Abstract: A series of pharmaceutical metal complexes (pMCs) were produced and characterized using the mast cell stabilizer, cromolyn, and bioactive metal ions (Zn+2, Mg+2, and Ca+2). Three novel pMCs, Cromolyn-Zn, Cromolyn-Mg, and Cromolyn-Ca were formed through reactions under controlled temperature and pH conditions. TGA demonstrated that these metal complexes showed an enhanced thermal stability due to the strong coordination with the ligand, cromolyn. PXRD data indicates a high degree of crystallinity as well as a unique packing arrangement for each pMCs. SEM analysis showed materials with well-defined morphologies while EDS presented elemental evidence for the unique composition of each pMCs. The crystal structure for these materials was elucidated through SCXRD, and a variety of binding modes and packing motifs were found within each respective metal complex. Only 2D structures were achieved under the conditions studied.

Abstract: A series of pharmaceutical metal complexes (pMCs) were produced and characterized using the mast cell stabilizer, cromolyn, and bioactive metal ions (Zn+2, Mg+2, and Ca+2). Three novel pMCs, Cromolyn-Zn, Cromolyn-Mg, and Cromolyn-Ca were formed through reactions under controlled temperature and pH conditions. TGA demonstrated that these metal complexes showed an enhanced thermal stability due to the strong coordination with the ligand, cromolyn. PXRD data indicates a high degree of crystallinity as well as a unique packing arrangement for each pMCs. SEM analysis showed materials with well-defined morphologies while EDS presented elemental evidence for the unique composition of each pMCs. The crystal structure for these materials was elucidated through SCXRD, and a variety of binding modes and packing motifs were found within each respective metal complex. Only 2D structures were achieved under the conditions studied.

Abstract: Disclosed herein are crystalline forms of compounds for the inhibition of RhoGTPase. Also disclosed herein are compounds, pharmaceutical compositions, and methods of treatment of RhoGTPase-mediated diseases, such as hyperproliferative and neoplastic diseases.

Abstract: The invention provides extended bisphosphonate-based metal complexes using benzene1,4-bis(bisphosphonic acid) (BBPA), an analog of benzene 1,4-dicarboxylic acid (BDC). Hydrothermal synthesis of BBPA with the bioactive metals Ca2+, Zn2+, and Mg2+ leads to four crystals phases, namely, BBPA-Ca forms I and II, BBPA-Zn form I, and BBPA-Mg form I. Out of the three structures, BBPA-Ca form II presents large channels (8 ?×12 ?), potentiating the use of this framework to load drugs. Cytotoxicity effects of BBPA was elucidated in a human breast cancer MDA-MB-231 and a normal osteoblast hFOB 1.19 cell lines. The half-maximal inhibitory concentration (IC50) for BBPA used to treat both cell lines were >200 ?M at 24, 48, and 72 h of treatment. The BBPA in the range of concentration employed (0-200 ?M) was not cytotoxic against these cell lines.

Abstract: A series of pharmaceutical metal complexes (pMCs) were produced and characterized using the mast cell stabilizer, cromolyn, and bioactive metal ions (Zn+2, Mg+2, and Ca+2). Three novel pMCs, Cromolyn-Zn, Cromolyn-Mg, and Cromolyn-Ca were formed through reactions under controlled temperature and pH conditions. TGA demonstrated that these metal complexes showed an enhanced thermal stability due to the strong coordination with the ligand, cromolyn. PXRD data indicates a high degree of crystallinity as well as a unique packing arrangement for each pMCs. SEM analysis showed materials with well-defined morphologies while EDS presented elemental evidence for the unique composition of each pMCs. The crystal structure for these materials was elucidated through SCXRD, and a variety of binding modes and packing motifs were found within each respective metal complex. Only 2D structures were achieved under the conditions studied.

Abstract: The invention provides extended bisphosphonate-based metal complexes using benzene1,4-bis(bisphosphonic acid) (BBPA), an analog of benzene 1,4-dicarboxylic acid (BDC). Hydrothermal synthesis of BBPA with the bioactive metals Ca2+, Zn2+, and Mg2+ leads to four crystals phases, namely, BBPA-Ca forms I and II, BBPA-Zn form I, and BBPA-Mg form I. Out of the three structures, BBPA-Ca form II presents large channels (8 ?×12 ?), potentiating the use of this framework to load drugs. Dissolution profiles were conducted to investigate the release of BBPA from BBPA-based metal complexes under physiological conditions (phosphate-buffered saline, PBS). These results show that <50% of BBPA was released from the BBPA-based metal complexes after 72 h. Binding assays employing hydroxyapatite (HA) were conducted to explore the affinity of BBPA to the bone microenvironment. About 99% of the BBPA could bind to HA in 10 days, revealing that BBPA is capable of binding to the bone.

Abstract: The hydrothermal reaction between bioactive metals (Ca2+, Zn2+, and Mg2+) salts and clinically utilized bisphosphonate (BP) alendronic acid (ALEN) were performed to prepare several bisphosphonate-based biocompatible coordination complexes (pBioCCs). The invention describes the effect of three variables M2+/BP molar ratio, reaction temperature, and pH on the reaction outcomes yields an unprecedented number of crystalline materials of enough crystal quality for structural elucidation. The crystal structure was unveiled by single crystal X-ray diffraction at 100 K and their solid-state properties revealed in tandem with other characterization techniques: thermogravimetry, vibrational spectroscopy, and elemental analysis. The invention provides materials with high structural stability and dissolution properties paving the way for better formulation strategies for alendronic acid (ALEN) through the design of pBioCCs for the treatment of bone-related diseases.

Abstract: Compositions, methods, and systems for controlling crystallization of an agent are generally described. In some embodiments, an agent is crystallized in the presence of polymer matrices, such as polymer particles. The polymer matrix may influence at least a portion of the crystallization process and/or the resulting composition. In some such embodiments, the polymer matrix allows one or more aspect of the process and/or composition to be controlled and/or altered. For instance, the polymer matrix may act as a crystallization promoter and/or acceptable carriers of the crystallized agent. In certain embodiments, the polymer matrix described herein, can be used with any agent regardless of its chemical and/or physical properties.