Patent Description:
Treatment regimens which deliver therapeutic agents such as polypeptides to diseased tissues in vivo can provide ultimate therapy options for many refractory pathologies including certain metastatic cancers. However, the use of peptide drugs and therapeutic proteins is limited by their poor stability and/or permeability in certain physiological environments. Thus, there is a growing effort to circumvent these problems by designing nanostructures that can act as carriers for the delivery of therapeutic proteins such antibodies.

Treatments for cancer metastases, especially those of the central nervous system (CNS), are less successful than those for primary tumors (<NUM>). Approximately <NUM>%-<NUM>% of all cancers develop a CNS metastasis (<NUM>,<NUM>), which most commonly arises from lung cancer, melanoma, breast cancer, and colorectal cancer. Therapeutic monoclonal antibodies (mAbs) have revolutionized the treatment of cancer; however, their efficacy is limited in patients with CNS metastases due to insufficient mAb CNS delivery-typically <NUM>% of the levels in plasma (<NUM>). By bypassing the blood-brain barrier (BBB) through intrathecal or intraventricular administration, mAb therapy has shown some effectiveness against CNS tumor metastases (<NUM>-<NUM>). However, direct CNS administration is invasive, with potential for neurotoxicity, and is limited by rapid efflux of antibodies from the CNS within hours (<NUM>,<NUM>,<NUM>). Therefore, novel approaches for mAbs delivery are preferable to maintain systemic therapeutic effect in the CNS with improved efficiency.

To date, various carrier vehicles for macromolecule delivery such as viral vectors, liposomes, cationic polymers, inorganic delivery systems, and other biomolecules have been explored to improve CNS delivery (<NUM>-<NUM>). Viral vectors are effective for CNS delivery in some settings but have potential safety concerns (<NUM>,<NUM>). Liposome-based protein delivery has been shown to penetrate the BBB, but with relatively low efficiency, biocompatibility and stability (<NUM>,<NUM>). Polymer nanoparticles conjugated to target ligands with a variety of structures and morphologies have been used to form micelles through self-assembly, but in vivo instability, tissue-specific accumulations and protein denaturation during complexing are problematic (<NUM>,<NUM>). Inorganic delivery systems, including gold nanoparticles (<NUM>,<NUM>) and mesoporous silica particles (<NUM>), are non-biodegradable and difficult to load or conjugate with macromolecules. Biomolecules, such as cell-penetrating peptides and antibodies, have improved the efficacy of macromolecule delivery, but degradation of cargo still hampers their therapeutic applications (<NUM>). The above approaches have shown promise, but drastic improvements are needed-especially in the systemic delivery of macromolecules into the CNS (<NUM>,<NUM>). Patent document <CIT> discloses nanocapsules having a brain tumor targeting delivery effect.

Rituximab (RTX) for treatment of non-Hodgkin lymphoma (NHL) was the first anticancer antibody approved by the U. Food and Drug Administration. RTX binds to CD20+ lymphoma cells and induces cell death through complement-dependent cytotoxicity (CDC), antibody-dependent cell-mediated cytotoxicity (ADCC), and apoptosis (<NUM>). RTX may also promote anti-lymphoma immune responses (<NUM>). The substantial benefits of RTX administration in treatments for systemic NHL are well-established, but treatment of primary and relapsed CNS lymphoma has not been effective through the intravenous route, likely due to the very low levels of systemic RTX entering the CNS (<NUM>). CNS involvement in NHL is relatively rare, but there is an elevated risk in patients with immunodeficiency diseases<NUM> or renal, cardiac, lung, and liver transplantation.

Central nervous system (CNS) metastases are a major cause of cancer deaths with unfortunately few therapeutic options. While monoclonal antibody-based therapy for cancer is a powerful therapeutic strategy, such therapies are typically limited in CNS metastases due to insufficient antibody delivery to the CNS. Consequently, there is a need in this field of technology for methods and materials capable of delivering therapeutic agents such as antibodies to the central nervous system.

It will be appreciated that the scope is in accordance with the claims. In a general context, the present invention relates to nano-encapsulated therapeutic compositions designed to include selected constellations of elements that, for example, allows them to be administrated intravenously and then cross the blood brain barrier into the central nervous system. The present invention further provides methods of making and using these nano-encapsulated therapeutic compositions. The compositions and methods disclosed herein allow medical practitioners to more easily deliver therapeutic agents such as cancer specific antibodies into the central nervous system, and in this way overcome significant problems in this field of technology. Accordingly, there is provided nanoencapsulated therapeutic composition as defined in claim <NUM>, a method of making said composition as defined in claim <NUM> and said composition for use in delivering a therapeutic agent to the central nervous system as defined in claim <NUM>. Further features are provided in accordance with the dependent claims. The specification may include description of arrangements outside the scope of the claims provided as background and to assist in understanding the invention. In working embodiments of the invention presented herein, we demonstrate that, as compared to administration of native antibody Rituximab (RTX), timed-release nanocapsule delivery of RTX achieves levels around <NUM>-fold higher RTX concentration in the CNS following a single-course treatment and is maintained for at least <NUM> weeks, as opposed to <NUM> week with native RTX. Furthermore, we developed a human NHL xenograft murine model for CNS metastases and show therapeutic efficacy of RTX nanocapsules against CNS lymphomas. In addition, using a humanized BLT mouse model of human brain cancer, we demonstrate clearance of the CNS lymphomas.

The invention disclosed herein has a number of embodiments as defined in the claims. Embodiments of the invention include a composition of matter as defined in claim <NUM> comprising: a polypeptide cargo antibody; a polymeric network configured to form a polymer shells using, for example, neutral monomers with zwitterionic properties, and <NUM>-methacryloyloxyethyl phosphorylcholine to form a nanocapsule that encapsulates the polypeptide cargo antibody; and hydrolysable crosslinking moieties comprising a glycerol dimethacrylate and/or a Poly(DL-lactide)-b-Poly(ethylene glycol)-b-Poly(DL-lactide)-diacrylate triblock copolymer coupled to polymers forming the polymeric network of the nanocapsule and a targeting agent CXCL13 coupled to the polymeric network, selected for its ability to preferentially bind to targets present in tissues of the central nervous system. In such embodiments of the invention, the nanocapsule is formed in situ on the polypeptide cargo; the polymeric network and the hydrolysable crosslinking moiety and their relative amounts are disposed in a three-dimensional architecture so that: the nanocapsule crosses blood brain barriers to deliver nanocapsules in a bloodstream into a central nervous system; and the hydrolysable crosslinking moiety is cleaved in the central nervous system so as to release the polypeptide cargo from the nanocapsule. Optionally such embodiments include a plurality of nanocapsules, wherein constituents and ratios of the nanocapsule components in the plurality of nanocapsules are disposed in a three-dimensional architecture so that the plurality of nanocapsules release the polypeptide cargos at different rates of time. In certain embodiments of the invention, the constituents and ratios of the shell components, the polypeptide cargo, the polymeric network and the hydrolysable crosslinking moiety are disposed in a three-dimensional architecture so that about <NUM>-fold more protein cargo crosses blood brain barriers as compared with the protein cargo antibody in the absence of the nanocapsule.

