Cancer associated bone pain (CIBP) is a common event in patients with advanced disease with bone metastases (BM), significantly impairing their quality of life. Treatment options are limited and mainly based on the use of opioids with unacceptable side effects. Local acidosis is a well-known cause of pain since it directly stimulates nociceptors that express acid-sensing ion channels and densely innervate bone. In BM, local acidosis derives from osteoclast bone resorption activity and from the acidification by glycolytic tumor cells. Here we speculated that the pH lowering of intratumoral interstitial fluid also promotes nociceptors sensitization and hyperalgesia through the activation of cells of mesenchymal origin in BM microenvironment that might release inflammatory and nociceptive mediators.

As a model of breast cancer that can metastatise to the bone we used MDA-MB-231 (MDA), and a subclone with a higher tendency to form osteolytic BM (bmMDA). We evaluated the basal expression of proton pumps/ion transporters by Real-Time PCR (Q-RT-PCR). To evaluate the effect of extracellular acidosis on mesenchymal tumor-associated stroma, we used human osteoblast primary cultures from healthy donors and cancer-associated fibroblasts isolated with specific immunobeads from the tumor biopsies of patient with BM. We exposed the cells to pH 6.8 medium at different time points (between 3 to 24 hours). After the short-term incubation with acidosis, for the expression of and acid-sensing ion channels, inflammatory cytokines and nociceptive mediators that can produce hyperalgesia, we used both a wide screening through a deep-sequencing approach and Q-RT-PCR, and ELISA. Xenograft for osteolytic BM induced by intratibial injection of bmMDA were treated with Omeprazole and monitored for CIBP through several cognitive tests.

We found a significantly higher extracellular proton efflux and expression of proton pumps/ion transporters associated with the acid-base balance, the monocarboxylate transporter 4 (MCT4), the carbonic anhydrase (CA9), and the vacuolar ATPase (V-ATPase) V₁G₁ subunit, and V₀c subunitin bmMDA, a subclone that is prone to form BM in respect to the parental cell line MDA-MB-231. In mesenchymal stromal cells, osteoblasts and cancer-associated fibroblasts, the incubation with pH 6.8 induced the expression of the achid-sensing ion channels AISC3/ACCN3 and AICS4/ACCN4, as well as of the nociceptive modulators nerve growth factor (NGF), Brain-derived neurotrophic factor (BDNF), and of the inflammatory cytokines interleukin 6 (IL6) and 8 (IL8), and Chemokine (C-C motif) ligand 5 (CCL5). Furthermore, the targeting of V0c subunit to inhibit intratumoral acidification significantly reduced CIBP in mice model of BM.

In this study we demonstrated for the first time that, in addition to the direct acid-sensing neuronal stimulation, the acidic microenvironment of BM causes hyperalgesia through the activation of an inflammatory reaction in the tumor-associated mesenchymal stroma at the tumor site, thereby offering as a new target for palliative treatment in advanced cancer.

The glycolytic-based metabolism of cancers promotes an acidic microenvironment that is responsible for increased aggressiveness. However, the effects of acidosis on tumour metabolism have been almost unexplored, and the metabolic adaptation of cancer cells to acidosis has never been compared with the metabolic response of normal cells.

In this study, to pinpoint for the first time the different metabolic profiles between osteosarcoma (OS) cells and normal human fibroblasts (Fb) under short-term acidosis, we used capillary electrophoresis with time-of-flight mass spectrometry (CE-TOFMS). We also screened alterations of the epigenetic profiles – DNA methylation and histone acetylation – of OS cells and compared it with those of normal Fb.

Using CE-TOFMS, we observed a significant metabolic difference associated with glycolysis repression (dihydroxyacetone phosphate), increase of amino acid catabolism (phosphocreatine and glutamate) and urea cycle enhancement (arginino succinic acid) in OS cells compared with normal Fb. Noteworthy, metabolites associated with chromatin modification, like UDP-glucose and N⁸-acetylspermidine, decreased more in OS cells than in normal Fb. Further, combined bisulfite restriction analysis (COBRA) and acetyl-H3 immunoblotting indicated an epigenetic stability in OS cells than in normal Fb, and OS cells were more sensitive to an HDAC inhibitor under acidosis than under neutral condition.

Our data suggest that acidosis promotes a metabolic reprogramming that can contribute to the epigenetic maintenance under acidosis only in OS cells, and then the acidic microenvironment should be considered for future therapeutic approaches. The application of epigenetic modulators will be able to become an effectively therapeutic option to selectively target malignancies under the acidic microenvironment.

