Adeno-associated virus-coated allografts: a novel approach for cranioplasty.

Bone autografts are considered the gold standard for cranioplasty, although they lead to co-morbidity. Bone allografts are more easily obtained but have low osteogenic potential and fail to integrate into healthy bone. Previously, we showed that, by coating long-bone allografts with freeze-dried recombinant adeno-associated virus (rAAV) vector encoding for an osteogenic gene, enhanced osteogenesis and bone integration were achieved. In this study our aim was to evaluate the bone repair potential of calvarial autografts and allografts coated with either single-stranded rAAV2 vector (SS-rAAV-BMP2) or self-complementary pseudotyped vector (SC-rAAV-BMP2) encoding for bone morphogenetic protein (BMP)2 in a murine cranioplasty model. The grafts were implanted into critical defects in the calvariae of osteocalcin/luciferase (Oc/Luc) transgenic mice, which allowed longitudinal monitoring of osteogenic activity using bioluminescence imaging (BLI). Our results showed that the bioluminescent signal of the SC-rAAV-BMP2-coated allografts was 40% greater than that of the SS-rAAV-BMP2-coated allografts (p<0.05) and that the bioluminescent signal of the SS-rAAV-BMP2-coated allografts was not significantly different from the signals of the autografts or uncoated allografts. Micro-computed tomography (µCT) confirmed the significant increase in osteogenesis in the SC-rAAV-BMP2 group compared with the SS-rAAV-BMP2 group (p<0.05), indicating a significant difference in bone formation when compared with the other grafts tested. In addition, histological analysis revealed extensive remodelling of the autografts. Collectively, these results demonstrate the feasibility of craniofacial regeneration using SC-rAAV-BMP2-coated allografts, which may be an attractive therapeutic solution for repair of severe craniofacial bone defects.

Smad8/BMP2-engineered mesenchymal stem cells induce accelerated recovery of the biomechanical properties of the Achilles tendon.

Tendon tissue regeneration is an important goal for orthopedic medicine. We hypothesized that implantation of Smad8/BMP2-engineered MSCs in a full-thickness defect of the Achilles tendon (AT) would induce regeneration of tissue with improved biomechanical properties. A 2 mm defect was created in the distal region of murine ATs. The injured tendons were then sutured together or given implants of genetically engineered MSCs (GE group), non-engineered MSCs (CH3 group), or fibrin gel containing no cells (FG group). Three weeks later the mice were killed, and their healing tendons were excised and processed for histological or biomechanical analysis. A biomechanical analysis showed that tendons that received implants of genetically engineered MSCs had the highest effective stiffness (>70% greater than natural healing, p < 0.001) and elastic modulus. There were no significant differences in either ultimate load or maximum stress among the treatment groups. Histological analysis revealed a tendon-like structure with elongated cells mainly in the GE group. ATs that had been implanted with Smad8/BMP2-engineered stem cells displayed a better material distribution and functional recovery than control groups. While additional study is required to determine long-term effects of GE MSCs on tendon healing, we conclude that genetically engineered MSCs may be a promising therapeutic tool for accelerating short-term functional recovery in the treatment of tendon injuries.

Novel immunotherapy for malignant melanoma with a monoclonal antibody that blocks CEACAM1 homophilic interactions.

CEACAM1 (biliary glycoprotein-1, CD66a) was reported as a strong clinical predictor of poor prognosis in melanoma. We have previously identified CEACAM1 as a tumor escape mechanism from cytotoxic lymphocytes. Here, we present substantial evidence in vitro and in vivo that blocking of CEACAM1 function with a novel monoclonal antibody (MRG1) is a promising strategy for cancer immunotherapy. MRG1, a murine IgG1 monoclonal antibody, was raised against human CEACAM1. It recognizes the CEACAM1-specific N-domain with high affinity (K(D) ~ 2 nmol/L). Furthermore, MRG1 is a potent inhibitor of CEACAM1 homophilic binding and does not induce any agonistic effect. We show using cytotoxicity assays that MRG1 renders multiple melanoma cell lines more vulnerable to T cells in a dose-dependent manner, only following antigen-restricted recognition. Accordingly, MRG1 significantly enhances the antitumor effect of adoptively transferred, melanoma-reactive human lymphocytes using human melanoma xenograft models in severe combined immunodeficient/nonobese diabetic (SCID/NOD) mice. A significant antibody-dependent cell cytotoxicity response was excluded. It is shown that MRG1 reaches the tumor and is cleared within a week. Importantly, approximately 90% of melanoma specimens are CEACAM1(+), implying that the majority of patients with melanoma could be amenable to MRG1-based therapy. Normal human tissue microarray displays limited binding to luminal epithelial cells on some secretory ducts, which was weaker than the broad normal cell binding of other anticancer antibodies in clinical use. Importantly, MRG1 does not directly affect CEACAM1(+) cells. CEACAM1 blockade is different from other immunomodulatory approaches, as MRG1 targets inhibitory interactions between tumor cells and late effector lymphocytes, which is thus a more specific and compartmentalized immune stimulation with potentially superior safety profile.

Direct gene therapy for bone regeneration: gene delivery, animal models, and outcome measures.

While various problems with bone healing remain, the greatest clinical change is the absence of an effective approach to manage large segmental defects in limbs and craniofacial bones caused by trauma or cancer. Thus, nontraditional forms of medicine, such as gene therapy, have been investigated as a potential solution. The use of osteogenic genes has shown great potential in bone regeneration and fracture healing. Several methods for gene delivery to the fracture site have been described. The majority of them include a cellular component as the carrying vector, an approach known as cell-mediated gene therapy. Yet, the complexity involved with cell isolation and culture emphasizes the advantages of direct gene delivery as an alternative strategy. Here we review the various approaches of direct gene delivery for bone repair, the choice of animal models, and the various outcome measures required to evaluate the efficiency and safety of each technique. Special emphasis is given to noninvasive, quantitative, in vivo monitoring of gene expression and biodistribution in live animals. Research efforts should aim at inducing a transient, localized osteogenic gene expression within a fracture site to generate an effective therapeutic approach that would eventually lead to clinical use.

Functional fibered confocal microscopy: a promising tool for assessing tendon regeneration.

This work advances fibered confocal microscopy (FCM) as a functional imaging platform for in vivo assessment of tissue mechanics. Building on our earlier studies demonstrating proof of principle and introducing an analytical framework for FCM image processing, here we present data that improve and validate several critical aspects of FCM. Specifically, we have considerably reduced the invasiveness of the imaging procedure, and verified that endoscopic imaging through a transcutaneous access point does not induce functional changes in passive ankle joint biomechanics. We have also verified that periodic (weekly) measurements on uninjured tendons are reproducible. Importantly, we have further proven that the method can sensitively detect and quantify compromised tendon mechanics in injured tendons. These incremental but essential developments further push FCM measurement of tissue mechanics from a novel concept to a usable tool that fills an important niche by functionally imaging living tissue at the highest available spatial resolution of any currently available in vivo imaging method. It is expected that functional FCM imaging will eventually enable accelerated screening of preclinical therapies, and allow researchers to quantifiably relate implanted cell behavior with resulting changes in tissue structure and function.