentiation of the CCP into peripheral neurons;

(b) co-culturing the CCP with central nervous system (CNS) nerves (and/or culturing the CCP in conditioned medium derived therefrom), to induce differentiation of the CCP into CNS neurons;

(c) co-culturing the CCP with retinal tissue (and/or culturing the CCP in conditioned medium derived therefrom), to induce differentiation of the CCP into retinal tissue. The retinal tissue may include, for example, one or more of: pigment epithelium, or photoreceptors. As appropriate, the retinal tissue may comprise fetal retinal tissue, embryonic retinal tissue, or mature retinal tissue.

Although in some embodiments, co-culturing is performed with sample tissues that are target tissues, as described above, in other embodiments, the CCP is directly or indirectly co-cultured with a sample tissue that does not itself represent a desired final state of the progenitor cells.

For some applications, slices or a homogenate of the target tissue are used for co-culturing, although other techniques for preparing the target tissue will be apparent to a person of ordinary skill in the art who has read the disclosure of the present patent application.

The target tissue may be in essentially direct contact with the CCP, or separated therefrom by a semi-permeable membrane. As appropriate, the target tissue may be autologous, syngeneic, allogeneic, or xenogeneic with respect to the source tissue from which the CCP was produced. Alternatively or additionally, the CCP is cultured in a conditioned medium made using target tissue (e.g., a target tissue described hereinabove), that is autologous, syngeneic, allogeneic, or xenogeneic with respect to the source tissue from which the CCP was produced. For some applications, the target tissue and the CCP are cultured together in the conditioned medium. It is noted that the source of the target tissue may also be tissue from a cadaver, and/or may be lyophilized, fresh, or frozen.

Alternatively or additionally, for some applications, to produce a desired class of progenitor cells, cells from the CCP are cultured in the presence of stimulation caused by “stimulation factors,” e.g., one or more antibodies, cytokines and/or growth factors such as: anti-CD34, anti-CD133, anti-CD117, LIF, EPO, IGF, b-FGF, M-CSF, GM-CSF, TGF alpha, TGF beta, VEGF, BHA, B27, F12, BDNF, GDNF, NGF, NT3, NT4/5, S-100, CNTF, EGF, NGF3, CFN, ADMIF, estrogen, prolactin, an adrenocorticoid, glutamate, serotonin, acetylcholine, NO, retinoic acid (RA), heparin, insulin, forskolin, and/or cortisone, and/or a derivative of one of these. It is to be appreciated that the particular stimulation factors described herein are by way of illustration and not limitation, and the scope of the present invention includes the use of other stimulation factors. As appropriate, these may be utilized in a concentration of between about 100 pg/ml and about 100 μg/ml (or molar equivalents). In some cases, medium additives are added at volume ratios of about 1:1 to about 1:30, or about 1:30 to about 1:500 from the total volume of the medium. Typically, particular stimulation factors are selected in accordance with the particular class of progenitor cells desired (e.g., to induce neural progenitor cells, one or more of the following stimulation factors or media additives are used: BHA, BDNF, NGF, NT3, NT4/5, EGF, NGF3, S-100, CNTF, GDNF, CFN, ADMIF, B27, F12 and acetylcholine).

For some applications, the stimulation factors are introduced to the CCP in a soluble form, and/or in an aggregated form, and/or attached to a surface of a culture dish. In an embodiment, the CCP is incubated on a surface comprising a growth-enhancing molecule other than collagen or fibronectin. The growth-enhancing molecule may comprise, for example, BDNF or another suitable antibody or factor described herein. As appropriate, the growth-enhancing molecule may be mixed with collagen or fibronectin, or may be coated on the surface in a layer separate from a layer on the surface that comprises collagen or fibronectin. Alternatively, the only growth-enhancing molecule(s) on the surface is collagen and/or fibronectin and/or autologous plasma.

Following stimulation of the CCP, the resultant product is typically tested to verify that it has differentiated into a desired form. For example, when neural progenitor cells are the desired product, the product typically comprises one or more of: CD34, CD117, CD44, Neu-N, nestin, microtubule associated protein-1 (MAP-1), MAP Tau, microtubule associated protein-2 (MAP-2), neurofilament NF200, neuron-specific enolase (NSE), choline acetyltransferase (CHAT) neuronal class III β-Tubulin, glutamic acid decarboxylase (GAD), glutamic acid, gamma-aminobutyric acid (GABA), oligodendrocyte marker (O4), myelin basic protein (MBP), galactocerebroside (GalC), glial fibrillary acidic protein (GFAP), CD211b, dopamine, norepinephrine, epinephrine, glycine, glutamate, acetylcholine, serotonin, and endorphin. The supernatant may also include one or more of the above, or neurotrophins, such as S-100, GDNF, CNTF, BDNF, NGF, NT3, NT4/5, which may be secreted by the NPCP.

Typically, greater than 1.5% of the cell population demonstrates one or more of these molecules. Alternatively or additionally, neural progenitor cells are typically positive for one or more of: Nestin, NSE, Notch, numb, Musashi-1, presenilin, FGFR4, Fz9, SOX 2, GD2, rhodopsin, recoverin, calretinin, PAX6, RX and Chx10.

