Platform for Measurements of the Casimir Force between Two Superconductors.

Several experimental demonstrations of the Casimir force between two closely spaced bodies have been realized over the past two decades. Extending the theory to incorporate the behavior of the force between two superconducting films close to their transition temperature has resulted in competing predictions. To date, no experiment exists that can test these theories, partly due to the difficulty in aligning two superconductors in close proximity, while still allowing for a temperature-independent readout of the arising force between them. Here we present an on-chip platform based on an optomechanical cavity in combination with a grounded superconducting capacitor, which overcomes these challenges and opens up the possibility to probe modifications to the Casimir effect between two closely spaced, freestanding superconductors as they transition into a superconducting state. We also perform preliminary force measurements that demonstrate the capability of these devices to probe the interplay between two widely measured quantum effects: Casimir forces and superconductivity.

Anatomy of the feeding arteries of the cerebral arteriovenous malformations.

BACKGROUND: Identification and anatomic features of the feeding arteries of the arteriovenous malformations (AVMs) is very important due to neurologic, radiologic, and surgical reasons. MATERIALS AND METHODS: Seventy-seven patients with AVMs were examined by using a digital subtraction angiographic (DSA) and computerised tomographic (CT) examination, including three-dimensional reconstruction of the brain vessels. In addition, the arteries of 4 human brain stems and 8 cerebral hemispheres were microdissected. RESULTS: The anatomic examination showed a sporadic hypoplasia, hyperplasia, early bifurcation and duplication of certain cerebral arteries. The perforating arteries varied from 1 to 8 in number. The features of the leptomeningeal and choroidal vessels were presented. The radiologic examination revealed singular (22.08%), double (32.48%) or multiple primary feeding arteries (45.45%), which were dilated and elongated in 58.44% of the patients. The feeders most often originated from the middle cerebral artery (MCA; (23.38%), less frequently from the anterior cerebral artery (ACA; 12.99%), and the posterior cerebral artery (PCA; 10.39%). Multiple feeders commonly originated from the ACA and MCA (11.69%), the MCA and PCA (10.39%), the ACA and PCA (7.79%), and the ACA, MCA and PCA (5.19%). The infratentorial feeders were found in 9.1% of the AVMs. Contribution from the middle meningeal and occipital arteries was seen in 3.9% angiograms. Two cerebral arteries had a saccular aneurysm. The AVM haemorrhage appeared in 63.6% of patients. CONCLUSIONS: The knowledge of the origin and anatomic features of the AVMs feeders is important in the explanation of neurologic signs, and in a decision regarding the endovascular embolisation, neurosurgical and radiosurgical treatments.

A novel combined model of intracerebral and intraventricular hemorrhage using autologous blood-injection in rats.

Intracerebral hemorrhage (ICH) is the least treatable form of stroke and is associated with the worst prognosis. In up to 40% of cases, ICH is further complicated by intraventricular hemorrhage (IVH), which predisposes to hydrocephalus, and increases case-mortality to 80%. However, IVH is not present in widely used preclinical models of ICH. Here, we characterize a novel rat model of combined ICH and IVH. Rats were injected with different volumes of autologous whole blood into the right deep basal ganglia region (100µL, 150µL, 200µL, and 250µL, n=10 per group). MRI was performed immediately, and at 24, 48, 72h, and 1week after blood injection, along with neurological evaluations. Injected blood volume reliably correlated with blood volumes measured from MRI obtained after blood injection. Brain edema was most prominent in the ⩾200µL groups, peaking at 48h in all groups, being statistically different between the ⩾200µL and <200µL groups at all-time points. Presence of hydrocephalus was detected in most of the animals, most clearly in the 200µL and 250µL groups, both being statistically different from the 100µL group at all-time points, with tendency to worsen during the whole follow-up period. Most deteriorating neurological and behavioral outcomes as well as the highest mortality rates were detected in groups injected with 200µL and 250µL of autologous blood, 40% and 70%, respectively. These volumes were most similar to the clinical scenario of combined ICH and IVH, demonstrating that this novel rat model is a promising starting point for future ICH+IVH research.

The blood-brain barrier is continuously open for several weeks following transient focal cerebral ischemia.

The blood-brain barrier (BBB) is the principal regulator of blood-borne substance entry into the brain parenchyma. Therefore, BBB leakage, which leads to cerebral edema and influx of toxic substances, is common in pathological conditions such as cerebral ischemia, inflammation, trauma, and tumors. The leakage of BBB after ischemia-reperfusion injury has long been considered to be biphasic, although a considerable amount of discrepancies as for the timing of the second opening does exist among the studies. This led us to evaluate systematically and quantitatively the dynamics of BBB leakage in a rat model of 90-min ischemia-reperfusion, using gadolinium-enhanced (small molecule) magnetic resonance imaging and fluorescent dye Evans Blue (large molecule). BBB leakage was assessed at the following time points after reperfusion: 25 min, 2, 4, 6, 12, 18, 24, 36, 48, and 72 h, and 1, 2, 3, 4, and 5 weeks. We observed BBB leakage for both gadolinium and Evans Blue as early as 25 min after reperfusion. Thereafter, BBB remained open for up to 3 weeks for Evans Blue and up to 5 weeks for gadolinium. Our results show that BBB leakage after ischemia-reperfusion injury in the rat is continuous and long-lasting, without any closure up to several weeks. This is the first systematic and extensive study fully demonstrating BBB leakage dynamics following transient brain ischemia and the findings are of major clinical and experimental interest.