Oscillations in K(ATP) conductance drive slow calcium oscillations in pancreatic ß-cells.

ATP-sensitive K+ (K(ATP)) channels were first reported in the ß-cells of pancreatic islets in 1984, and it was soon established that they are the primary means by which the blood glucose level is transduced to cellular electrical activity and consequently insulin secretion. However, the role that the K(ATP) channels play in driving the bursting electrical activity of islet ß-cells, which drives pulsatile insulin secretion, remains unclear. One difficulty is that bursting is abolished when several different ion channel types are blocked pharmacologically or genetically, making it challenging to distinguish causation from correlation. Here, we demonstrate a means for determining whether activity-dependent oscillations in K(ATP) conductance play the primary role in driving electrical bursting in ß-cells. We use mathematical models to predict that if K(ATP) is the driver, then contrary to intuition, the mean, peak, and nadir levels of ATP/ADP should be invariant to changes in glucose within the concentration range that supports bursting. We test this in islets using Perceval-HR to image oscillations in ATP/ADP. We find that mean, peak, and nadir levels are indeed approximately invariant, supporting the hypothesis that oscillations in K(ATP) conductance are the main drivers of the slow bursting oscillations typically seen at stimulatory glucose levels in mouse islets. In conclusion, we provide, for the first time to our knowledge, causal evidence for the role of K(ATP) channels not only as the primary target for glucose regulation but also for their role in driving bursting electrical activity and pulsatile insulin secretion.

The Grasshopper Mouse and Bark Scorpion: Evolutionary Biology Meets Pain Modulation and Selective Receptor Inactivation.

Pain, however unpleasant, is a vital part of survival, providing a motivating response to noxious stimuli that helps move us away from danger. In medicine, adequate pain control can be maintained using analgesics, many of which produce unwanted and complicating side effects, most notably opioid analgesics. Here, I review a study which explored the unique predator/prey relationship between the Southern grasshopper mouse (Onychomys torridus) and its natural prey, the Arizona bark scorpion (Centruroides sculpturatus). O. torridus has developed an analgesic response to the scorpion's usually highly painful sting and, in doing so, provides a wonderful display of ion channel function and evolutionary biology. O. torridus' unique adaptation serves as a strong example of Krugg's Principle, which states there exists a best animal specimen for any scientific question. This principle is utilized to great effect by the authors to better understand receptor activation in pain. The study gradually progresses from an animal behavior model to isolating the amino acid residue in the ion channel responsible for the pain-relieving effect of scorpion venom on O. torridus. This provides a convincing argument for the potential of highly selective analgesics and the prospective sites of action for these future drugs.

Quantitative measures of osteoinductivity of a porous poly(propylene fumarate) bone graft extender.

Bioresorbable bone graft substitutes could alleviate disadvantages associated with the use of autografts, allografts, and other synthetic materials. However, little is known about the minimum autograft/extender ratio for a given material at which a sufficient osteoinductive effect is still seen. Therefore, we investigated a bioresorbable bone graft substitute made from the unsaturated polyester poly(propylene fumarate), PPF, at various mixing ratios with autograft. The bone graft extender is cross-linked in the presence of a hydroxylapatite filler and effervescent foaming agents citric acid and sodium bicarbonate. The porous bone graft extender material develops porosity in vivo by generating carbon dioxide during the effervescent reaction, resulting in foam formation and expansion with respective pore sizes of 50 to 1000 microm. In an attempt to determine how much cancellous autograft bone could be extended with the poly(propylene fumarate) material and at which ratio the autograft/extender combination remained supportive of the overall structural integrity of the repairing defect site, we studied the amount of new bone formation on implantation of the materials in 3-mm holes made in the anteromedial tibial metaphysis of Sprague-Dawley rats. The extender formulation was analyzed at high autograft/extender (75% autograft/25% extender) and low autograft/extender (25% autograft/75% extender) mixing ratios and compared with negative (extender alone) and positive (autograft alone) controls. Animals from each of the formulations were killed in groups of eight at 6 weeks postoperatively. Hence, a total of 32 animals were included in this study. Histologic analysis of the healing process revealed enhanced in vivo osteoinduction with the bone graft extender regardless of the autograft loading. Histomorphometry did not show any statistically significant difference between the high and low autograft/extender ratios. All formulations maintained implant integrity and did not provoke sustained inflammatory responses. This study suggested that the presence of even a small amount of autograft within the polymer-based bone graft extender results in significant enhancement of osteoinduction. This finding has immediate applicability to the development of bone graft extender formulations for clinical use.