For some applications, an effort is made to minimize the time elapsed from collection of cells from the cell donor until the CCP-derived progenitor cells are used (e.g., for administration into a patient). Alternatively, cells are preserved at one or more points in the process. For example, the CCP may be frozen prior to the stimulation thereof that generates progenitor cells. In another example, the CCP are stimulated in order to generate desired progenitor cells, and these progenitor cells are frozen. In either of these cases, the frozen cells may be stored and/or transported, for subsequent thawing and use.

By way of illustration and not limitation, it is noted that certain applications are suitable for large-scale commercialization, including freezing and transport, such as (a) generation of stores of CCPs, (b) generation of stores of NPCPs, and (c) stem cell banks where individuals may store a CCP or differentiated NPCP cells, for possible later use. “Transport,” in this context, means transport to a remote site, e.g., a site greater than 10 km or 100 km away from a site where the CCP is first created.

For some applications, the CCP is cultured for a period lasting between about 1 and about 60 days in a culture medium without serum (serum free) or in a culture medium comprising less than about 5% serum. Alternatively, the CCP is cultured for a period lasting between about 1 and about 60 days in a culture medium comprising greater than about 10% serum. In an embodiment, one of these periods follows the other of these periods.

For some applications, the CCP is cultured, in serum-free or low-serum conditions for a certain period, in a culture medium comprising less than about 10% serum (e.g., less than 1% or 0.01% serum, or being serum free), and, in high-serum conditions for another period, in a culture medium comprising greater than or equal to about 10% serum. In an embodiment, culturing the CCP during the serum-free or low-serum period comprises culturing the CCP for a duration of between about 1 and about 60 days. Alternatively or additionally, culturing the CCP during the high-serum time period comprises culturing the CCP for a duration of between about 1 and about 60 days. Typically, culturing the CCP during the serum-free or low-serum period is performed prior to culturing the CCP during the high-serum time period. Alternatively, culturing the CCP during the low-serum time period is performed following culturing the CCP during the high-serum time period.

For some applications, the CCP is cultured in the presence of one or more proliferation-differentiation-enhancing agents, such as anti-CD34, anti-CD133, anti-CD 117, LIF, EPO, IGF, b-FGF, M-CSF, GM-CSF, TGF alpha, TGF beta, VEGF, BHA, B27, F12, BDNF, NGF, NT3, NT4/5, S-100, CNTF, GDNF, EGF, NGF3, CFN, ADMIF, estrogen, prolactin, an adrenocorticoid, glutamate, serotonin, acetylcholine, NO, retinoic acid (RA), heparin, insulin, forskolin, and/or cortisone, and/or a derivative of any of these.

In an embodiment, techniques described herein are practiced in combination with (a) techniques described in one or more of the references cited herein, (b) techniques described in U.S. Provisional Patent Application 60/576,266, filed Jun. 1, 2004, and/or (c) techniques described in U.S. Provisional Patent Application 60/588,520, filed Jul. 15, 2004, and/or (d) techniques described in U.S. Provisional Patent Application 60/636,391, filed Dec. 14, 2004. Each of these provisional patent applications is assigned to the assignee of the present patent application and is incorporated herein by reference. The scope of the present invention includes embodiments described in these provisional patent applications.

In an embodiment, a method is provided comprising culturing the CCP in a first container during a first portion of a culturing period; removing at least some cells of the CCP from the first container at the end of the first portion of the period; and culturing, in a second container during a second portion of the period, the cells removed from the first container. For example, removing at least some of the CCP cells may comprise selecting for removal cells that adhere to a surface of the first container.

If cells from a progenitor/precursor cell population derived from a CCP are to be transplanted into a human, they should be generally free from any bacterial or viral contamination. In addition, in the case of a NPCP the following conditions should typically be met:

(I) Cells should be morphologically characterized as (a) larger in size than lymphocytes, and/or (b) having irregular perikarya, from which filamentous or tubular extensions spread, contacting neighboring cells and forming net-like organizations, and/or (c) granulated or dark nucleated.

(II) Final cell suspension should generally contain at least 1 million cells expressing one or more of the following: CD34, CD117, CD44, Neu-N, nestin, microtubule associated protein-1 (MAP-1), MAP Tau, microtubule associated protein-2 (MAP-2), neurofilament NF200, neuron-specific enolase (NSE), choline acetyltransferase (CHAT) neuronal class III β-Tubulin, glutamic acid decarboxylase (GAD), glutamic acid, gamma-aminobutyric acid (GABA), oligodendrocyte marker (O4), myelin basic protein (MBP), galactocerebroside (GalC), glial fibrillary acidic protein (GFAP), CD211b, dopamine, norepinephrine, epinephrine, glutamate, glycine, acetylcholine, serotonin, and endorphin. The supernatant may also include one or more of the above, or neurotrophins, such as S-100, GDNF, CNTF, BDNF, NGF, NT3, NT4/5, which may be secreted by the NPCP.

It is noted that the cells in CCPs generated from various tissues typically can be characterized as having greater than 80% viability.

It is noted that CCPs generated from blood, bone marrow, and umbilical cord blood, typically have greater than 70% of their cells being CD45+.

There is therefore provided, in accordance with an embodiment of the invention, a method including in vitro stimulating a core cell population (CCP) of at least 5 million cells that have a density of less than 1.072 g/ml, and at least 1.5% of which are CD34+CD45−/dim, to differentiate into a neural progenitor/precursor cell population (NPCP).