Specifically, claim <NUM> is directed to a composition of matter comprising an antibody; a polymeric network formed from <NUM>-methacryloyloxyethyl phosphorylcholine and configured to form a nanocapsule that encapsulates the antibody; a hydrolysable crosslinking moiety comprising a glycerol dimethacrylate and/or a Poly(DL-lactide)-b-Poly(ethylene glycol)-b-Poly(DL-lactide)-diacrylate triblock copolymer coupled to polymers forming the polymeric network; and a targeting agent comprising CXCL13 coupled to the polymeric network. In this embodiment of the invention, the nanocapsule is formed in situ on the polypeptide cargo; and the nanocapsule constituents and ratios of the polypeptide cargo, the polymeric network, the hydrolysable crosslinking moiety and the targeting agent are disposed in a three-dimensional architecture so that the nanocapsule crosses blood brain barriers to deliver nanocapsules in a bloodstream into a central nervous system such that at least <NUM>, <NUM> or <NUM> fold more antibody that is disposed in the nanocapsule crosses blood brain barriers as compared with the antibody in the absence of the nanocapsule; and the hydrolysable crosslinking moiety is cleaved in the central nervous system so as to release the antibody from the nanocapsule.

Another embodiment of the invention is a method of making a polypeptide cargo antibody (e.g. an antibody selected to target cancerous cells) encapsulated by a polymeric network as defined in claim <NUM>. Typically, the method comprises performing an in situ polymerization process on monomers comprising a <NUM>-methacryloyloxyethyl phosphorylcholine moiety) that localize to the surface of the polypeptide cargo via molecular affinity interactions (e.g. electrostatic interactions and the like) so as to form a polymerized nanocapsule that encapsulates the polypeptide cargo; coupling polymers in the polymeric network with one or more hydrolysable crosslinking moieties, wherein the hydrolysable crosslinking moieties are selected to cleaved in the central nervous system so as to release the polypeptide cargo from the nanocapsule; and then coupling the polymeric network to one or more targeting agents CXCL13 (e.g. a polypeptide comprising a CXCL13 motif), wherein the targeting agents are selected to bind to targets present in tissues of the central nervous system. In such embodiments, the nanocapsule constituents and ratios of the polypeptide cargo antibody, the polymeric network, the hydrolysable crosslinking moiety and the targeting agent are selected to allow the nanocapsule to cross blood brain barriers to deliver protein cargo antibodies into a central nervous system; and also the hydrolysable crosslinking moiety to be cleaved in the central nervous system so as to release the polypeptide cargo antibody from the nanocapsule.

Yet another embodiment of the invention is a method of selectively delivering a therapeutic agent to the central nervous system of an individual, the method comprising intravenously administering a nanocapsule composition defined in claim <NUM> to the individual; and then allowing the composition to cross the blood brain barrier of the individual into the central nervous system. In this context, the composition comprises an antibody, a polymeric network formed from <NUM>-methacryloyloxyethyl phosphorylcholine and configured to form a nanocapsule that encapsulates the antibody, a hydrolysable crosslinking moiety coupled to polymers forming the polymeric network, and a targeting agent CXCL13 (e.g. one that targets diseased tissue within the central nervous system) coupled to the polymeric network. In such embodiments of the invention, the nanocapsule is formed in situ on the polypeptide cargo, the nanocapsule constituents and ratios of the antibody, the polymeric network, the hydrolysable crosslinking moiety and the targeting agent are disposed in a three-dimensional architecture so that the nanocapsule crosses blood brain barriers to deliver nanocapsules present in a bloodstream into a central nervous system such that at least <NUM> fold more antibody disposed in nanocapsules crosses blood brain barriers as compared with the antibody not encapsulated by nanocapsules. Typically in these embodiments, the hydrolysable crosslinking moiety is cleaved in the central nervous system so as to release the antibody from the nanocapsule.

Other objects, features and advantages of the present invention will become apparent to those skilled in the art from the following detailed description. It is to be understood, however, that the detailed description and specific examples, while indicating some embodiments of the present invention, are given by way of illustration and not limitation.

Many of the techniques and procedures described or referenced herein are well understood and commonly employed using conventional methodology by those skilled in the art. In the description of the preferred embodiment, reference may be made to the accompanying drawings which form a part hereof, and in which is shown by way of illustration a specific embodiment in which the invention may be practiced. Unless otherwise defined, all terms of art, notations and other scientific terms or terminology used herein are intended to have the meanings commonly understood by those of skill in the art to which this invention pertains. In some cases, terms with commonly understood meanings are defined herein for clarity and/or for ready reference, and the inclusion of such definitions herein should not necessarily be construed to represent a substantial difference over what is generally understood in the art.

CNS metastases are a major cause of cancer deaths with few therapeutic options for treatment. Monoclonal antibody-based therapy is one of the most successful therapeutic strategies for cancer; however, its efficacy is limited against CNS metastases due to insufficient CNS delivery. Here, we show significantly improved antibody delivery to the CNS using novel timed-release nanocapsules that encapsulate individual antibodies within a thin layer of crosslinked phosphorylcholine polymer and gradually release cargo over time through hydrolysable crosslinkers. Surprisingly, a single course of rituximab (RTX) nanocapsule treatment elevates RTX levels in the CNS by nearly <NUM>-fold compared to native RTX. We improved control of CNS metastases in a murine xenograft model of non-Hodgkin lymphoma; moreover, using a xenograft humanized BLT mouse model, lymphomas were eliminated with a single course of RTX nanocapsule treatment. This approach is useful for treatment of cancers with CNS metastases and is generalizable for delivery of any antibody to the CNS.

As discussed in detail below, embodiments of the invention are based upon, for example, the unexpected discovery that certain types of nanocapsules can be used to elevate levels of intravenously administered therapeutic antibody in the CNS by nearly <NUM>-fold by facilitating crossing of the blood brain barrier. Embodiments of the invention include compositions of matter, as well as methods for making and using such compositions. For example, embodiments of the invention include compositions of matter as defined in claim <NUM> that include a polypeptide cargo and a polymeric network selectively configured to form a polymer shell around the cargo, using, for example, neutral monomers with zwitterionic properties, and <NUM>-methacryloyloxyethyl phosphorylcholine as well as selected hydrolysable crosslinking agents/moieties that are coupled to the polymers that form the nanocapsule that surrounds the polypeptide cargo. In such embodiments of the invention, the nanocapsule is formed in situ on the polypeptide cargo; the polymeric network and the hydrolysable crosslinking moiety and their relative amounts are disposed in a three-dimensional architecture so that: the nanocapsule crosses blood brain barriers to deliver nanocapsules in a bloodstream into a central nervous system; and the hydrolysable crosslinking moiety is cleaved in the central nervous system so as to release the polypeptide cargo from the nanocapsule.

Optionally such compositons of matter include a plurality of different nanocapsules, wherein specific constituents and/or ratios of the nanocapsule components (e.g. degradable crosslinkers and the like) in the plurality of nanocapsules are selected and disposed in a three-dimensional architecture in the nanocapsule so that the plurality of nanocapsules release the polypeptide cargos at different rates of time. In certain embodiments of the invention, the constituents and ratios of the shell components, the polypeptide cargo antibody), the polymeric network and the hydrolysable crosslinking moiety are disposed in a three-dimensional architecture so that at least <NUM>, <NUM> or <NUM>-fold more protein cargo crosses blood brain barriers as compared with a control protein cargo in the absence of the nanocapsule.

