In vitro assessment of inflammatory skin potential of poly(methyl methacrylate) at non-cytotoxic concentrations.

Poly(methyl methacrylate) (PMMA) is considered an attractive substrate material for fabricating wearable skin sensors such as fitness bands and microfluidic devices. Despite its widespread use, inflammatory and allergic responses have been attributed to the use of this material. Therefore, the main objective of this study was to obtain a comprehensive understanding of potential biological effects triggered by PMMA at non-cytotoxic concentrations using in vitro models of NIH3T3 fibroblasts and reconstructed human epidermis (RhE). It was hypothesized that concentrations that do not reduce cell viability are sufficient to activate pathways of inflammatory processes in the skin. The study included cytotoxicity, cell metabolism, cytokine quantification, histopathological, and gene expression analyses. The NIH3T3 cell line was used as a testbed for screening cell toxicity levels associated with the concentration of PMMA with different molecular weights (MWs) (i.e., MW ~5,000 and ~15,000 g/mol). The lower MW of PMMA had a half-maximal inhibitory concentration (IC50 ) value of 5.7 mg/cm2 , indicating greater detrimental effects than the higher MW (IC50 = 14.0 mg/cm2 ). Non-cytotoxic concentrations of 3.0 mg/cm2 for MW ~15,000 g/mol and 0.9 mg/cm2 for MW ~5,000 g/mol) induced negative metabolic changes in NIH3T3 cells. Cell viability was severely reduced to 7% after the exposure to degradation by-products generated after thermal and photodegradation degradation of PMMA. PMMA at non-cytotoxic concentrations still induced overexpression of pro-inflammatory cytokines, chemokines, and growth factors (IL1B, CXCL10, CCL5, IL1R1, IL7, IL17A, VEGFA, FGF2, IFNG, IL15) on the RhE model. The inflammatory response was also supported by histopathological and gene expression analyses of PMMA-treated RhE, indicating tissue damage and gene overexpression. Results suggested that non-cytotoxic concentrations of PMMA (3.0 to 5.6 mg/cm2 for MW ~15,000 g/mol and 0.9 to 2.1 mg/cm2 for MW ~5,000 g/mol) were sufficient to negatively alter NIH3T3 cells metabolism and activate inflammatory events in the RhE skin.

High-Affinity Extended Bisphosphonate-Based Coordination Polymers as Promising Candidates for Bone-Targeted Drug Delivery.

Extended bisphosphonate-based coordination polymers (BPCPs) were produced when 1,1'-biphenyl-4,4'-bisphosphonic acid (BPBPA), the analogue of 1,1'-biphenyl-4,4'-dicarboxylic acid (BPDC), reacted with bioactive metals (Ca2+, Zn2+, and Mg2+). BPBPA-Ca (11 Å × 12 Å), BPBPA-Zn (10 Å × 13 Å), and BPBPA-Mg (8 Å × 11 Å) possess channels that allow the encapsulation of letrozole (LET), an antineoplastic drug that combined with BPs treats breast-cancer-induced osteolytic metastases (OM). Dissolution curves obtained in phosphate-buffered saline (PBS) and fasted-state simulated gastric fluid (FaSSGF) demonstrate the pH-dependent degradation of BPCPs. Specifically, the results show that the structure of BPBPA-Ca is preserved in PBS (∼10% release of BPBPA) and collapses in FaSSGF. Moreover, the phase inversion temperature nanoemulsion method yielded nano-Ca@BPBPA (∼160 d. nm), a material with measurably higher (>1.5x) binding to hydroxyapatite than commercial BPs. Furthermore, it was found that the amounts of LET encapsulated and released (∼20 wt %) from BPBPA-Ca and nano-Ca@BPBPA are comparable to those of BPDC-based CPs [i.e., UiO-67-(NH2)2, BPDC-Zr, and bio-MOF-1], where other antineoplastic drugs have been loaded and released under similar conditions. Cell viability assays show that, at 12.5 µM, the drug-loaded nano-Ca@BPBPA exhibits higher cytotoxicity against breast cancer cells MCF-7 and MDA-MB-231 [relative cell viability (%RCV) = 20 ± 1 and 45 ± 4%] compared with LET (%RCV = 70 ± 1 and 99 ± 1%). At this concentration, no significant cytotoxicity was found for the hFOB 1.19 cells treated with drug-loaded nano-Ca@BPBPA and LET (%RCV = 100 ± 1%). Collectively, these results demonstrate the potential of nano-Ca@BPCPs as promising drug-delivery systems to treat OM or other bone-related diseases because these present measurably higher affinity, allowing bone-targeted drug delivery under acidic environments and effecting cytotoxicity on estrogen receptor-positive and triple-negative breast cancer cell lines known to induce bone metastases, without significantly affecting normal osteoblasts at the metastatic site.

