ABSTRACT
Objective To introduce an optimized practical method of making and detecting pipettes for microinjection.Methods Transfer pipette was made from hard glass capillary. We softened the hard glass capillary by rotating it in a spirit-lamp flame,then moved out from the flame and quickly pulled it into two transfer pipettes.After broken by a grinding wheel,the tip of the pipette was fire-polished by quickly touching the flame to make a fine opening.A hard glass capillary (1.0 mm,ouside diametre)was pulled into two holding pipettes by pipette Puller.The pipette shoulder was broken at desired position with a grinding wheel,then the fine pipette tip opening was heated by a microforge and shrinked into a diameter -15 μm.Injection pipette could be made directly from a capillary with filament by Puller.The solution loaded injection pipette and holding pipette were assembled into the micromanipulator and could be checked before use.We transfered both pipettes into the zygotes media drop,touched the holding pipette with the tip of the injection pipette to make a "suitable"opening.Then we switched injection pipette to the mineral oil and applied injection pressure through the injector to check whether the solution could come out of the tip smoothly and at a proper speed.It could be further verified by pronucleus microinjection of zygotes.Results The results showed that the method introduced in this paper could produce suitable pipettes for zygote microinjection.In particular,the method of detecting the opening of the injection pipette was helpful for achieving high efficiency of zygote microinjection.Conclusion The method introduced here to make and detect pipettes for microinjection is very helpful for establishing a standard microinjection manipulation procedure and improving the efficiency of zygote microinjection.
ABSTRACT
Objective To introduce an optimized practical method of making and detecting pipettes for microinjection.Methods Transfer pipette was made from hard glass capillary. We softened the hard glass capillary by rotating it in a spirit-lamp flame,then moved out from the flame and quickly pulled it into two transfer pipettes.After broken by a grinding wheel,the tip of the pipette was fire-polished by quickly touching the flame to make a fine opening.A hard glass capillary (1.0 mm,ouside diametre)was pulled into two holding pipettes by pipette Puller.The pipette shoulder was broken at desired position with a grinding wheel,then the fine pipette tip opening was heated by a microforge and shrinked into a diameter -15 μm.Injection pipette could be made directly from a capillary with filament by Puller.The solution loaded injection pipette and holding pipette were assembled into the micromanipulator and could be checked before use.We transfered both pipettes into the zygotes media drop,touched the holding pipette with the tip of the injection pipette to make a "suitable"opening.Then we switched injection pipette to the mineral oil and applied injection pressure through the injector to check whether the solution could come out of the tip smoothly and at a proper speed.It could be further verified by pronucleus microinjection of zygotes.Results The results showed that the method introduced in this paper could produce suitable pipettes for zygote microinjection.In particular,the method of detecting the opening of the injection pipette was helpful for achieving high efficiency of zygote microinjection.Conclusion The method introduced here to make and detect pipettes for microinjection is very helpful for establishing a standard microinjection manipulation procedure and improving the efficiency of zygote microinjection.
ABSTRACT
Objective To establish patient-specific hexahedral finite element mesh model for the maxillofacial surgery. Methods A standard and common hexahedral finite element mesh model for the face soft tissue was first built by semi-automatic procedure, and the an individual facial hexahedral mesh was then generated by an example learning method based on volumetric mapping. Results It was convenient to generate a high quality patient-specific hexahedral mesh with geometric shape feature and mesh element quality preserved as much as possible with this method. Conclusions The new hexahedral mesh modeling method can provide high quality hexahedral mesh input for biomechanics analysis with good application prospect in many fields such as oral and maxillofacial surgery.
ABSTRACT
<p><b>OBJECTIVE</b>To discuss the application of MRI in indirect temporomandibular joint injury without condylar fracture.</p><p><b>METHODS</b>MRI examination on temporomandibular joint was conducted in 28 patients with indirect injury to temporomandibular joint without condylar fracture. The scanning sequence included T(1)WI, PDWI on oblique sagittal section at both open and closed mouth positions, and T(1)WI, T(2)WI on oblique coronal section. The MRI appearance was analyzed by 2 senior radiologists.</p><p><b>RESULTS</b>Among the 56 temporomandibular joints of 28 patients, 35 joints exhibited pathological changes on MRI, in which there were 9 bone injuries, 21 articular disc dislocation, 24 intracapsular hematocele and hydrops.</p><p><b>CONCLUSIONS</b>MRI can clearly reveal bone injury, articular disc dislocation as well as articular capsule abnormality in the indirect injury of temporomandibular joint without condylar fracture. It is highly advocated in clinical use.</p>