A specific embodiment of the invention as described in claim <NUM> is a composition of matter comprising an antibody; a polymeric network formed from <NUM>-methacryloyloxyethyl phosphorylcholine and configured to form a nanocapsule that encapsulates the antibody; a hydrolysable crosslinking moiety comprising a glycerol dimethacrylate and/or a Poly(DL-lactide)-b-Poly(ethylene glycol)-b-Poly(DL-lactide)-diacrylate triblock copolymer coupled to polymers forming the polymeric network; and a targeting agent comprising CXCL13 coupled to the polymeric network. In this embodiment of the invention, the nanocapsule is formed in situ on the polypeptide cargo; and the nanocapsule constituents and ratios of the polypeptide cargo, the polymeric network, the hydrolysable crosslinking moiety and the targeting agent are disposed in a three-dimensional architecture so that the nanocapsule crosses blood brain barriers to deliver nanocapsules in a bloodstream into a central nervous system such that at least about <NUM>, <NUM> or <NUM> fold more antibody that is disposed in the nanocapsule crosses blood brain barriers as compared with the antibody in the absence of the nanocapsule; and the hydrolysable crosslinking moiety is cleaved in the central nervous system so as to release the antibody from the nanocapsule.

Another embodiment of the invention is a method of making a polypeptide cargo antibody (e.g. an antibody selected to target cancerous cells) encapsulated by a polymeric network as defined in claim <NUM>. Typically, the method comprises performing an in situ polymerization process on monomers comprising a <NUM>-methacryloyloxyethyl phosphorylcholine moiety) that form electrostatic interactions with the polypeptide cargo so as to form a nanocapsule that encapsulates the polypeptide cargo; coupling polymers in the polymeric network with one or more hydrolysable crosslinking moieties, wherein the hydrolysable crosslinking moieties are selected to cleaved in the central nervous system so as to release the polypeptide cargo from the nanocapsule; wherein the polymeric network is coupled to one or more targeting agents, wherein the targeting agents CXCL13 are selected to bind to targets present in tissues of the central nervous system (e.g. a polypeptide comprising a CXCL13 motif). In such embodiments, the nanocapsule constituents and ratios of the polypeptide cargo, the polymeric network, the hydrolysable crosslinking moiety and the targeting agent are selected to allow the nanocapsule to cross blood brain barriers to deliver protein cargos into a central nervous system; and also the hydrolysable crosslinking moiety to be cleaved in the central nervous system so as to release the polypeptide cargo from the nanocapsule.

Yet another embodiment of the invention is a method (not claimed) of selectively delivering a therapeutic agent to the central nervous system of an individual or use in delivering a therapeutic agent, the method or use comprising intravenously administering a nanocapsule composition disclosed herein to the individual; and then allowing the composition to cross the blood brain barrier of the individual into the central nervous system. The composition comprises an antibody, a polymeric network formed from <NUM>-methacryloyloxyethyl phosphorylcholine and configured to form a nanocapsule that encapsulates the antibody, a hydrolysable crosslinking moiety comprising a glycerol dimethacrylate and/or a Poly(DL-lactide)-b-Poly(ethylene glycol)-b-Poly(DL-lactide)-diacrylate triblock copolymer coupled to polymers forming the polymeric network, and a targeting agent CXCL13(e.g. one that targets diseased tissue within the central nervous system) coupled to the polymeric network. In such embodiments of the invention, the nanocapsule is formed in situ on the polypeptide cargo antibody, the nanocapsule constituents and ratios of the antibody, the polymeric network, the hydrolysable crosslinking moiety and the targeting agent are disposed in a three-dimensional architecture so that the nanocapsule crosses blood brain barriers to deliver nanocapsules present in a bloodstream into a central nervous system such that at least <NUM>, <NUM>, <NUM> or <NUM> or fold more antibody disposed in nanocapsules crosses blood brain barriers as compared with the antibody not encapsulated by nanocapsules as is surprisingly observed in working embodiments of the invention (see, e.g. the data shown in <FIG>). Typically in these embodiments, the hydrolysable crosslinking moiety is cleaved in the central nervous system so as to release the antibody from the nanocapsule.

As disclosed herein, embodiments of the invention provide for the effective delivery of mAb to the CNS by encapsulating the anti-CD20 mAb rituximab (RTX) within a thin shell of polymer that can comprise, for example, analogs of choline and acetylcholine receptors (e.g. as targeting agents). This encapsulated RTX, denoted as n-RTX, eliminated lymphoma cells systemically in a xenografted humanized mouse model using an immunodeficient mouse as a recipient of human hematopoietic stem/progenitor cells and fetal thymus more effectively than native RTX; importantly, n-RTX showed notable anti-tumor effect on CNS metastases which is unable to be shown by native RTX.

We further illustrated the properties of n-RTX in immunocompetent animals, rats, and non-human primates (NHPs). Results from these studies show that a single intravenous injection of n-RTX resulted in <NUM>-fold greater levels in the CNS and <NUM>-<NUM>-fold greater levels in the lymph nodes of RTX, respectively, than the injection of native RTX in both rats and NHPs. In addition, we demonstrate the enhanced delivery and efficient B-cell depletion in lymphoid organs of NHPs with n-RTX. Moreover, detailed hematological analysis and liver enzyme activity tests indicate n-RTX treatment is safe in NHPs. As this nanocapsule platform can be universally applied to other therapeutic mAbs, it holds great promise for extending mAb therapy to poorly accessible body compartments.

Further illustrative aspects and embodiments of the invention are described in the following sections.

We have developed a nanotechnology platform whereby individual macromolecules are encapsulated within a thin polymer shell formed by in situ polymerization of monomers and stabilized by environmentally-responsive crosslinkers (<NUM>,<NUM>). Like a virion capsid, the polymer shell shields cargo from the environment and confers high resistance to denaturation, proteases, and nucleases, and determines the distribution of nanocapsules. Nanocapsules with polymer shells formed by neutral monomers with zwitterionic properties, <NUM>-methacryloyloxyethyl phosphorylcholine (MPC), exhibited broad biodistribution (<NUM>) and a long half-life (<NUM>). MPC is used in contact lenses and tested for use in coronary stents and other medical devices (<NUM>,<NUM>) and is inert, highly stable, resistant to protein adsorption, and lacks immunogenicity. We synthesized RTX nanocapsules with MPC monomers and glycerol dimethacrylate (GDMA) crosslinkers, which are efficiently degraded under acidic conditions but very slowly under physiological conditions (termed n-RTX(GDMA)).

We first evaluated the biodistribution and brain delivery efficiency of our nanoparticles without release of the RTX cargo under physiologic conditions using n-RTX(GDMA) (<FIG>). Biodistribution of the nanocapsules was assayed by enzyme-linked immunosorbent assay (ELISA) after releasing RTX by acid treatment (pH5. <NUM>) at <NUM> <NUM>C for overnight ex vivo. Higher levels of n-RTX(GDMA) were present in plasma by day <NUM>. Importantly, more RTX released from n-RTX(GDMA) was observed in the brain and cerebrospinal fluid (CSF). Levels of released RTX in CSF were <NUM>-<NUM>% the levels in plasma (<NUM>% on day <NUM>, <NUM> % on day <NUM>, and <NUM>% on day <NUM>); native RTX was undetectable in CSF at all three points. This is consistent with the relative inability of antibodies to cross the BBB (<NUM>).