Design of Extended Bisphosphonate-Based Coordination Polymers as Bone-Targeted Drug Delivery Systems for Breast Cancer-Induced Osteolytic Metastasis and Other Bone Therapies.

The coordination between benzene 1,4-bis(bisphosphonic acid) (BBPA), the bisphosphonate (BP) analogue of benzene 1,4-dicarboxylic acid (BDC), and bioactive metals led to the formation of extended bisphosphonate-based coordination polymers (BPCPs). Four distinct crystalline phases were obtained, namely, BBPA-Ca forms I and II, BBPA-Zn, and BBPA-Mg. Among these, BBPA-Ca forms I (7 × 9 Å2) and II (8 × 12 Å2) possess channels large enough to encapsulate 5-fluorouracil (5-FU), a drug prescribed in combination with BPs to treat breast cancer-induced osteolytic metastases (OM). Dissolution curves show a 14% release of BBPA from BBPA-Ca form II in phosphate-buffered saline, while ∼90% was released in fasted-state simulated gastric fluid. These results suggest that this material is relatively stable in neutral environments yet collapses in acidic conditions. Moreover, the phase inversion temperature method decreased the particle size of BBPA-Ca form II, resulting in nano-Ca@BBPA (∼134 d.nm). Binding assays showed a higher affinity of nano-Ca@BBPA (∼97%) to hydroxyapatite than BBPA (∼70%) and significantly higher binding than commercial BPs, zolendronic (3.0×), and risedronic (2.4×) acids after 24 h. Furthermore, both BBPA-Ca form II and nano-Ca@BBPA presented comparable drug loading and release (∼30 wt % 5-FU) relative to BDC-based CCs (UiO-66, MIL-53, and BDC-Zr) where other pharmaceutical compounds (caffeine, ibuprofen, aspirin, and α-cyano-4-hydroxycinnamic acid) have been encapsulated. Cell viability assays established that drug-loaded nano-Ca@BBPA increases the cytotoxicity of a triple-negative human breast cancer cell line (MDA-MB-231) when compared to 5-FU (%RCV = 8 ± 5 vs 75 ± 1% at a 100 µM). At the same concentration, no significant decrease in cell viability was observed for normal human osteoblast-like hFOB 1.19 cells (%RCV = 85 ± 1%). Collectively, these results demonstrate the feasibility of nano-Ca@BBPA as a potential drug delivery system (DDS), with high affinity to bone tissue, to treat bone-related diseases such as OM.

Beyond Antiresorptive Activity: Risedronate-Based Coordination Complexes To Potentially Treat Osteolytic Metastases.

Coordination of clinically employed bisphosphonate, risedronate (RISE), to bioactive metals, Ca2+, Mg2+, and Zn2+, allowed the formation of bisphosphonate-based coordination complexes (BPCCs). Three RISE-based BPCCs, RISE-Ca, RISE-Mg, and RISE-Zn, were produced, and their structures were elucidated by single crystal X-ray diffraction. Interestingly, the addition of an auxiliary ligand, etidronic acid (HEDP), resulted in the recrystallized protonated form of the ligand, H-RISE. The pH-dependent structural stability of the RISE-based BPCCs was measured by means of dissolution profiles under neutral and acidic simulated physiological conditions (PBS and FaSSGF, respectively). In comparison to RISE (Actonel), the complexes showed a lower equilibrium solubility (∼70-85% in 18-24 h) in PBS, while a higher equilibrium solubility (∼100% in 3 h) in acidic media. The results point to the capacity to release this BP in a pH-dependent manner from the RISE-based BPCCs. Subsequently, the particle size of RISE-Ca was reduced, from 300 µm to ∼350 d.nm, employing the phase inversion temperature (PIT)-nanoemulsion method, resulting in nano-Ca@RISE. Aggregation measurements of nano-Ca@RISE in 1% fetal bovine serum (FBS):H2O was monitored after 24, 48, and 72 h to study the particle size longevity in physiological media, showing that the suspended material has the potential to maintain its particle size over time. Furthermore, binding assays were performed to determine the potential binding of nano-Ca@RISE to the bone, where results show higher binding (∼1.7×) for the material to hydroxyapatite (HA, 30%) when compared to RISE (17%) in 1 d. The cytotoxicity effects of nano-Ca@RISE were compared to those of RISE against the human breast cancer MDA-MB-231 and normal osteoblast-like hFOB 1.19 cell lines by dose-response curves and relative cell viability assays in an in vitro setting. The results demonstrate that nano-Ca@RISE significantly decreases the viability of MDA-MB-231 with high specificity, at concentrations ∼2-3× lower than the ones reported employing other third-generation BPs. This is supported by the fact that when normal osteoblast cells (hFOB 1.19), which are part of the tissue microenvironment at metastatic sites, were treated with nano-Ca@RISE no significant decrease in viability was observed. This study expands on the therapeutic potential of RISE beyond its antiresorptive activity through the design of BPCCs, specifically nano-Ca@RISE, that bind to the bone and degrade in a pH-dependent manner under acidic conditions.