In an embodiment, the CCP includes at least 5 million cells that have a density of less than 1.062 g/ml, at least 2% of which are CD34+CD45−/dim, and wherein stimulating the CCP includes stimulating the CCP that has the at least 5 million cells that have a density of less than 1.062 g/ml.

In an embodiment, at least 1.5 million of the cells in the NPCP and at least 1.5% of the cells in the NPCP include at least one molecule or molecular structure selected from the list consisting of: CD34, CD117, CD44, Neu-N, nestin, microtubule associated protein-1 (MAP-1), MAP Tau, microtubule associated protein-2 (MAP-2), neurofilament NF200, neuron-specific enolase (NSE), choline acetyltransferase (ChAT) neuronal class III β-Tubulin, glutamic acid decarboxylase (GAD), S-100, GDNF, CNTF, BDNF, NGF, NT3, NT4/5, glutamic acid, gamma-aminobutyric acid (GABA), oligodendrocyte marker (O4), myelin basic protein (MBP), galactocerebroside (GalC), glial fibrillary acidic protein (GFAP), CD211b, dopamine, norepinephrine, epinephrine, glutamate, glycine, acetylcholine, serotonin, and endorphin.

In an embodiment, the method includes preparing the NPCP as a research tool.

In an embodiment, stimulating the CCP includes only stimulating the CCP if the CCP is derived from a mammalian donor.

In an embodiment, the method includes applying cells extracted from a mammalian donor to one or more gradients suitable for selecting cells having a density less than 1.072 g/ml, and deriving the CCP responsive to applying the cells to the gradient.

In an embodiment, the CCP is characterized by at least 2% of the CCP being CD34+CD45−/dim, and wherein stimulating the CCP includes stimulating the CCP having the at least 2% of the CCP that are CD34+CD45−/dim.

In an embodiment, the CCP is characterized by at least 2.5% of the CCP being CD34+CD45−/dim, and wherein stimulating the CCP includes stimulating the CCP having the at least 2.5% of the CCP that are CD34+CD45−/dim.

In an embodiment, the CCP is characterized by at least 50% of the CCP being CD14+, and wherein stimulating the CCP includes stimulating the CCP having the at least 50% of the CCP that are CD14+.

In an embodiment, the CCP is characterized by at least 30% of the CCP being CD14+, and wherein stimulating the CCP includes stimulating the CCP having the at least 30% of the CCP that are CD14+.

In an embodiment, the CCP is characterized by at least 70% of the CCP being CD31+, and wherein stimulating the CCP includes stimulating the CCP having the at least 70% of the CCP that are CD31+.

In an embodiment, the CCP is characterized by at least 40% of the CCP being CD31+, and wherein stimulating the CCP includes stimulating the CCP having the at least 40% of the CCP that are CD31+.

In an embodiment, stimulating the CCP includes stimulating the CCP to differentiate into a pre-designated, desired class of neural progenitor cells.

In an embodiment, stimulating the CCP includes culturing the CCP during a period of between 3 and 60 days in vitro.

In an embodiment, the method includes deriving the CCP from at least one source selected from the list consisting of: umbilical cord blood, umbilical cord tissue, neonatal tissue, adult tissue, fat tissue, nervous tissue, bone marrow, mobilized blood, peripheral blood, peripheral blood mononuclear cells, and skin tissue.

In an embodiment, the method includes deriving the CCP from at least one source selected from the list consisting of: fresh tissue and frozen tissue.

In an embodiment, the method includes identifying an intended recipient of the NPCP, and deriving the CCP from at least one source selected from the list consisting of: tissue autologous to tissue of the intended recipient, tissue syngeneic to tissue of the intended recipient, tissue allogeneic to tissue of the intended recipient, and tissue xenogeneic to tissue of the intended recipient.

In an embodiment, stimulating the CCP includes incubating the CCP in a container having a surface including at least one of: an antibody and autologous plasma.

In an embodiment, stimulating the CCP includes culturing the CCP for a period lasting between 1 and 5 days in a culture medium including less than 0.01% serum.

In an embodiment, stimulating the CCP includes culturing the CCP for a period lasting between 1 and 5 days in a culture medium including less than 5% serum.

In an embodiment, stimulating the CCP includes culturing the CCP for a period lasting between 1 and 5 days in a culture medium including at least 10% serum.

In an embodiment, stimulating the CCP includes culturing the CCP in the presence of at least one of the following: B27, F12, a proliferation-differentiation-enhancing agent, anti-CD34, anti-CD117, LIF, IGF, b-FGF, M-CSF, GM-CSF, TGF alpha, TGF beta, BHA, BDNF, NGF, NT3, NT4/5, S-100, GDNF, CNTF, EGF, NGF3, CFN, ADMIF, estrogen, prolactin, an adrenocorticoid, glutamate, serotonin, acetylcholine, retinoic acid (RA), heparin, insulin, forskolin, cortisone, and a derivative of any of these.

In an embodiment, the method includes preparing the CCP, and facilitating a diagnosis responsive to a characteristic of the preparation of the CCP.

In an embodiment, the method includes freezing the CCP prior to stimulating the CCP.

In an embodiment, the method includes freezing the NPCP.