To achieve proper release of mAb for therapeutic treatment, nanocapsules were designed to release cargo over time. This is accomplished by securing the polymer shell with mixed crosslinkers that are hydrolyzed gradually under physiological conditions (<FIG>). MPC monomers are enriched around the surface of individual RTX molecules through electrostatic interactions, then hydrolysable crosslinker (Poly(DL-lactide)-b-Poly(ethylene glycol)-b-Poly(DL-lactide)-diacrylate triblock copolymers (PLA-PEG-PLA) and slowly-hydrolysable crosslinker GDMA under physiological conditions are associated by hydrogen bonding. Subsequent polymerization in an aqueous solution wraps each molecule with a thin shell of polymer through in-situ free-radical polymerization. When PLA-PEG-PLA is hydrolyzed by body fluids, the nanocapsules dissociate and release encapsulated RTX. These nanocapsules have a relatively uniform, small diameter of <NUM>-<NUM> as measured by transmission electron microscope (TEM) (<FIG>) and consist of a single-RTX molecule core-shell structure (<FIG>). To sustain timed release in plasma at neutral pH, we mixed GDMA with PLA-PEG-PLA to achieve different release rates. Depending on the relative ratios of PLA-PEG-PLA (<NUM>%, <NUM>%, <NUM>%, and <NUM>%), these nanocapsules released RTX at different rates under physiological conditions (<FIG>): RTX nanocapsules with <NUM>% PLA-PEG-PLA crosslinker (termed n-RTX) enabled release to occur gradually over <NUM> days. Importantly, lower pH (pH <NUM>-<NUM>) allowed accelerated RTX release (<FIG>), which would facilitate quicker release of RTX in the lower pH tumor microenvironment (<NUM>,<NUM>) than in the bloodstream or healthy tissues.

We next examined the kinetics of RTX released from nanocapsules with <NUM>% PLA-PEG-PLA crosslinker in B6 mice (<FIG>,<FIG>). Mice were injected with a single intravenous dose of either n-RTX or native RTX. Except for Day <NUM>, where RTX was slightly lower in the n-RTX group, there were comparable levels in plasma through Day <NUM>. In striking contrast, <NUM> to <NUM>-fold enhancements of free RTX levels were surprisingly observed in the CNS and brain tissue when delivered by n-RTX relative to native RTX. Mice treated with n-RTX had detectable levels of RTX in the CNS and brain for up to <NUM> weeks. Similar results were also confirmed in rats. Immunohistochemical staining of rat brains treated with n-RTX showed normal microglia and astrocyte morphology (<FIG>) (<NUM>,<NUM>). No significant elevation of ionized calcium-binding adapter molecule <NUM> (Iba1) in microglial cells nor glial fibrillary acidic proteins (GFAP) in astrocytes of rat brains treated with nanocapsules were observed compared to untreated control animals (<FIG>). These results provide proof of concept for penetration, release, maintenance, and safety of mAb nanocapsules in both plasma and CNS.

Next, we compared anti-lymphoma efficacy of native RTX and n-RTX in a xenograft murine model. We first established a human NHL xenograft murine model that can consistently form CNS lymphomas with 2F7 cells, a cell line derived from AIDS-associated B-cell NHL (<NUM>). These 2F7 cells were marked with an mStrawberry reporter gene by a lentiviral vector. Individual sub-clones were tested for their ability to metastasize into the CNS. Two out of ten sub-lines formed CNS lymphomas within <NUM> weeks after intraperitoneal injection. Lymphoma cells were isolated from the brain of one of these sub-lines and re-adapted to cell culture. The resulting cell line, termed "2F7-BR44," forms lymphomas in CNS in <NUM>% of mice within <NUM> weeks following intraperitoneal injection or <NUM>-<NUM> weeks following tail vein injection of <NUM>×<NUM><NUM> cells (<FIG>). 2F7-BR44 cells maintain expression of four pan B cell markers (CD19, CD20, CD22, and CXCR5) at levels comparable to the parental 2F7 cells (<FIG>). The cells are sensitive to apoptosis mediated by RTX, comparable to the parental cell line, and also sensitive to complement in vitro (<FIG>).

Lymphoma burden and therapeutic efficacy were quantified by evaluating the percentage of mStrawberry+ 2F7-BR44 cells in different tissues. CNS metastases generally arise later than those in systemic organs; without treatment, animals usually die from systemic complications. Mice with lymphoma show apparent signs of lymphoma burden such as weight loss, pale skin, anemia, and decreased activity. Once the lymphoma burden in CNS increases up to ~<NUM>%, as quantified by the percentage of mStrawberry+ in single cell fraction obtained from whole brain tissues following perfusion, mice show hind leg paralysis. Native RTX treatment significantly extended survival of mice engrafted with 2F7-BR44 cells (<FIG>) and efficiently reduced lymphoma burden in bone marrow as well as to a lesser extent in spleen, but was ineffective in brain as well as lymph nodes (<FIG>).

We next compared the efficacy of native RTX versus n-RTX in controlling lymphoma formation in the brain. n-RTX improved the therapeutic efficacy of RTX against CNS metastasis in the NHL murine model; in contrast, untreated animals required euthanization at week <NUM>-<NUM> due to severe anemia (<FIG>). Treatment significantly improved mouse life span: native RTX treated mice survived up to week <NUM>, whereas half of the n-RTX treated mice showed no symptoms of lymphoma formation in brain until the end time points (week <NUM>). Both native RTX and n-RTX capably suppressed lymphoma formation in bone marrow. In contrast, n-RTX significantly reduced lymphoma burden in the brain, whereas native RTX had no effect despite effective systemic control (<FIG>). The correlation between controlled lymphoma growth and heightened RTX concentration illustrated by these results further demonstrates that RTX delivered via nanocapsules exerts control over CNS metastases.

Ligands can be readily conjugated to the surface of nanocapsules to redirect them to specific targets; thus, targeting nanocapsules to lymphoma cells is predicted to increase RTX concentrations at the site of the lymphoma, enhancing potency and specificity of activity. To demonstrate the potential of ligand-mediated lymphoma targeting, we selected CXCL13: a chemokine belonging to the CXC family that interacts with CXCR5, a receptor expressed on mature B cells (<NUM>,<NUM>), and is associated with NHLs of B cell origin (<NUM>-<NUM>). In malignancies, CXCL13 has suspected involvement in metastasis of lymphoma cells (<NUM>,<NUM>); therefore, to assure accurate modelling of the metastatic environment, we evaluated CXCR5 expression in 2F7-BR44 cells and confirmed that they showed a similar level of CXCR5 expression to that of parental 2F7 cells (<FIG>). We then conjugated CXCL13 to the surface of nanocapsules at a molar ratio of approximately <NUM>:<NUM> (<FIG>, n-RTXCXCL13). This conjugation did not induce significant change on either particle size or surface charge of n-RTX (<FIG> <FIG>).

To evaluate the binding of CXCL13-conjugated nanocapsules, EGFP was used as a model protein for nanocapsule synthesis with slowly hydrolysable GDMA crosslinkers under physiological conditions (n-EGFP(GDMA) and n-EGFP(GDMA)CXCL13). We found that CXCL13 conjugation improved the specific binding of nanocapsules on 2F7-BR44 cells (<FIG>, 2F7) while minimizing non-specific binding on non-targeted cells (<FIG>, Jurkat); this specific binding of n-EGFP(GDMA)CXCL13 on 2F7-BR44 cells was further confirmed by flow cytometry (<FIG>). Importantly, CXCL13 conjugation did not change the surface properties of MPC nanocapsules, maintaining resistance to cellular uptake. Similarly to n-RTX(GDMA), n-RTX(GDMA)CXCL13 bound to 2F7-BR44 cells but was not internalized (<FIG>). Biodistribution data showed that both n-RTX(GDMA) and n-RTX(GDMA)CXCL13 systemically distributed in mice (<FIG>), were delivered with uniform efficiency within the brain, and exhibited decreased accumulation in the liver, kidney, and lung-tissues known for showing non-specific accumulation of antibody (<FIG>,<FIG>).

