Results from a first-in-human phase I safety trial to evaluate the use of a vascularized pericranial/temporoparietal fascial flap to line the resection cavity following resection of newly diagnosed glioblastoma

Glioblastoma (GBM), the most common malignant primary brain tumor, is uniformly fatal despite conventional therapy with surgery, radiation, and chemotherapy. One of the difficulties in treating GBM stems from the intrinsic privileged nature of the brain, specifically as a result of the blood–brain barrier (BBB) [1]. This complex structure limits the passage of ionized, hydrophilic, and large molecules and limits systemic delivery of potentially effective chemotherapies from penetrating tumor tissue in vivo [2].

Several techniques have been investigated to overcome the BBB and facilitate drug delivery. These include the use of fusion proteins, viral vectors, convection-enhanced delivery, carrier-mediated transport systems, focused ultrasound, and intra-arterial delivery of osmotic agents [3‐6]. However, these techniques have inherent shortcomings related to the delivery system, the drug itself, or its bioactivity. An ability to provide long-term durable delivery without requiring a specific drug or technique would permit more treatment versatility while allowing further clinical study comparing a variety of currently limited therapeutics.

Pedicled soft tissue flaps are commonly and frequently used in head and neck surgery and neurosurgery, reinforcing various skull base defects to prevent cerebrospinal fluid leaks [7]. Periosteal flaps and temporoparietal fascial flaps (TPFFs) are widely used options because they have predictable vasculature and a wide rotational arc [7, 8]. In cerebrovascular neurosurgery, flaps may be derived from regions of the superficial temporal artery (STA), internal maxillary artery, or omentum, rotated either directly or indirectly, and transposed onto ischemic brain regions [9‐11]. A new vascular network develops between the flap and the brain tissue as neovascularization takes over. Following stroke or TBI, this neovascularization has been shown to lack many of the characteristics of the BBB and therefore creates a uniquely permeable vascular network within an otherwise privileged microenvironment [12].

We hypothesize that implantation of vascularized flaps into and lining the surgical resection cavity may promote similar neovascularization with the ability to deliver classically restricted chemotherapeutic agents and give tumor bed access to circulating immune cells without the constraints of the BBB, thus generating an opportunity to increase both the antitumoral immunogenic response as well as drug delivery into the GBM microenvironment. We, therefore, performed this first-in-human, phase I study to assess the safety and feasibility of placing a TPFF/PCF in the resection cavity of newly diagnosed GBM.

Despite decades of research, the prognosis of GBM remains extremely poor [15]. Apart from the complex and heterogeneous signaling pathways, the unique tumor microenvironment of GBM strengthens the resistance to radiation and chemotherapy [16]. Importantly, the BBB presents a two-fold challenge: First, it prevents many intravenously administered chemotherapeutics from reaching sufficient concentrations in the brain [17]. Second, it limits the immunologic response to tumor-associated antigens in GBM thereby hindering a strong potential immunological response [18]. In this study, we investigated the safety and feasibility of inserting a vascularized temporoparietal fascial or pericranial flap into the tumor cavity as a method of promoting vascular ingrowth devoid of a BBB into the peritumoral microenvironment to facilitate using systemic therapies as well as to facilitate an improved immunologic response against the tumor.

Our results show that TPFF or PCF can be easily harvested, without a significant technical challenge. Furthermore, the pre-defined specific safety goals of this surgical technique were met in this study. Lining the resection cavity with a vascularized TPFF/PCF did not result in increased adverse events following implantation. No patient demonstrated increased seizure activity or wound complications due to devascularization of the overlying scalp. In our statistical analysis, both PFS and OS exceeded 6 months and greater than 70% of patients had 6 m PFS. Most notably, histopathological analyses of resected TPFF/PCF flaps at recurrence demonstrated no tumor infiltration into the flap suggestive of “hijacking” of the flap by the underlying GBM.