In an embodiment, the method includes transporting the CCP to a site at least 10 km from a site where the CCP is first created, and stimulating the CCP at the remote site.

In an embodiment, the method includes transporting the NPCP to a site at least 10 km from a site where the NPCP is first created.

In an embodiment, the method includes transfecting a gene into the NPCP, and subsequently assessing a level of expression of the gene.

In an embodiment, the method includes transfecting a gene into the CCP, and subsequently assessing a level of expression of the gene.

In an embodiment, the method includes transfecting into the NPCP a gene identified as suitable for gene therapy.

In an embodiment, the method includes transfecting a gene into the CCP prior to stimulating the CCP.

In an embodiment, transfecting the gene includes transfecting into the CCP a gene identified as suitable for gene therapy.

In an embodiment, the method includes preparing, as a product for administration to a patient, the NPCP generated by differentiation of the CCP into which the gene has been transfected.

In an embodiment, the method includes preparing the NPCP as a product for administration to a patient.

In an embodiment, the patient has a condition selected from the list consisting of: a neural consequence of a transient ischemic attack (TIA), a neural consequence of ischemic stroke, a circulatory disease, hypertensive neuropathy, venous thrombosis, a cerebrovascular disorder, a cerebrovascular disorder caused by bleeding, a neural consequence of intracerebral hemorrhage, a neural consequence of subdural hemorrhage, a neural consequence of epidural hemorrhage, a neural consequence of subarachnoid hemorrhage, a neural consequence of an arteriovenous malformation, Alzheimer's-related dementia, non-Alzheimer's-related dementia, vascular dementia, AIDS dementia, hereditary degeneration, Batten's syndrome, traumatic CNS injury, a neural consequence of a CNS neoplasm, a neural consequence of peripheral nervous system surgery, a neural consequence of central nervous system surgery, a radiation injury to the CNS, a neural consequence of a CNS infection, Parkinson's disease, a choreoathetoid syndrome, a progressive supranuclear palsy, spinocerebellar degeneration, multiple sclerosis, a demyelinating diseases, acute disseminated encephalomyelitis, adrenoleukodystrophy, neuromyelitis optica, a neural deficit due to cerebral palsy, a neurological consequence of hydrocephalus, Leber's optic atrophy, a mitochondrial disease, myoclonus epilepsy associated with ragged-end fiber disease (MERRF), mitochondrial encephalomyopathy, a motor neuron disease, progressive muscular atrophy, amyotrophic lateral sclerosis, a cranial nerve lesion, Horner's syndrome, internuclear opthalmoplegia, Parinaud's syndrome, a gaze palsy, a neural consequence of intoxication, a neural consequence of poisoning, acquired retinal degeneration, age related macular degeneration (AMD), myopic retinopathy, Best's disease, central serous choroidoretinopathy, a vascular retinopathy, diabetic retinopathy, hypertensive retinopathy, glaucoma, retinitis pigmentosa, a hereditary retinopathy, a retinal hole, an ophthalmic mechanical injury affecting a retina, a radiation injury affecting the retina, a retinal vascular occlusion, a retinal deficit caused by retinal detachment, an inner-ear disease, peripheral nervous system degeneration, peripheral nervous system injury, and a peripheral nervous system vascular lesion.

In an embodiment, the method includes facilitating a diagnosis responsive to stimulating the CCP to differentiate into the NPCP.

In an embodiment, facilitating the diagnosis includes assessing an extent to which the stimulation of the CCP produces a particular characteristic of the NPCP.

In an embodiment, stimulating the CCP includes incubating the CCP in a container with a surface including a growth-enhancing molecule other than collagen or fibronectin.

In an embodiment, incubating the CCP includes incubating the CCP in a container having a surface that includes, in addition to the growth-enhancing molecule, at least one of: collagen, fibronectin, and autologous plasma.

In an embodiment, mixing the growth-enhancing molecule with the at least one of: collagen, fibronectin, and autologous plasma.

In an embodiment, applying to the surface a layer that includes the growth-enhancing molecule and a separate layer that includes the at least one of: collagen, fibronectin, and autologous plasma.

In an embodiment, stimulating the CCP includes:

during a low-serum time period, culturing the CCP in a culture medium including less than 10% serum; and

during a high-serum time period, culturing the CCP in a culture medium including greater than or equal to 10% serum

In an embodiment, culturing the CCP in the culture medium including less than 10% serum includes culturing the CCP in a culture medium including less than 0.01% serum.

In an embodiment, culturing the CCP during the low-serum time period includes culturing the CCP for a duration of between 1 and 5 days.

In an embodiment, culturing the CCP during the high-serum time period includes culturing the CCP for a duration of between 1 and 30 days.

In an embodiment, culturing the CCP during the low-serum time period is performed prior to culturing the CCP during the high-serum time period.

In an embodiment, culturing the CCP during the low-serum time period is performed following culturing the CCP during the high-serum time period.

In an embodiment, stimulating the CCP includes:

culturing the CCP in a first container during a first portion of a culturing period;

removing at least some cells of the CCP from the first container at the end of the first portion of the period; and culturing, in a second container during a second portion of the period, the cells removed from the first container.

In an embodiment, removing at least some cells of the CCP includes selecting for removal cells that adhere to a surface of the first container.