We next demonstrated the enhanced effectiveness of n-RTX conjugated with CXCL13 (n-RTXCXCL13) in controlling lymphoma growth in a xenograft murine model. Compared to native RTX, there was significant improvement in the kinetics of RTX delivery released from both n-RTX and n-RTXCXCL13 into CSF and brain; minimal differences were noted between the two kinds of nanocapsules (<FIG>). Moreover, there were no obvious liver or kidney toxicities over <NUM> weeks of nanocapsule treatment (<FIG>). Importantly, compared to native RTX and n-RTX-treated animals, mice treated with n-RTXCXCL13 showed improved survival rate (<FIG>) and minimal CNS lymphoma formation until the end time points (<FIG>). Greater numbers of n-RTXCXCL13 were observed in areas of lymphoma growth (<FIG>), indicating that n-RTXCXCL13 preferentially locates with 2F7-BR44 lymphoma in the brain. Besides lymphomas in brain, renal lymphoma and intraocular lymphoma were also observed in this NHL murine model. Unlike native RTX treatment, intraocular lymphoma was prevented by treatment with n-RTX; however, nodules still formed on kidneys (<FIG>). n-RTXCXCL13 showed clear colocalization with 2F7-BR44 cells in the kidney (<FIG>) and exerted superior anti-lymphoma activity in both locations compared to native RTX or n-RTX (<FIG>).

To facilitate longitudinal analysis of lymphoma location and progression, the NHL mouse model was further adapted for optical imaging by marking 2F7-BR44 cells with a lentiviral vector expressing firefly luciferase (2F7-BR44-Luc). Following injection of D-luciferin, the substrate of luciferase, in vivo distributions and growth of 2F7-BR44-Luc cells were monitored by in vivo bioluminescence imaging over time (<FIG>). Bioluminescence imaging in the NHL xenograft murine model indicated that 2F7-BR44 cells initially migrated into the lungs after tail vein injection, followed by redistribution to CNS (brain and spinal cord) and bone marrow (BM) from sternum and femur within the first week. At week <NUM>, signal intensity from lymphomas in the brain, spinal cord, sternum, femur, and kidneys increased.

Based upon the kinetics of lymphoma formation, we conducted studies in which treatment was initiated after obvious lymphoma formation. Mice were treated with native RTX or n-RTXCXCL13 at different times: Week <NUM> (Group I) and Week <NUM> (Group II) post-injection of 2F7-BR44-Luc cells. Treatment by n-RTXCXCL13 in both groups resulted in significant control of lymphoma burden relative to native RTX treatment, measured by bioluminescence per a defined area (<FIG>). Survival of lymphoma-bearing mice was significantly extended for <NUM>-<NUM> weeks by n-RTXCXCL13 compared to native RTX in both Group I and II (<FIG>). To quantify the difference in therapeutic efficacy between native RTX and n-RTXCXCL13, bioluminescence intensity (BLI) from 2F7-BR44-Luc cells in the whole body was compared every week after treatment (<FIG>). In Group I, whole body therapeutic efficacy was similar in the first week post-treatment across both treatment types but was significantly improved by n-RTXCXCL13 later, suggesting more effective control of lymphoma burden by n-RTXCXCL13. In Group II, there was a significantly greater effect of n-RTXCXCL13 treatment, but less than in mice treated in Group I. To assess the impact upon CNS lymphomas, BLIs from the head area were quantified (<FIG>). Treatment with n-RTXCXCL13 notably slowed and controlled CNS lymphoma burden in both groups. In Group II, where lymphomas had already formed in CNS before treatment, all mice with n-RTXCXCL13 showed a decrease in lymphoma burden at <NUM> week following treatment.

The above NHL xenograft murine model uses immunodeficient mice in which the killing of 2F7-BR44-Luc cells is likely to be primarily, if not exclusively, by induction of apoptosis. RTX is known to induce anti-lymphoma killing through multiple mechanisms in addition to apoptosis, including ADCC and CDC (<NUM>). Thus, the efficacy of RTX against CNS lymphomas in the NHL xenograft model is highly limited (<NUM>). We further evaluated n-RTXCXCL13 in a humanized BLT (bone marrow/liver/thymus) murine model wherein human T cells, B cells, natural killer (NK) cells, and macrophages reconstitute; of these populations, both NK cells and macrophages can induce ADCC. Humanized BLT mice develop notably human NK and macrophage populations in tissues, including the brain (<NUM>-<NUM>). Consistent with a published study (<NUM>), we found substantial macrophage repopulation in the brains of these mice. Humanized BLT mice were treated with native RTX or n-RTXCXCL13 at week <NUM> post-injection of 2F7-BR44-Luc cells and monitored for lymphoma growth for <NUM> weeks while unrelated antibody Herceptin (anti-human epidermal growth factor receptor (HER) <NUM>) and n-HERCXCL13 were included as negative controls. Native RTX treatment showed effective therapeutic efficacy throughout the body except in brain, which resulted in paralysis on weeks <NUM>-<NUM>; additionally, neither native HER nor n-HERCXCL13 treatment showed any therapeutic effect (<FIG>). In contrast, n-RTXCXCL13 completely eliminated lymphomas in mice and initiated regression of CNS lymphomas, with no relapse observed even until the endpoint at week <NUM>. Survival of lymphoma-bearing mice was significantly extended by n-RTXCXCL13 treatment (<FIG>). The clearance of lymphomas was confirmed by flow cytometry of tissues (<FIG>).

We demonstrate that a single-course treatment of RTX encapsulated within an MPC-based nanocapsule designed to administer mAb by timed release results in CNS RTX concentrations up to <NUM>-fold higher than native antibody and yields detectable levels for at least <NUM> weeks in a murine model. Using an NHL xenograft murine model, better penetration into the CNS allows control of CNS lymphoma formation. Three basic components were tuned to increase anti-lymphoma effects of RTX: <NUM>) a polymer shell which allows longer systemic circulation and CNS penetration, <NUM>) crosslinkers which stabilize the polymer shell and release mAb through timed hydrolysis, and <NUM>) CXCL13 conjugated to the surface enabling targeting to CXCR5-expressing lymphoma cells. CNS penetration of the nanocapsules appears to be mediated by binding of choline and acetylcholine analogues of the nanocapsule polymer shell to choline transporters and acetylcholine receptors.

Enhanced RTX levels in the CNS could act to control local lymphoma growth through various effector mechanisms. Both CDC and ADCC function in the CNS (<NUM>-<NUM>), but are likely limited due to low antibody levels. In the NSG xenograft murine model, induction of apoptosis is likely to be the major mechanism for lymphoma cell elimination since complement components are absent, and it is unclear whether murine microglia may contribute to ADCC activity (<NUM>). With limited effector functions, only partial control was achieved in xenografted NSG mice. By repeating studies in humanized BLT mice wherein human macrophages and NK cells differentiate, we demonstrated complete elimination of lymphomas both systemically and in the CNS. We suspect that the differences between these two murine models exist due to the presence of ADCC in the humanized BLT mice, which is absent in the standard xenograft model using NSG mice. Future studies will better elucidate the mechanisms responsible for lymphoma control and clearance.

The results of these studies are applicable to other therapeutic mAbs wherein CNS penetration is limited. For example, breast cancer patients controlled systemically by Herceptin often relapse with CNS metastases that are resistant to mAb therapy (<NUM>,<NUM>). By bypassing the BBB through intrathecal or intraventricular administration, mAb therapy for lymphoma and breast cancer has shown some effectiveness against CNS metastases (<NUM>,<NUM>). Our results provide a potential non-invasive alternative treatment of CNS lymphomas as well as prophylactic use of the nanocapsule against CNS metastases. Since the biodistribution properties of the mAb are conferred by the nanocapsule, not cargo, any mAb (or protein) can be readily substituted. Anti-phosphorylcholine autoantibodies have been reported in mice (<NUM>) and humans (<NUM>), and could potentially affect in vivo dynamics of nanocapsules generated with MPC, though we do not observe more rapid clearance relative to native mAb. We anticipate that further studies on biodistribution and optimization of formulations through engineering design of polymers, crosslinkers, and targeting ligands will further improve CNS delivery and therapeutic efficacy for CNS diseases.