A complete design-manufacturing process for delivering customized foot orthoses by means of digital technologies is presented. Moreover, this feasibility study aims to combine a semi-automatic modelling approach with the use of low-cost devices for 3D scanning and 3D printing.

In clinical practice, traditional methods for manufacturing customized foot orthoses are completely manual, mainly based on plaster casting plus hand fabrication, and are widely used among practitioners. Therefore, results depend on skills and expertise of individual orthoptists and podiatrists that need considerable training and practice in order to obtain optimal functional devices.

On the other side, novel approaches for design and manufacturing customized foot orthoses by means of digital technologies (generally based on 3D scanning, 3D modelling and 3D printing) are recently reported as a valid alternative method to overcome these limitations.

This study has been carried out in an interdisciplinary approach between the staff of Design and Methods in Industrial Engineering and the staff of Podology with the aim to assess the feasibility of a novel user-friendly and cost-effective solution for delivering customized functional foot orthoses. More specifically, a Generative Design (GD) workflow has been developed to enable practitioners without enough CAD skills to easily 3D modelling and interactively customize foot orthoses. Additionally, low-cost devices for 3D scanning and 3D printing that have been acquired by the Podology Lab, were also tested and compared with the high-cost ones of the Department of Industrial Engineering.

The complete process is divided into three main steps. The first one regards the digitization of the patient's foot by means of 3D laser scanner devices. Then a user-friendly 3D modelling approach, developed for this purpose as GD workflow, allows interactively generating the customized foot orthosis, also adjusting several features and exporting the watertight mesh in STL format. Finally, the last step involves Additive Manufacturing systems to obtain the expected physical item ready to use.

First, for what concerns the digitizing step, the acquired data resulting from 3D scanning by means of the low-cost system (Sense 3D scanner) appears accurate enough for the present practical purposes.

Then, with respect to the 3D modelling step, the proposed GD workflow in Grasshopper is intuitive and allows easily and interactively customizing the final foot orthosis. Finally, regarding the Additive Manufacturing step, the low cost 3D printer (Wasp Delta 40 70) is capable to provide adequate results for the shell of the foot orthosis. Moreover, this system appears really versatile in reason of the capability to print in a wide range of different filaments. Therefore, since the market of 3D printing filaments is rapidly growing, building sessions with different materials (both flexible and rigid such, for example, PLA, AB and PETG) were completed.

This study validated, in terms of feasibility, that the use of a GD modelling approach, in combination with low-cost devices for 3D scanning and 3D printing, is a real alternative to conventional processes for providing customized foot orthosis. Moreover, the interdisciplinary approach allowed the transfer of skills and knowledge to the practitioners involved and, also, the low-cost devices Sense 3D scanner and Wasp Delta 40 70 that have been acquired by the Podology Lab, were demonstrated suitable for this kind of applications.

Osteosarcoma (OS) is an aggressive bone malignancy with a high relapse rate despite combined treatment with surgery and multiagent chemotherapy. As for other cancers, OS-associated microenvironment may contribute to tumor initiation, growth, and metastasis. We consider mesenchymal stromal cells (MSC) as a relevant cellular component of OS microenvironment, and have previously found that the interaction between MSC and tumor cells is bidirectional: tumor cells can modulate their peripheral environment that in turn becomes more favourable to tumor growth through metabolic reprogramming (1).

Stem-like cells were derived from HOS osteosarcoma cell line by using the spherogenic system (2). CSC isolated from HOS (HOS-CSC) were co-coltured with MSC isolated from bone marrow. Cell lysates and supernatants were collected for the analysis of RNA expression and of secreted cytokines, by Q-RT-PCR and specific ELISA assays, respectively.

Here, we determined the effects of MSC on OS stemness and migration, two major features associated with recurrence and chemoresistance. Recruitment of MSC to the tumor environment leads to enhanced proliferation of OS stem cells, which increase the expression levels of TGFβ1. The latter, in turn, could be responsible for the activation of NF-kB genes and IL-6 secretion by MSC. Pro-tumorigenic effects of MSC, via IL-6, including induction of HOS-CSC migration and sphere growth, can be counteracted by IL-6 neutralizing antibody. The presence of MSC is also responsible for increased expression of adhesion molecules involved in intra- or extra-vasation.