In an embodiment, removing at least some cells of the CCP includes selecting for removal cells that do not adhere to a surface of the first container.

In an embodiment, the first container includes on a surface thereof a growth-enhancing molecule, and wherein culturing the CCP in the first container includes culturing the CCP in the first container that includes the growth-enhancing molecule.

In an embodiment, the growth-enhancing molecule is selected from the list consisting of: collagen, fibronectin, autologous plasma, a growth factor, and an antibody to a stem cell surface receptor.

In an embodiment, the second container includes on a surface thereof a growth-enhancing molecule, and wherein culturing the CCP in the second container includes culturing the CCP in the second container that includes the growth-enhancing molecule.

In an embodiment, the growth-enhancing molecule is selected from the list consisting of: collagen, fibronectin, autologous plasma, a growth factor, and an antibody to a stem cell surface receptor.

In an embodiment, stimulating includes culturing the CCP with at least one factor derived from a target tissue.

In an embodiment, the method includes preparing a conditioned medium for culturing the CCP therein, the conditioned medium including the factor, the factor being derived from a tissue selected from the list consisting of: peripheral nerve tissue, central nervous system (CNS) tissue, retinal tissue, pigment epithelial tissue, photoreceptor tissue, fetal retinal tissue, embryonic retinal tissue, and mature retinal tissue.

In an embodiment, stimulating includes co-culturing the CCP with a target tissue.

In an embodiment, co-culturing includes preparing the target tissue by a method selected from the list consisting of: slicing the target tissue, homogenizing the target tissue, freezing the target tissue, processing the target tissue by ultrasound, and processing the target tissue by non-ultrasound radiation.

In an embodiment, co-culturing includes:

utilizing the target tissue to produce a conditioned medium; and

co-culturing the CCP with the target tissue in the conditioned medium.

In an embodiment, co-culturing includes separating the target tissue from the CCP by a semi-permeable membrane.

In an embodiment, the method includes designating the target tissue to include a tissue selected from the list consisting of: peripheral nerve tissue, central nervous system (CNS) tissue, retinal tissue, pigment epithelial tissue, photoreceptor tissue, fetal retinal tissue, embryonic retinal tissue, and mature retinal tissue.

There is also provided, in accordance with an embodiment of the present invention, a method including in vitro stimulating a core cell population (CCP) of at least 5 million cells that have a density of less than 1.072 g/ml, and at least 1.5% or at least 2% of which are CD34+CD45−/dim, to differentiate into a progenitor/precursor cell population (PCP), such as a neural progenitor/precursor cell population (NPCP) or a non-neural progenitor/precursor cell population.

For some applications, the CCP includes at least 5 million cells that have a density of less than 1.062 g/ml, at least 2% of which are CD34+CD45−/dim, and stimulating the CCP includes stimulating the CCP that has the at least 5 million cells that have a density of less than 1.062 g/ml.

For some applications, the method includes preparing the PCP as a product for administration to a patient. Alternatively, the method includes preparing the PCP as a research tool.

For some applications, stimulating the CCP includes only stimulating the CCP if the CCP is derived from a mammalian donor. For some applications, the method includes applying cells extracted from a mammalian donor to one or more gradients suitable for selecting cells having a density less than 1.072 g/ml, and deriving the CCP responsive to applying the cells to the gradient.

For some applications, the CCP is characterized by at least 2.5% of the CCP being CD34+CD45−/dim, and stimulating the CCP includes stimulating the CCP having the at least 2.5% of the CCP that are CD34+CD45−/dim. For some applications, the CCP is characterized by at least 50% of the CCP being CD14+, and stimulating the CCP includes stimulating the CCP having the at least 50% of the CCP that are CD14+. For some applications, the CCP is characterized by at least 30% of the CCP being CD14+, and stimulating the CCP includes stimulating the CCP having the at least 30% of the CCP that are CD14+. For some applications, the CCP is characterized by at least 40% or at least 70% of the CCP being CD31+, and stimulating the CCP includes stimulating the CCP having the at least 40% or at least 70% of the CCP that are CD31+.

For some applications, stimulating the CCP includes stimulating the CCP to differentiate into a pre-designated, desired class of progenitor cells.

For some applications, stimulating the CCP includes culturing the CCP during a period of between 3 and 60 days in vitro.

For some applications, the method includes deriving the CCP from at least one source selected from the list consisting of: umbilical cord blood, umbilical cord tissue, neonatal tissue, adult tissue, fat tissue, nervous tissue, bone marrow, mobilized blood, peripheral blood, peripheral blood mononuclear cells, and skin cells. Alternatively, the method includes deriving the CCP from at least one source selected from the list consisting of: fresh tissue and frozen tissue. For some applications, the method includes identifying an intended recipient of the NPCP, and deriving the CCP from at least one source selected from the list consisting of: tissue autologous to tissue of the intended recipient, tissue syngeneic to tissue of the intended recipient, tissue allogeneic to tissue of the intended recipient, and tissue xenogeneic to tissue of the intended recipient.

For some applications, stimulating the CCP includes incubating the CCP in a container having a surface including an antibody.

For some applications, stimulating the CCP includes culturing the CCP for a period lasting between 1 and 60 days in a culture medium, which is either serum-free or contains less than 5% serum. For some applications, stimulating the CCP includes culturing the CCP for a period lasting between 1 and 5 days in a culture medium including at least 10% serum.