Porous poly(propylene fumarate) foam coating of orthotopic cortical bone grafts for improved osteoconduction.

A porous biodegradable scaffold coating for perforated and demineralized cortical bone allografts could maintain immediate structural recovery and subsequently allow normal healing and remodeling by promoting bony ingrowth and avoiding accelerated graft resorption. This new type of osteoconductive surface modification should improve allograft incorporation by promoting new bone growth throughout the biodegradable scaffold, hence encasing the graft with the recipient's own bone. We investigated the feasibility of augmenting orthotopically transplanted cortical bone grafts with osteoconductive biodegradable polymeric scaffold coatings. Five types of bone grafts were prepared: type I, untreated fresh-frozen cortical bone grafts (negative control); type II, perforated and partially demineralized cortical bone grafts without additional coating (positive control); type III, perforated and partially demineralized cortical bone coated with a low-porosity poly(propylene fumarate) (PPF) foam; type IV, perforated and partially demineralized cortical bone coated with a medium-porosity PPF foam; and type V, perforated and partially demineralized cortical bone coated with a high-porosity PPF foam. Grafts were implanted into the rat tibial diaphysis. Fixation was achieved with an intramedullary threaded K-wire. Two sets of animals were operated on. Animals were killed in groups of eight with one set being killed 12 weeks, and the other 16 weeks, postoperatively. Radiographic, histologic, and histomorphometric analyses of grafts showed that the amount of new bone forming around the foam-coated grafts was significantly higher than that in the type I control group (uncoated) or that in type II group (perforated and partially demineralized cortical bone grafts). Although all foam formulations appeared initially equally osteoconductive, histologic evaluation of medium-porosity PPF foam-based coatings appeared to result in a sustained response 16 weeks postoperatively. Significant resorption was present in perforated and partially demineralized cortical bone graft allografts, with some accompanying new bone formation occurring primarily within the laser holes. Therefore, PPF foam-coated cortical bone grafts appeared to be better protected from excessive bone resorption, as frequently seen with invasion of fibrovascular tissue. Biomechanical analysis of the PPF foam-coated grafts corroborated findings of the morphometric analysis in that the failure strength at the allograft-host bone junction sites of all PPF-coated cortical bone grafts was higher than in the uncoated controls.

Evaluation of a porous, biodegradable biopolymer scaffold for mandibular reconstruction.

PURPOSE: Bioresorbable bone graft substitutes could eliminate disadvantages associated with the use of autografts, allografts, and other synthetic materials. The authors investigated the osteoinductive capacity of a bioresorbable bone graft substitute made from the unsaturated polyester poly(propylene glycol-co-fumaric acid) (PPF) for mandibular reconstruction in a rat model. The eventual intention is to use this material either as a stand-alone bone graft substitute or as an extender to autograft harvested from mandibular reconstruction sites. MATERIALS AND METHODS: The PPF bone graft was crosslinked in the presence of a hydroxyapatite filler and effervescent foaming agents to develop porosity in situ by generating carbon dioxide during the effervescent reaction of citric acid and sodium bicarbonate. The latter reagents are responsible for foam formation and expansion, resulting in a polymeric scaffold with pore sizes in the range of 100 to 500 microm. Twenty adult Sprague-Dawley rats had 3-mm-diameter cortical defects decorticated on the outer aspect of their left mandibular ramus using a Hall drill. Animals were divided into 2 groups of 10 animals each. Animals in group A were treated with implantation of the PPF-based bone graft substitute. Implants were applied buccally to defects on the left side. In group B animals with similar defects, the drill holes were left to heal unaided. The amount of new bone formation and the presence of an inflammatory infiltrate were evaluated at 7 weeks postoperatively. RESULTS: Histologic analysis of the healing process revealed enhanced in vivo new bone formation with the PPF bone graft substitute. These findings were corroborated by the histomorphometric analysis of new bone formation. DISCUSSION: Results of this study demonstrated biocompatibility of the porous PPF-based scaffold in a mandibular defect. CONCLUSIONS: These findings may have applicability to the further development of bone graft substitutes for oral/maxillofacial applications.