Stromal cells in combination with OS spheres exploit a vicious cycle where the presence of CSC stimulates mesenchymal cytokine secretion, which in turn increases stemness, proliferation, migration, and metastatic potential of CSC. Furthermore, for the first time we identified a novel OS stem cell marker, the Met proto-oncogene, that is frequently overexpressed and is pathogenetically relevant in OS (2 and 3). Altogether, our data corroborates the concept that a comprehensive knowledge of the interplay between tumor and stroma that also includes the stem-like fraction of tumor cells is needed to develop novel and effective anti-cancer therapies.

The success of biomaterials lies in the direct interaction with the host tissue. Calcium phosphates (CaP) stand as an alternative graft material for bone regeneration due to their similar composition to natural bone. Few studies have focused on the early stages of bone-like material remodeling by osteoclasts (OC), though the CaP fate is to be resorbed and then replaced by new bone. Instead, to understand how osteoclasts modify the CaP surface and initiate resorption, so as to influence subsequent osteoblast activities and bone formation, is mandatory.

Sintered hydroxyapatite (s-HA) and biomimetic hydroxyapatite with two different microstructures (b-HA-C, coarse and b-HA-F, fine) discs (1500×250 µm²) were produced from the same reagents [1]. Tissue culture polystyrene (TCPS) was used as control. Precursor human OC from buffy coats were seeded on ceramic substrates [6·10⁶cells/cm²] and supplemented with RANKL-containing osteoblast supernatant as differentiation medium over 21 days. Cell interaction with the biomaterials was investigated in terms of OC adhesion and differentiation, with gene expression, tartrate-resistant acid phosphatase (TRAP) and Hoechst staining for OC maturation. Cell culture supernatants were analyzed for ionic exchange, namely Ca and P, due to biomaterials or cells. Osteoclasts morphology was evaluated using SEM at 21 days. Innovatively, focused ion beam (FIB) was used to evaluate biomaterial structure beneath the OC to further investigate the resorption effects. To this aim, selected OC were cut cross-sectioned using a Gallium ion beam at an acceleration of 30KV, followed by a coarse milling at 10nA and a deposition of platinum to achieve a fine milling at 500pA.

Clear differences in cellular behavior were noted relative to the different substrate microstructures. Control TCPS and s-HA showed similar TRAP-positive staining and gene expression for mature OC. Several resorption pits with partial dissolution of the equiaxial grains of s-HA were noticed. b-HA substrates also showed attached and differentiated TRAP-positive OC, but gene expression resulted lower than control and s-HA. However, morphological evaluation with SEM-FIB interestingly showed early stages of osteoclast-mediated degradation on b-HA-F, i.e.an increased surface roughness in the substrate underlying cells. B-HA-C also showed attached and mature OC with a scarce degradation activity

FIB technique has been applied to cell-seeded CaP and shown as a viable method to investigate OC morphology and resorption. Though gene expression showed similarities for both biomimetic substrates, substrate morphology observed underneath OC was significantly different. b-HA-F showed early stages of OC mediated degradation underneath well spread cells similar to those seen on s-HA. No resorptive activity was found on b-HA-C even though gene expression values were similar to b-HA-F: both the acute ion exchange and the surface tortuosity on b-HA-C could explain the difficulty with the resorptive process by OC. In conclusion focused ion beam technique complements SEM imaging and may disclose changes in the inner structure of materials due to cell/material interactions.

For unrepairable nerve defects, to date autogenous nerves are considered the golden standard, but donor site morbidity, limited availability and operation time prolongation are relevant problem. Acellular nerves from cadaveric donor, introduced since more than one decade ago, represent a novel promising alternative to bridge unrepairable nerve gaps.

Aim of this study is to provide a new tool to ameliorate the assistance of the numerous patients suffering from traumatic, oncological and jatrogenic nerve lesions. For this purpose, our project is promoting a progress beyond the state of the art of nerve gaps bridging surgery by developing a new technique to obtain acellular nerve allografts (ANAs).

Several methods to examine the effect of detergents on nerve tissue morphology and protein composition have been previously reported. Most of them are too expensive and time consuming. The presented novel decellularization technique is a modification of the Michigan detergent-based organic material removal, to speed up myelin and cellular debris detachment. The previously published Hudson's method¹has been chosen as control of the decellularization process). To validate the new nerve decellularization method, in terms of histological characteristics, outcomes were estimated through morphological and immunohistochemical studies in vitro and in vivo. The in vivo study consisted of a 1 cm defect in the tibial nerve of 3 new Zealand rabbits. This nerve defect was microsurgically replaced with a “Rizzoli” acellular nerve allograft. Rabbits were sacrificed 12 weeks after surgery. Endpoints were nerve conduction studies and histology.