For some applications, stimulating the CCP includes culturing the CCP in the presence of at least one of the following: a proliferation-differentiation-enhancing agent, anti-CD34, anti-CD133, anti-CD117, LIF, EPO, IGF, b-FGF, M-CSF, GM-CSF, TGF alpha, TGF beta, VEGF, BHA, B27, F12, BDNF, NGF, NT3, NT4/5, S-100, GDNF, CNTF, EGF, NGF3, CFN, ADMIF, estrogen, prolactin, an adrenocorticoid, glutamate, serotonin, acetylcholine, NO, retinoic acid (RA), heparin, insulin, forskolin, and/or cortisone, and/or a derivative of any of these.

For some applications, the method includes preparing the CCP, and facilitating a diagnosis responsive to a characteristic of the preparation of the CCP.

For some applications, the method includes freezing the CCP prior to stimulating the CCP. For some applications, the method includes freezing the PCP.

For some applications, the method includes transporting the CCP to a site at least 10 km from a site where the CCP is first created, and stimulating the CCP at the remote site. For some applications, the method includes transporting the PCP to a site at least 10 km from a site where the PCP is first created.

In an embodiment, the method includes facilitating a diagnosis responsive to stimulating the CCP to differentiate into the PCP. For some applications, facilitating the diagnosis includes assessing an extent to which the stimulation of the CCP produces a particular characteristic of the NPCP.

In an embodiment, the method includes transfecting a gene into the CCP prior to stimulating the CCP. For some applications, the method includes preparing, as a product for administration to a patient, the PCP generated by differentiation of the CCP into which the gene has been transfected.

In an embodiment, stimulating the CCP includes incubating the CCP in a container with a surface including a growth-enhancing molecule other than collagen or fibronectin. For some applications, incubating the CCP cells includes incubating the CCP in a container having a surface that includes, in addition to the growth-enhancing molecule, at least one of: collagen and fibronectin. For some applications, the method includes mixing the growth-enhancing molecule with the at least one of: collagen and fibronectin. For some applications, the method includes applying to the surface a layer that includes the growth-enhancing molecule and a separate layer that includes the at least one of: collagen and fibronectin.

In an embodiment, stimulating the CCP includes:

during a serum-free or low-serum period, culturing the CCP in a culture medium including less than 10% serum; and

during a high-serum time period, culturing the CCP in a culture medium including greater than or equal to 10% serum.

For some applications, culturing the CCP during the serum-free or low-serum time period includes culturing the CCP for a duration of between 1 and 60 days. For some applications, culturing the CCP during the high-serum time period includes culturing the CCP for a duration of between 1 and 60 days. For some applications, culturing the CCP during the serum-free or low-serum time period is performed prior to culturing the CCP during the high-serum time period. For some applications, culturing the CCP during the serum-free or low-serum time period is performed following culturing the CCP during the high-serum time period.

In an embodiment, stimulating the CCP includes:

culturing the CCP in a first container during a first portion of a culturing period;

For some applications, removing at least some cells of the CCP includes selecting for removal cells that adhere to a surface of the first container. For some applications, removing at least some cells of the CCP includes selecting for removal cells that do not adhere to a surface of the first container.

For some applications, the first container includes on a surface thereof a growth-enhancing molecule, and culturing the CCP in the first container includes culturing the CCP in the first container that includes the growth-enhancing molecule.

For some applications, the growth-enhancing molecule is selected from the list consisting of: collagen, fibronectin, a growth factor, and an antibody to a stem cell surface receptor.

For some applications, the second container includes on a surface thereof a growth-enhancing molecule, and culturing the CCP in the second container includes culturing the CCP in the second container that includes the growth-enhancing molecule.

For some applications, the growth-enhancing molecule is selected from the list consisting of: collagen, fibronectin, a growth factor, and an antibody to a stem cell surface receptor.

In an embodiment, stimulating includes culturing the CCP with at least one factor derived from a target tissue. For some applications, the method includes preparing a conditioned medium for culturing the CCP therein, the conditioned medium including the factor, the factor being derived from a tissue selected from the list consisting of: peripheral nerve tissue, central nervous system (CNS) tissue, retinal tissue, pigment epithelial tissue, photoreceptor tissue, fetal retinal tissue, embryonic retinal tissue, and mature retinal tissue. In an embodiment, stimulating includes co-culturing the CCP with a target tissue. For some applications, co-culturing includes preparing the target tissue by a method selected from the list consisting of: slicing the target tissue, homogenizing the target tissue, freezing the target tissue, and processing the target tissue by ultra-sound or other type of radiation.

For some applications, co-culturing includes utilizing the target tissue to produce a conditioned medium, and co-culturing the CCP with the target tissue in the conditioned medium. For some applications, co-culturing includes separating the target tissue from the CCP by a semi-permeable membrane.

For some applications, the method includes designating the target tissue to include a tissue selected from the list consisting of: peripheral nerve tissue, central nervous system (CNS) tissue, retinal tissue, pigment epithelial tissue, photoreceptor tissue, fetal retinal tissue, embryonic, retinal tissue, and mature retinal tissue.