High affinity zoledronate-based metal complex nanocrystals to potentially treat osteolytic metastases.

Formation of several materials, denoted as bisphosphonate-based coordination complexes (BPCCs), resulted from the reaction between clinically employed bisphosphonate, zoledronate (ZOLE) and bioactive metals (M2+ = Ca2+, Mg2+ and Zn2+). Six ZOLE-based BPCCs were synthesized using different variables (M2+ : ZOLE molar ratio, temperature, pH, and anion) and their structures were elucidated by single crystal X-ray diffraction (ZOLE-Ca forms I and II, ZOLE-Mg forms I and II, and ZOLE-Zn forms I and II). The dissolution of the ZOLE-based BPCCs was compared to that of ZOLE (Reclast®). Most of the ZOLE-based BPCCs (60-85%, in 18-24 h) present a lower dissolution and equilibrium solubility than ZOLE (∼100%, 30 min) in phosphate buffered saline (PBS), while a significantly higher dissolution is observed in acidic media (88% in 1 h). This suggests the ability to release the ZOLE content in a pH-dependent manner. Moreover, a phase inversion temperature (PIT)-nano-emulsion synthesis was performed, which demonstrated the ability to significantly decrease the crystal size of ZOLE-Ca form II from a micron-range (∼200 µm) to a nano-range (∼150 d nm), resulting in nano-Ca@ZOLE. Furthermore, low aggregation of nano-Ca@ZOLE in 10% fetal bovine serum (FBS) : PBS after 0, 24 and 48 h was demonstrated. Additionally, nano-Ca@ZOLE showed an ∼2.5x more binding to hydroxyapatite (HA, 36%) than ZOLE (15%) in 1 d. The cytotoxicity of nano-Ca@ZOLE against MDA-MB-231 (cancer cell model) and hFOB 1.19 (normal osteoblast-like cell model) cell lines was investigated. The results demonstrated significant cell growth inhibition for nano-Ca@ZOLE against MDA-MB-231, specifically at a low concentration of 3.8 µM (%RCL = 55 ± 1%, 72 h). Under the same conditions, the nanocrystals did not present cytotoxicity against hFOB 1.19 (%RCL = 100 ± 2%). These results evidence that nano-ZOLE-based BPCCs possess viable properties in terms of structure, dissolution, stability, binding, and cytotoxicity, which render them suitable for osteolytic metastasis therapy.

Potentiating bisphosphonate-based coordination complexes to treat osteolytic metastases.

The hydrothermal reaction between bioactive metal (Ca2+, Zn2+, and Mg2+) salts and a clinically utilized bisphosphonate, alendronate (ALEN), promotes the formation of several materials denominated as bisphosphonate-based coordination complexes (BPCCs). The systematic exploration of the effect of three variables, M2+/ALEN molar ratio, temperature, and pH, on the reaction yielded an unprecedented number of materials of enough crystal quality for structural elucidation. Five crystal structures were unveiled by single crystal X-ray diffraction (ALEN-Ca forms I and II, ALEN-Zn forms I and II, and ALEN-Mg) and their solid-state properties revealed in tandem with other techniques. The dissolution of these BPCCs was tested and contrasted to that of the commercially employed generic form of Fosamax® Alendronate Sodium, using fasted-state simulated gastric fluid and phosphate-buffered saline solution. Quantification of ALEN content was performed by derivatization with Cu2+, which produced a soluble complex suitable for quantification. The results show that these materials present a pH-dependent degradation. Moreover, a phase inversion temperature (PIT) nano-emulsion method was applied to the synthesis of ALEN-Ca form II. Size distribution analysis demonstrated the efficiency of the PIT-nano-emulsion method to decrease the particle size of this BPCC from ∼60 µm to ∼438 d nm. The cytotoxicity of ALEN, ALEN-Ca form II (bulk crystals), and nano-Ca@ALEN (nanocrystals) against the MDA-MB-231 cell line was investigated. Nano-Ca@ALEN form II presents higher cytotoxicity effects than ALEN and ALEN-Ca form II (bulk crystals), showing inhibition of cell proliferation at 7.5 µM. These results provide evidence of the structure, stability, dissolution and cytotoxicity properties of ALEN-based BPCCs and pave the way for better formulation strategies for this drug through the design of nano-sized BPCCs for the treatment of bone-related diseases.