Histological analysis of processed acellular nerve have been performed to evaluate the preservation of the structure and almost complete clearance of donor cells and cellular debris. Immunostaining analysis confirmed absence of Schwann cells and the maintenance of basal lamina. In vivo studies showed an effective and abundant nerve regeneration through the microsurgically reconstructed nerve defects. This was histologically proven. However no electophysiological return of function was showed.

The novel method will allow the storing of acellular nerve allografts. First results obtained by morphological analysis and immunofluorescence experiments and in vivo studies indicate that the internal structure of native nerve is maintained. It is then possible to decellularize nerves with the novel technique reducing both manufacturing times and costs. The relatively inexpensive method of decellularization will facilitate the number of patients that will benefit from reconstruction of nerve defects with ANAs.

The postoperative course of median nerve decompression in the carpal tunnel syndrome may sometimes be complicated by postoperative pain, paresthesias, and other unpleasant symptoms, or be characterized by a slow recovery of nerve function due to prolonged preoperative injury causing extensive nerve damage.

The aim of this study is to explore any possible effects of alpha lipoic acid (ALA) in the postoperative period after surgical decompression of the median nerve at the wrist.

Patients were enrolled with proven carpal tunnel syndrome and randomly assigned into one of two groups: Group A: surgical decompression of the median nerve followed by ALA for 40 days. Group P: surgical decompression followed by placebo. The primary endpoint of the study was nerve conduction velocity at 3 months post surgery, Other endpoints were static 2 point discrimination, the Boston score for hand function, pillar pain and use of pain killers beyond the second postoperative day.

ALA did not show to significantly improve nerve conduction velocity or Boston score. However, a statistically significant reduction in the postoperative incidence of pillar pain was noted in Group A. In addition, static 2 point discrimination showed to be significantly improved by ALA.

Administration of ALA following decompression of the median nerve for carpal tunnel release is effective on nerve recovery, although this is not detectable through nerve conduction studies but in terms of accelerated and improved static two-point discrimination.

The use of ALA as a supplementation for nerve recovery after surgical decompression may be extended to all types of compression syndromes or conditions where a nerve is freed from a mechanical insult.

Furthermore, ALA limits post-decompression pain, including late pericicatricial pain at the base of the palm, the so called pillar pain, which seems to be associated with a reversible damage to the superfical sensitive small nerve fibers.

In conclusion postoperative administration of ALA for 40 days post-median nerve decompression was positively associated with nerve recovery, induced a lower incidence of postoperative pillar pain and was associated with a more rapid improvement of static two-point discrimination. This treatment is well tolerated and associated with high levels of satisfaction and compliance, supporting its value as a standard postoperative supplementation after carpal tunnel decompression.

Delayed bone healing and nonunion are complications of long bone fractures, with prolonged pain and disability. Regenerative therapies employing mesenchymal stromal cells (MSC) and/or bone substitutes are increasingly applied to enhance bone consolidation. The REBORNE project entailed a multi-center orthopaedic clinical trial focused on the evaluation of efficacy of expanded autologous bone marrow (BM) derived MSC combined with a CaP-biomaterial, to enhance bone healing in patients with nonunion of diaphyseal fractures. To complement the clinical and radiological examination of patients, bone turnover markers (BTM) were assayed as potential predictors of bone healing or non-union.

Peripheral blood was collected from patients at fixed time-endpoints, that is at 6,12 and 24 weeks post-surgery for implantation of expanded autologus MSC and bone-like particles. Bone-specific alkaline phosphatase (BAP), C-terminal-propeptide type I-procollagen (PICP), osteocalcin (OC), β-Cross-Laps Collagen (CTX), soluble receptor activator of NFkB (RANKL), osteoprotegerin (OPG) were measured by ELISA assays in blood samples of 22 patients at BM collection and at follow-up visits.