There is also provided, in accordance with an embodiment of the present invention, a method including in vitro stimulating an elemental cell population (ECP) of at least 5 million cells that have a density of less than 1.072 g/ml, at least 1.5% of which are CD34+CD45−/dim, at least 30% of which are CD14+, and/or at least 40% of which are CD31+, to differentiate into a progenitor/precursor cell population (PCP).

For some applications, the ECP includes at least 5 million cells that have a density of less than 1.062 g/ml, at least 2% of which are CD34+CD45−/dim, and stimulating the ECP includes stimulating the ECP that has the at least 5 million cells that have a density of less than 1.062 g/ml.

For some applications, stimulating the ECP includes only stimulating the ECP if the ECP is derived from a mammalian donor. For some applications, the method includes applying cells extracted from a mammalian donor to one or more gradients suitable for selecting cells having a density less than 1.072 g/ml, and deriving the ECP responsive to applying the cells to the gradient.

For some applications, the ECP is characterized by at least 2.5% of the ECP being CD34+CD45−/dim, and stimulating the ECP includes stimulating the ECP having the at least 2.5% of the ECP that are CD34+CD45−/dim. For some applications, the ECP is characterized by at least 50% of the ECP being CD14+, and stimulating the ECP includes stimulating the ECP having the at least 50% of the ECP that are CD14+. For some applications, the ECP is characterized by at least 30% of the ECP being CD14+, and stimulating the ECP includes stimulating the ECP having the at least 30% of the ECP that are CD14+. For some applications, the ECP is characterized by at least 40% or at least 70% of the ECP being CD31+, and stimulating the ECP includes stimulating the ECP having the at least 40% or at least 70% of the ECP that are CD31+.

For some applications, stimulating the ECP includes stimulating the ECP to differentiate into a pre-designated, desired class of progenitor cells.

For some applications, stimulating the ECP includes culturing the ECP during a period of between 3 and 60 days in vitro.

For some applications, the method includes deriving the ECP from at least one source selected from the list consisting of: umbilical cord blood, umbilical cord tissue, neonatal tissue, adult tissue, fat tissue, nervous tissue, bone marrow, mobilized blood, peripheral blood, peripheral blood mononuclear cells, and skin cells. Alternatively, the method includes deriving the ECP from at least one source selected from the list consisting of: fresh tissue and frozen tissue. For some applications, the method includes identifying an intended recipient of the PCP, and deriving the ECP from at least one source selected from the list consisting of: tissue autologous to tissue of the intended recipient, tissue syngeneic to tissue of the intended recipient, tissue allogeneic to tissue of the intended recipient, and tissue xenogeneic to tissue of the intended recipient.

For some applications, stimulating the ECP includes incubating the ECP in a container having a surface including an antibody.

For some applications, stimulating the ECP includes culturing the ECP for a period lasting between 1 and 60 days in a culture medium including serum-free or less than 5% serum. For some applications, stimulating the ECP includes culturing the ECP for a period lasting between 1 and 60 days in a culture medium including at least 10% serum.

For some applications, stimulating the ECP includes culturing the ECP in the presence of at least one of the following: a proliferation-differentiation-enhancing agent, anti-CD34, anti-Tie-2, anti-CD133, anti-CD117, LIF, EPO, IGF, b-FGF, M-CSF, GM-CSF, TGF alpha, TGF beta, VEGF, BHA, B27, F12, BDNF, NGF, NT3, NT4/5, S-100, GDNF, CNTF, EGF, NGF3, CFN, ADMIF, estrogen, prolactin, an adrenocorticoid, glutamate, serotonin, acetylcholine, NO, retinoic acid (RA), heparin, insulin, forskolin, and/or cortisone, and/or a derivative of any of these.

For some applications, the method includes preparing the ECP, and facilitating a diagnosis responsive to a characteristic of the preparation of the ECP.

For some applications, the method includes freezing the ECP prior to stimulating the ECP. For some applications, the method includes freezing the NPCP.

For some applications, the method includes transporting the ECP to a site at least 10 km from a site where the ECP is first created, and stimulating the ECP at the remote site. For some applications, the method includes transporting the NPCP to a site at least 10 km from a site where the NPCP is first created.

In an embodiment, the method includes facilitating a diagnosis responsive to stimulating the ECP to differentiate into the NPCP. For some applications, facilitating the diagnosis includes assessing an extent to which the stimulation of the ECP produces a particular characteristic of the NPCP.

In an embodiment, the method includes transfecting a gene into the ECP prior to stimulating the ECP. For some applications, the method includes preparing, as a product for administration to a patient, the NPCP generated by differentiation of the ECP into which the gene has been transfected.

In an embodiment, stimulating the ECP includes incubating the ECP in a container with a surface including a growth-enhancing molecule or substance other than collagen or fibronectin or autologous plasma. For some applications, incubating the ECP cells includes incubating the ECP in a container having a surface that includes, in addition to the growth-enhancing molecule, at least one of: collagen, fibronectin, and autologous plasma. For some applications, the method includes mixing the growth-enhancing molecule with the at least one of: collagen and fibronectin and autologous plasma. For some applications, the method includes applying to the surface a layer that includes the growth-enhancing molecule and a separate layer that includes the at least one of: collagen, fibronectin, and autologous plasma.

In an embodiment, stimulating the ECP includes:

during a serum-free or low-serum time period, culturing the ECP in a culture medium including less than 10% serum; and during a high-serum time period, culturing the ECP in a culture medium including greater than or equal to 10% serum.