Synthesis of nanocapsules. Nanocapsules were synthesized with optimized modication for antibodies based on our previous reports (<NUM>). Proteins (RTX or EGFP) were encapsulated via in situ polymerization at room temperature using MPC as the monomer, PLA-PEG-PLA and/or GDMA as the crosslinker, and ammonium persulfate and tetramethylethylenediamine as the initiator. Synthesized nanocapsules were dialyzed against PBS, and purified by passing through a hydrophobic interaction column (Phenyl-Sepharose 4BCL).

Biodistribution studies. Biodistribution of native RTX and n-RTX was determined by monitoring the free RTX concentration in animal body fluids and perfused tissue homogenates. Briefly, C57BL/<NUM> mice were randomly divided into two groups and retro-orbitally injected at a doseage of <NUM>/kg/mouse, which dose has been reported to be effective in an NHL xenograft murine model (<NUM>). CSF was collected from a mouse under anesthesia by Ketamine and Xylazine (<NUM>/kg each). After CSF collection, this mouse was perfused with cold phosphate-buffered saline (PBS), euthanized, and organs were harvested. All perfused tissues were homogenized by vortexing with ceramic beads in PBS containing protease inhibitor cocktail.

Non-Hodgkin Lymphoma (NHL) mouse model with CNS metastases. Animal research described in the study was conducted under UCLA's Chancellor's Animal Research Committee (Institutional Animal Care and Use Committee [IACUC]) in accordance with guidelines for housing and care of laboratory animals of the National Institutes of Health (NIH) and the Association for the Assessment and Accreditation of Laboratory Animal Care (A ALAC) International 2F7 cells were first marked with a fluorescent reporter gene by a lentiviral vector expressing mStrawberry. The 2F7 cells were then sub-cloned and tested individually for ability to metastasize into CNS. We selected clone <NUM> out of <NUM> clones, which showed a stable brain metastatic ability. An NSG mouse received <NUM>×<NUM><NUM> mStrawberry+ 2F7 clone <NUM> cells via intraperitoneal injection and showed brain metastasis <NUM> weeks post-injection (see <FIG>). Lymphoma cells were isolated from the brain metastatic site and adapted to cell culture to establish the 2F7-BR44 cell line. <NUM>×<NUM><NUM> of 2F7-BR44 cells were injected into NSG mice via lateral tail vein to establish an NHL xenograft murine model with CNS metastases.

MAb detection by ELISA. The concentration of RTX in animal body fluids (CSF and plasma) and tissue homogenates was measured by ELISA against RTX. <NUM>-well plates were coated with <NUM>µg/mL of anti-RTX antibody (diluted in sodium carbonate-bicarbonate buffer), followed by blocking with <NUM>% BSA/PBS for <NUM> hours at room temperature. Diluted RTX in PBST (<NUM>% Tween/PBS) from <NUM> to <NUM> ng/mL were then added and incubated for an hour at room temperature to obtain calibration curves. Animal body fluids and tissue homogenates containing encapsulated RTX in non-degradable nanocapsules were treated with <NUM> sodium acetate buffer (pH <NUM>) at <NUM> overnight, then used for ELISA measurement. Free RTX released from n-RTX was directly measured with animal body fluids and tissue homogenates. All animal samples were added to the well and incubated for an hour at room temperature. After five-times wash with PBST, peroxidase-conjugated anti-human Fc antibody was added and incubated for an additional hour at room temperature. The substrate <NUM>,<NUM>',<NUM>,<NUM>'-Tetramethylbenzidine (TMB) solution was added and incubated until the appropriate color had developed. The reaction was stopped and absorbance at <NUM> was measured with a microplate reader.

Anti-lymphoma efficacy of RTX in the NHL xenograft murine model with CNS metastases. 2F7-BR44 cells (<NUM>×<NUM><NUM>/animal) were injected into NSG mice via tail vein. Five days after 2F7-BR44 cell injection unless otherwise stated, mice were treated with a single course of native RTX, n-RTX or n-RTX conjugated with CXCL13 (n-RTXCXCL13) via retro-orbital vein injection (<NUM>/kg/day for <NUM> days). Mice were sacrificed when in critical condition due to lymphoma burden or at the end time points decided in experiment design. The mice were perfused with cold PBS, euthanized, and organs were harvested for single-cell isolation from tissues. Cells from target tissues were stained with anti-human CD45 and CD19, then analyzed by flow cytometry.

In vivo imaging to monitor lymphoma progression. 2F7-BR44 cells were gene marked with a lentiviral vector expressing firefly luciferase, then luciferase-expressing cells were selected by a week of Zeocin treatment (<NUM>µg/ml) (2F7-BR44-Luc). 2F7-BR44-Luc cells (<NUM>×<NUM><NUM>/animal) were injected into NSG mice or BLT humanized mice via tail vein. Humanized mice were prepared as previously described with modifications (<NUM>-<NUM>). Six-week-old NSG mice were administered Busulfan (<NUM>/kg) intraperitoneally. Twenty-four hours later, the mice were implanted with a portion of human fetal thymus combined with fetal liver derived CD34+ cells solidified in Matrigel under the kidney capsule and also via retro-orbital vein injection. After the human blood cell reconstitution in peripheral blood, 2F7-BR44 cells (<NUM>×<NUM><NUM>/animal) were injected into humanized BLT mice via tail vein to establish xenograft humanized BLT mice. Lymphoma formation was monitored by in vivo bioimaging using the IVIS Lumina II in vivo imaging system (PerkinElmer, Waltham, MA). In vivo bioluminescence imaging was performed following subcutaneous injection of <NUM> D-luciferin (Pierce, Woodland Hills, CA). Mice were imaged at the signal plateau (<NUM> minutes post-D-luciferin injection) under isoflurane anesthesia. Lymphoma burden was quantified as the total photon flux per second within a region of interest (ROI) (whole body or head area) of the mouse; the ROIs were identically sized for all measurements. Sensitivity settings were adjusted at each time point to maintain <NUM>-<NUM> counts per pixel for humanized mice and <NUM>-<NUM> counts per pixel for NSG mice.

Statistical analyses. Results are expressed as mean ± standard deviation (SD). Errors depict SD. Data were analysed by Student's t-test and one way analysis of variance (ANOVA) using the GraphPad Prism (La Jolla, CA). The significance of survival curve was compared with a log-rank (Mantel-Cox) test. P-value was shown in GP style. *: P values <<NUM>; **: P values <<NUM>;***: P values <<NUM>;****: P values <<NUM>.