A significant relationship with age was found only at 6 months, with an inverse correlation for CTX, RANKL and OC, and positive for OPG. BTM levels were not related to gender. As an effect of local regenerative process, some BTM showed significant changes in comparison to the baseline value. In particular, the time course of BAP, PICP and RANKL was different in patients with a successful healing in comparison to patients with a negative outcome. The BTM profile apparently indicated a remarkable bone formation activity 12 weeks after surgery. However, the paucity of failed patients in our case series did not allow to prove statistically the role of BTM as predictors of the final outcome.

Blood markers related to bone cell function are useful to measure the efficacy of a expanded MSC-regenerative approach applied to long bone non-unions. Changes of the markers may provide a support to radiological assessment of bone healing.

The regenerative potential of bone grafts is tightly linked to the interaction of the biomaterial with the host tissue environment. Hence, strategies to confer artificial extracellular matrix (aECM) cues on the material surface are becoming a powerful tool to trigger the healing cascade and to stimulate bone regeneration. The use of glycosaminoglycans (GAGs), such as heparin, as aECM components has gained interest in the last years as a strategy to improve biological response. Calcium phosphates (CaP) are extensively used as bone grafts, however no studies have investigated the effect of GAG functionalisation on their surface. Some authors have focused on the effects of GAGs on osteoblastic cells, however, little work has been performed on the interaction with osteoclasts (OC), and still the reported effects are controversial [1]. The aim of this study was to investigate the effect of heparin on osteoclastic fate in terms of adhesion and differentiation.

Sintered CaP (β-TCP) and biomimetic CaP (calcium-deficient hydroxyapatite, CDHA) discs were synthesized at 1100 ºC and at 37ºC, respectively. Heparinisation was achieved though silane coupling (APTES) followed by amidation in the presence of EDC/NHS to covalently link heparin. The osteoclast response of heparinised (H) vsnon-heparinised substrates was studied using human monocytes as OC precursors. Tissue culture plastic (TCPS) was used as a control sample. Cell densities were 6·10⁶and 3·10⁶cells/cm²for biomaterials and TCPS, respectively. Cell cultures were supplemented every 3 days with 25% supernatant of osteoblast-like cell line as a source of RANKL, as well as other stimulating factors [2]. Tartrate-resistant acid phosphatase and Hoechst staining were used to evaluate OC adhesion, differentiation and morphology at different time points from seeding on the surfaces (14–21–28 days).

OC precursors showed adhesion on all substrates. β-TCP and β-TCP-H hosted higher number of OC precursors which might be related to the smoother sintered surface of the materials. Oppositely, the high roughness of CDHA and CDHA-H hamper the adhesion of OC, hence a lower number of cells was observed on heparin-coated and uncoated biomimetic apatites. However, the maturation of OC precursors was found to take place at earlier times (14days) on biomimetic substrates compared to sintered ones. TCPS, CDHA, CDHA-H and β-TCP-H showed clearly differentiated OC at 14 days, as revealed by TRAP positivity and multinuclearity. Interestingly, CDHA-H and β-TCP-H induced the highest multinuclearity among all differentiated OC. Both heparinised substrates point at an enhancing effect of heparin on OC maturation.

OC precursors are able to differentiate on β-TCP and CDHA substrates, a process enhanced when heparin functionalisation is performed on the materials surface. In our hands heparinisation is promoting OC differentiation at early time points, similarly to TCPS control. Interestingly, heparin substrates induced larger TRAP positive-OC and higher multinuclearity in the mature OC than TCPS control. As pointed out by Irie et al., heparin might interact through the RANKL/OPG ratio [3], thus inhibiting OPG activity and enhancing RANKL which triggers OC maturation.

Summary

We demonstrate that osteoclast-like cells of GCT result from the spontaneous fusion and differentiation of CD14+ cells of the monoblastic lineage by an autocrine mechanism mediated by RANKL, rather than induced by stromal cells. This process is further enhanced by the simultaneous impairment of the negative feed-back regulation of osteoclastogenesis by interferon β.

Summary

Starting from human musculoskeletal sarcomas, we isolated a subset of cells that display cancer stem cell properties. The control of culture conditions is crucial to enhance the isolation of this cell population.

Summary

Reciprocal metabolic reprogramming of MSCs and osteosarcoma cells influences tumor-stroma cross talk. Drugs targeting Warburg metabolism may define innovative therapeutic approaches in osteosarcoma.

Summary Statement

In this study it has been considered an alternative therapeutic approach to bone resorption diseases by using plant decoctions to improve adherence from patients to the treatment. In this context, Hemidesmus indicus represents a possible therapeutic or adjuvant natural compound.