For some applications, culturing the ECP during the serum-free or low-serum time period includes culturing the ECP for a duration of between 1 and 60 days. For some applications, culturing the ECP during the high-serum time period includes culturing the ECP for a duration of between 1 and 60 days. For some applications, culturing the ECP during the serum-free or low-serum time period is performed prior to culturing the ECP during the high-serum time period. For some applications, culturing the ECP during the serum-free or low-serum time period is performed following culturing the ECP during the high-serum time period.

In an embodiment, stimulating the ECP includes:

culturing the ECP in a first container during a first portion of a culturing period;

removing at least some cells of the ECP from the first container at the end of the first portion of the period; and culturing, in a second container during a second portion of the period, the cells removed from the first container.

For some applications, removing at least some cells of the ECP includes selecting for removal cells that adhere to a surface of the first container. For some applications, removing at least some cells of the ECP includes selecting for removal cells that do not adhere to a surface of the first container.

For some applications, the first container includes on a surface thereof a growth-enhancing molecule, and culturing the ECP in the first container includes culturing the ECP in the first container that includes the growth-enhancing molecule.

For some applications, the second container includes on a surface thereof a growth-enhancing molecule, and culturing the ECP in the second container includes culturing the ECP in the second container that includes the growth-enhancing molecule.

In an embodiment, stimulating includes culturing the ECP with at least one factor derived from a target tissue. For some applications, the method includes preparing a conditioned medium for culturing the ECP therein, the conditioned medium including the factor, the factor being derived from a tissue selected from the list consisting of: peripheral nerve tissue, central nervous system (CNS) tissue, retinal tissue, pigment epithelial tissue, photoreceptor tissue, fetal retinal tissue and embryonic retinal tissue, mature retinal tissue.

In an embodiment, stimulating includes co-culturing the ECP with a target tissue. For some applications, co-culturing includes freezing the target tissue and/or processing the target tissue by ultrasound or other type of radiation. For some applications, co-culturing includes preparing the target tissue by a method selected from the list consisting of: slicing the target tissue, and homogenizing the target issue. For some applications, co-culturing includes utilizing the target tissue to produce a conditioned medium, and co-culturing the ECP with the target tissue in the conditioned medium. For some applications, co-culturing includes separating the target tissue from the ECP by a semi-permeable membrane.

There is therefore provided, in accordance with an embodiment of the present invention, a method including in vitro stimulating a core cell population (CCP) of at least 5 million cells that have a density of less than 1.072 g/ml, and at least 1.5% of which are CD34+CD45−/dim, to differentiate into a neural progenitor/precursor cell population (NPCP).

In an embodiment, the CCP includes at least 5 million cells that have a density of less than 1.062 g/ml, at least 2% of which are CD34+CD45−/dim, and stimulating the CCP includes stimulating the CCP that has the at least 5 million cells that have a density of less than 1.062 g/ml.

In an embodiment, at least 1.5 million of the cells in the NPCP and at least 1.5% of the cells in the NPCP include at least one molecule or molecular structure selected from the list consisting of: CD34, CD117, CD44, Neu-N, nestin, microtubule associated protein-1 (MAP-1), MAP Tau, microtubule associated protein-2 (MAP-2), neurofilament NF200, neuron-specific enolase (NSE), choline acetyltransferase (ChAT) neuronal class III β-Tubulin, glutamic acid decarboxylase (GAD), glutamic acid, gamma-aminobutyric acid (GABA), oligodendrocyte marker (O4), myelin basic protein (MBP), galactocerebroside (GalC), glial fibrillary acidic protein (GFAP), CD211b, dopamine, norepinephrine, epinephrine, glutamate, glycine, acetylcholine, serotonin, and endorphin. The supernatant may also include one or more of the above, or neurotrophins, such as S-100, GDNF, CNTF, BDNF, NGF, NT3, NT4/5, which may be secreted by the NPCP.

In an embodiment, the method includes preparing the NPCP as a research tool.

In an embodiment, stimulating the CCP includes only stimulating the CCP if the CCP is derived from a mammalian donor.

In an embodiment, the CCP is characterized by at least 2% of the CCP being CD34+CD45−/dim, and stimulating the CCP includes stimulating the CCP having the at least 2% of the CCP that are CD34+CD45−/dim.

In an embodiment, the CCP is characterized by at least 2.5% of the CCP being CD34+CD45−/dim, and stimulating the CCP includes stimulating the CCP having the at least 2.5% of the CCP that are CD34+CD45−/dim.

In an embodiment, the CCP is characterized by at least 50% of the CCP being CD14+, and stimulating the CCP includes stimulating the CCP having the at least 50% of the CCP that are CD14+.

In an embodiment, the CCP is characterized by at least 30% of the CCP being CD14+, and stimulating the CCP includes stimulating the CCP having the at least 30% of the CCP that are CD14+.

In an embodiment, the CCP is characterized by at least 70% of the CCP being CD31+, and stimulating the CCP includes stimulating the CCP having the at least 70% of the CCP that are CD31+.

In an embodiment, the CCP is characterized by at least 40% of the CCP being CD31+, and stimulating the CCP includes stimulating the CCP having the at least 40% of the CCP that are CD31+.