All chemicals were purchased from Sigma-Aldrich (St. Louis, MO) unless otherwise noted. All cell culture reagents were purchased from ThermoFisher Scientific (Waltham, MA) unless otherwise noted. Hydrolysable crosslinker Poly(DL-lactide)-b-Poly(ethylene glycol)-b-Poly(DL-lactide)-diacrylate triblock (PLA-PEG-PLA) was purchased from PolySciTech Akina, Inc (West Lafeyette, IN). NHS-PEG4-Azide was purchased from ThermoFisher Scientific. Mono-sulfo-N-hydroxy-succinimido nanogold labeling reagent (#<NUM>) and the GoldENhance™ EM kit (#<NUM>) were purchased from Nanoprobes (Yaphank, NY). Capture antibody for ELISA against rituximab (RTX) was purchased from Bio-Rad Laboratories (MCA2260, Hercules, CA). HRP-conjugated goat anti-human IgG Fc for ELISA assay was purchased from ThermoFisher Scientific. Anti-human CD19, anti-human CD20, anti-human CD22, anti-human CD185 (CXCR5), and recombinant CXCL13 were purchased from BioLegend (San Diego, CA). RTX (RITUXAN™: Genentech, San Francisco, CA) and HER (Herceptin®: Genentech) were obtained at the UCLA hospital pharmacy. Anti-glial fibrillary acidic protein (GFAP) (clone GA-<NUM>) and anti-ionized calcium binding adaptor molecule <NUM> (Iba1) (MABN92) antibodies were obtained from Biocare Medical (Pacheco, CA) and EMD Millipore (Darmstadt, Germany), respectively. Anti-Ku80 antibody (clone C48E7, Cell Signaling Technology, Danvers, MA) and rhodamine red-X anti-rabbit IgG (Jackson ImmunoResearch, West Grove, PA) were used for detection of 2F7-BR44 cells in the brain. <NUM>-diamidino-<NUM>-phenylindole (DAPI) was purchased from Invitrogen. Antifade mounting media was obtained from Vector laboratories (Burlingame, CA). Mouse aspartate aminotransferase (AST) ELISA kit and mouse alanine transaminase (ALT) ELISA kit were purchased from G-Biosciences (St. Louis, MO), and urea nitrogen (BUN) colorimetric detection kit was purchased from Arbor Assays (Ann Arbor, MI). Matrigel was purchased from BD Biosciences (San Jose, CA).

Instruments. TEM images of nanocapsules were obtained on a Philips EM120 TEM (Amsterdam, Netherlands) at 100000x. Fluorescent images of cells were obtained with a Revolve R4 fluorescent microscope, Discover Echo Inc (San Diego, CA). Fluorescent images of brain tissue and tissue sections were obtained with the Maestro™ In-Vivo fluorescence imaging system, CRi, Inc (Dallas, TX) and Leica DMi8 inverted microscope (Buffalo Grove, IL), respectively. Optical images and bioluminescence were collected on IVIS Lumina II In vivo imaging system (PerkinElmer, Inc, Waltham, MA). Cell numbers were acquired via either manual counting with trypan blue dye exclusion under microscope or with the MACSQuant® Analyzer <NUM> (Miltenyi Biotech, Bergisch Gladbach, Germany). Expression of mStrawberry and cell surface markers were analyzed by BD LSRFortessa (BD Biosciences). UV/VIS spectra were acquired with a GeneSys <NUM> spectrometer (ThermoFisher Scientific). UV/VIS absorbance was measured by NanoDrop One spectrophotometer (ThermoFisher Scientific). The detection of ELISA was acquired by use of the VersaMax™ Tunable microplate reader (Molecular Devices, San Jose, CA). Dynamic light scattering (DLS) studies of native proteins and nanocapsules were obtained by Zetasizer Nano instrument (Malvern Instruments Ltd. , Kingdom).

Synthesis of RTX nanocapsules. RTX nanocapsule with mixed crosslinkers of glycerol dimethacrylate (GDMA) and PLA-PEG-PLA at a <NUM>:<NUM> molar ratio (n-RTX) as well as RTX nanocapsules with GDMA (n-RTX(GDMA)) were synthesized with optimized modification for antibodies based on our previous reports (<NUM>). The n-RTX were synthesized using a volume of <NUM> RTX at <NUM>/mL, a specific amount of <NUM>-methacryloyloxyethyl phosphorylcholine (MPC, <NUM>% m/v in PBS), PLA-PEG-PLA (<NUM>% m/v in PBS) and GDMA (<NUM>% m/v in DMSO) in a molar ratio of RTX:MPC:PLA-PEG-PLA:GDMA=<NUM>:<NUM>:<NUM>:<NUM>. The n-RTX(GDMA) were synthesized using the same amount of RTX, MPC (<NUM>% m/v in PBS) and GDMA (<NUM>% m/v in DMSO) at a molar ratio of RTX:MPC:GDMA=<NUM>:<NUM>:<NUM>. Radical polymerization from the surface of the protein was then initiated by adding ammonium persulfate (<NUM>% m/v in PBS, molar ratio to RTX=<NUM>:<NUM>) and N,N,N',N'-tetramethylethylenediamine (TEMED, molar ratio to RTX=<NUM>:<NUM>) into the reaction vial and kept in ice bath for <NUM> hours. Finally, dialysis was used to remove extra free monomers and initiators. The free RTX was removed using hydrophobic interaction chromatography (Phenyl Sepharose CL-4B; Sigma Aldrich) as described previously (<NUM>).

Synthesis of nanogold-labeled n-RTX(GDMA). Native RTX (<NUM>/mL in PBS) was reacted with mono-sulfo- N-hydroxy-succinimido-nanogold at a <NUM>:<NUM> molar ratio in ice bath for <NUM> hour as published previously (<NUM>). Excess nanogold was removed by size-exclusion spin columns. The concentration of nanogold on each protein was determined by the UV/VIS spectrum at <NUM> (the extinction coefficient ε420=<NUM>,<NUM>-<NUM>cm-<NUM>) as <NUM> nanogolds per RTX. The nanogold-labeled RTX was then used for nanocapsule synthesis as described above.

Preparation of nanocapsules conjugated with CXCL13 ligands. CXCL13 ligands were conjugated on nanocapsules through copper-free click chemistry <NUM> Dibenzocyclooctyne-S-S-N-hydroxysuccinimidyl ester (DBCO-SS-NHS) in DMSO (<NUM>/ml) was added into nanocapsule solution at a <NUM>:<NUM> molar ratio. NHS-PEG4-Azide in DMSO (<NUM>/ml) was added into CXCL13 solution at a <NUM>:<NUM> molar ratio. Both reactions were processed in an ice bath for <NUM> hour. Free reagents were removed by size-exclusion spin columns. The conjugation between DBCO-modified nanocapsules and azide-modified CXCL13 was reacted at <NUM> for <NUM> hours at a <NUM>:<NUM> molar ratio.

Determination of the average number of CXCL13 in n-RTXCXCL13. The average number of CXCL13 on each n-RTXCXCL13 was assessed by quantifying the amount of reacted DBCO after CXCL13 conjugation. The numbers of DBCO in DBCO-modified nanocapsules and CXCL13 conjugated nanocapsules were determined by the adsorption at <NUM> based on the Beer-Lambert law as
<MAT>
wherein A309 is the absorbance of DBCO-modified nanocapsules at <NUM>; ε309 represents the extinction coefficient of DBCO at <NUM> (ε309= <NUM>,<NUM>-<NUM>cm-<NUM>). Protein concentration assay. Protein content in the form of nanocapsules was determined by bicinchoninic acid (BCA) colorimetric protein assay. Briefly, a tartrate buffer (pH11. <NUM>) containing <NUM> BCA, <NUM> CuSO<NUM>, and protein/nanocapsule samples was incubated at <NUM> for <NUM> minutes. After the reaction was cooled to room temperature, the absorbance reading at <NUM> was determined with a UV/Vis spectrometer. BSA was used as a standard.

TEM and DLS measurements of the nanocapsules. For TEM imaging of n-RTX, <NUM>µL of an n-RTX(GDMA) solution (<NUM>/mL) was dropped onto a carbon-coated copper grid and removed after a <NUM> second incubation. The grid was rinsed with water three times and stained with <NUM>% uranyl acetate solution. For TEM imaging of nanogold-labeled n-RTX(GDMA), the signal of nanogolds was enhanced by the GoldENhance™ EM kit. The size and zeta potential of the nanocapsules were measured by DLS under the concentration of <NUM>/mL.