Tumors reoccurred at the craniotomy site in 4 patients in our cohort, providing an important opportunity to sample the tissue as it matured within the cavity. In all 4 cases, the presence of lymphocytes within the flap, and to a lesser extent within the adjacent brain, coupled with a lack of neoplastic cells in the transplanted flap, was encouraging as it supports the concept of a vascularized flap as a BBB-circumvented “scaffold”. Similarly, the presence of immune mediators and macrophages supports the introduction of an immunologic, inflammatory response into the tumoral environment [19, 20]. Although in this preliminary analysis, these changes were not identified robustly within the tumor resection bed, this study was not designed to examine this specifically, and future work is necessary to characterize changes in the resection bed related to TPFF/PCF insertion. Future studies using checkpoint inhibitors, for example, may further allow for T-cell infiltration into the tumor microenvironment via the implanted flap.

Previous studies have shown that most recurrences after resection in GBM patients occur in, or adjacent to, the resection cavity [21]. Targeting the cavity, facilitated by a flap, would therefore carry a potential for improved treatment efficacy. Thus, the finding of the increased population of immune cells and capillaries in the flap adjacent to the tumor microenvironment, compared to naïve pericranium, was encouraging [22].

Past studies in both animal models and humans, exploring post-stroke or TBI neovascularization via pial synangiosis in recovering central nervous system tissue, show robust neovascularization [23, 24]. Analyses of these newly formed blood vessels show that the vessels that form either lack or have a substantially more permeable BBB relative to healthy brain tissue [12]. The Matsushima grade, developed to assess these collaterals, describes the extent of perfusion on postoperative angiograms [25, 26]. Interestingly, the angioarchitecture of these vessels bears resemblance to vessels formed after an insult coupled with a microenvironment supporting neuroangiogenesis. knowledge of BBB forming around the bypass collaterals, however, remains limited.

We hypothesized that the insertion of TPFF/PCF vascularized flaps would cause similar vascular ingrowth and potentially facilitate the delivery and effects of local therapy into the perilesional cavity [22]. This would permit access to systemic and targeted therapy which does not normally cross the BBB into the adjacent peritumoral regions which commonly demonstrate the highest potential for tumor recurrence. The implantation of Gliadel wafers at the site of a resected brain tumor could offer sustained high local concentrations of carmustine and has shown effectiveness in a dose-dependent manner [27]. Studies have shown that transposing omentum onto the cerebral cortex can stimulate vessel penetration into the cortex in twelve hours [28]. The potential for omental vessels to form collateral connections with subarachnoid vessels was established in preclinical models of GBM [28]. Another earlier animal study had shown that free muscle grafts can form permeable new vessels on the brain, allowing molecules of different sizes to penetrate, with the depth of penetration correlating to the size of the graft [29]. In our study, the flap showed abundant CD68-positive macrophages and the adjacent brain tissue also showed abundant CD68-positive microglia/ macrophages. Theoretically, we hope that combining our technique with immunomodulatory strategies such as immune checkpoint inhibitors to increase T cell activity, strategies targeting CD8 + T cells, Tregs, and γδ T cells could potentially increase the abundance of immune cells and improve treatment response [30]. More samples are necessary to precisely understand the pathobiology of the interface between the flap and microenvironment of the resection cavity.

While the study met its primary and secondary endpoints, recurrence in a subset of patients permitted histopathological analyses of previously inserted tissue. These analyses identified a source of immune cells in direct contact with the neoplastic tissue. This element can potentially be additive to the hypothesized BBB bypass effect and may generate increased exposure of an immunologically ‘cold’ tumor (GBM) to a naturally lymphocytic-rich implanted tissue [19]. Therefore, if supported by future larger trials, the presence of B-cells, T-cells, and macrophages, as shown in 4 cases presented here both in the flap as well as in adjacent brain tissue, could provide support for a possible local immuno-therapeutic approach.

Our study has several limitations. Due to the nature of a small cohort, some adverse effects which are only clinically noticeable in a larger group, may be missed. The surgical technique described above, although simple to reproduce and not shown to extend the duration of surgery, may not be suitable for fragile patients, or in patients with other systemic diseases that may affect wound healing. Importantly, establishing a clear relationship between the suggested physiological process occurring at the interface of the flap and adjacent brain tissue, could not be demonstrated in this pilot study.

Our study suggests that pedicled autologous TPF or PCF, lining the resected tumor’s cavity, is both a safe and feasible technique tolerated by newly diagnosed GBM patients. Results show an encouraging outcome in terms of procedure tolerability, safety profile, and disease progression. Further future studies are warranted to confirm the safety and efficacy of this approach in patients with newly diagnosed GBM.