Cell culture. 2F7 cells were transduced with a lentiviral vector encoding mStrawberry under ubiquitin C promoter. Transduced 2F7 cells were flow sorted for mStrawberry expression and sub-cloned to obtain single cell clones. After in vivo selection for brain lymphoma formation, 2F7-BR44 cells were used for all in vitro and in vivo experiments. Jurkat, a T cell line, was marked with a lentiviral vector encoding blue fluorescent protein (BFP). Parental 2F7, 2F7-BR44, and Jurkat cells were cultured in Iscove's Modified Dulbecco's (IMDM) supplemented with <NUM>% fetal bovine serum, <NUM>% GlutaMax and <NUM>% Antibiotic-Antimycotic. 2F7-BR44-Luc cells were established by transducing a lentiviral vector encoding firefly luciferase together with the bleomycin-resistant gene under elongation factor-<NUM>α promoter and selection in <NUM>µg/ml of Zeocin.

Cytotoxicity assay. Anti-lymphoma activity of RTX on parental 2F7 cells and 2F7-BR44 cells was assessed by absolute cell number counting using MACSQuant® Analyzer <NUM>. For the apoptosis test, parental 2F7 cells and 2F7-BR44 were cultured in <NUM>-well plates (<NUM>×<NUM><NUM>/mL) for <NUM> hours in the presence of RTX (<NUM>µg/mL). Same volumes of cell culture were taken to obtain absolute cell numbers on MACSQuant® Analyzer <NUM>. For complement-dependent cytotoxicity (CDC) testing, parental 2F7 cells and 2F7-BR44 cells were cultured in <NUM>-well plates (<NUM>×<NUM><NUM>/mL) for <NUM> hours in the presence of RTX (<NUM>µg/mL) and <NUM>% human serum with no heat inactivation. Cell death percentages were calculated as cell death (%) = <NUM> × (<NUM>-(cell number after RTX treatment/control without RTX)).

Cell surface marker staining. Same cell counts of parental 2F7 cells and 2F7-BR44 cells were taken and washed by <NUM>% fetal bovine serum/PBS. Four antibodies specific for B cell surface markers-CD19, CD20, CD22, and CXCR5-were added and stained at <NUM> for <NUM> minutes. Expression levels were assessed by BD LSRFortessa after fixation with <NUM>% formaldehyde in PBS.

Immunohistochemical (IHC) analyses. Mouse brain was embedded in paraffin, sectioned at the coronal plane with <NUM> thickness, and Nissl bodies were stained with Cresyl Violet Nissl stain dye by the UCLA Translational Pathology Core Laboratory (TPCL). Slides were further stained with primary anti-human CD20 antibody, followed by HRP-labeled secondary antibody, then incubated with ABC-peroxidase and diaminobenzidine (DAB). Levels of brain damage were evaluated by elevation of two brain damage markers: GFAP for astrocytes, and Iba1 for microglia and macrophages. Sprague Dawley rats were treated with native RTX or n-RTX (<NUM>/kg) and brain tissues were processed for IHC analysis as described above.

The biodistribution of native RTX, n-RTX(GDMA), and n-RTX(GDMA)CXCL13 in mouse brain and kidney tissues was analyzed by light microscopy. Nanogold-labeled RTX, n-RTX(GDMA), and n-RTX(GDMA)CXCL13 were synthesized and purified with the protocol described above and administrated to mice (<NUM>/kg). At day <NUM> post-administration, mice were perfused with PBS to wash out body fluids and blood cells, followed by perfusion with <NUM>% paraformaldehyde for fixation. Brain and kidney tissues were then harvested and embedded in paraffin. Tissue sections of the coronal plane were prepared and signals of nanogold were enhanced by the GoldENhance™ EM kit. 2F7-BR44 lymphoma cells in the brain were visualized by anti-Ku80 staining. Images were taken by Leica DMi8 inverted microscope. Expression levels of each antigen were quantified from three randomly selected slides of each sample with Software ImageJ.

Specific binding of CXCL13 conjugated nanocapsules on 2F7-BR44 cells. 2F7-BR44 cells (mStrawberry+, <NUM>×<NUM><NUM> cells) and Jurkat T cells (BFP+, <NUM>×<NUM><NUM> cells) were mixed and suspended in <NUM> Opti-MEM medium with <NUM>% fetal bovine serum. EGFP encapsulated with slow-hydrolysable nanocapsule (n-EGFP(GDMA)) or CXCL13 conjugated n-EGFP(GDMA) (n-EGFP(GDMA)CXCL13) were added to culture at a final concentration of <NUM>/mL and mixed thoroughly. After incubation at <NUM> for <NUM> hour, cells were washed three times with PBS then resuspended in <NUM> for flow cytometer analysis. For fluorescent microscopic analysis, cells were transferred to Poly-D-Lysine-coated <NUM> well chambers. The slide was then mounted by a coverslip with aqueous mounting medium and analyzed using a Leica DMi8 inverted fluorescence microscope. All cells were fixed with <NUM>% formaldehyde in PBS for <NUM> minutes at room temperature before analysis.

Fluorescence imaging of nanocapsule internalization. 2F7-BR44 cells (mStrawberry+, <NUM>×<NUM><NUM> cells) were incubated with FITC-labeled native CXCL13, n-RTX(GDMA), and n-RTX(GDMA)CXCL13 (<NUM>/mL) at both <NUM> and <NUM> for <NUM> hours. Cells were then washed with PBS three times and visualized with a fluorescent microscope. To quench the fluorescent signal of FITC on the cell surface, cells were mixed with <NUM>% trypan blue/PBS with a volume ratio of <NUM>:<NUM> before taking images.

Biodistribution of the nanocapsules. The biodistributions of native RTX, n-RTX(GDMA), and n-RTX(GDMA)CXCL13 were analyzed by optical imaging. Native RTX, n-RTX(GDMA), and n-RTX(GDMA)CXCL13 were fluorescently labeled with carboxytetramethylrhodamine (TAMRA) and administrated to mice (<NUM>/kg). In vivo fluorescence imaging was performed at <NUM> day post-administration (Ex. =<NUM>, Em. =<NUM>) by IVIS Lumina II In vivo imaging system. The main organs, including brain, heart, liver, spleen, kidneys and lung, were harvested following perfusion with PBS for ex vivo optical imaging.

Claim 1:
A composition of matter comprising:
an antibody;
a polymeric network formed from <NUM>-methacryloyloxyethyl phosphorylcholine and configured to form a nanocapsule that encapsulates the antibody;
a hydrolysable crosslinking moiety comprising a glycerol dimethacrylate and/or a Poly(DL-lactide)-b-Poly(ethylene glycol)-b-Poly(DL-lactide)-diacrylate triblock copolymer coupled to polymers forming the polymeric network; and
a targeting agent comprising CXCL13 coupled to the polymeric network;
wherein:
the nanocapsule is formed in situ on the antibody;
constituents and ratios of the antibody, the polymeric network, the hydrolysable crosslinking moiety and the targeting agent are disposed in a three-dimensional architecture so that:
the nanocapsule crosses blood brain barriers to deliver nanocapsules in a bloodstream into a central nervous system such that at least <NUM> fold more antibody that is disposed in the nanocapsule crosses blood brain barriers as compared with the antibody in the absence of the nanocapsule; and
the hydrolysable crosslinking moiety is cleaved in the central nervous system so as to release the antibody from the nanocapsule.