Using transfixion irrigation with negative pressure drainage (TINPD) minimally invasive to manage infratemporal fossa (ITF) abscess.

RATIONALE: The treatment of abscess in the infratemporal space is still controversial and bedside and operative intraoral drainage is often used to resolve the abscess. However, it can be difficult to control the infection quickly.[1] In this report, the authors present a new technique of using transfixion irrigation with negative pressure drainage for minimally invasive management of infratemporal fossa abscess. PATIENT CONCERNS: A 45-year-old man with type 2 diabetes complained of painful swelling and trismus in the right lower facial region for 10 days. The patient was weak, with mild anxiety, and gradually aggravated. DIAGNOSES: The patient was misdiagnosed and received dental pulp treatment for the right mandibular first molar and was given oral cefradine capsules (500 mg 3 times per day). Computed tomography scan and puncture revealed an abscess in the infratemporal fossa. INTERVENTION: The authors used transfixion irrigation with negative pressure drainage from different directions to reach the abscess cavity. Saline solution was infused through 1 tube and allowed to flow out through the other tube to flush out the pus and debris from the abscess. OUTCOME: On day 9, the drainage tube was removed and the patient was discharged. One week later, the patient was followed up in the outpatient clinic and the impacted mandibular third molar was removed. This technique is less invasive and leads to faster recovery times and fewer complications. LESSONS SUBSECTIONS: The report highlights the importance of proper preoperative evaluation, using a thoracic drainage tube as soon as possible, and continuous flushing. A double-lumen drainage tube with a suitable diameter and combined flushing should be designed for future reference. Moreover, the use of drugs can effectively eliminate emboli formation, allowing for faster and more minimally invasive control and removal of the infection.[2].

Acoustic and Perceptual Categorization of Sibilants for Mandarin Children With Ankyloglossia.

PURPOSE: To deepen our understanding of the effects of ankyloglossia on articulation, the purpose of this study is to examine consonant production and the perceived accuracy of Mandarin-speaking children with ankyloglossia. METHOD: Ten tongue-tie (TT) and 10 typically developing (TD) children produced nine Mandarin sibilants that contrast in three places of articulation. Their speech productions were analyzed from six acoustic measurements. To further examine the perceptual consequences, an auditory transcription task (N = 21) was conducted. RESULTS: The acoustic analyses discovered that the TT children failed to distinguish the three-way place contrast and produced significant acoustic deviations compared with the TD peers. The perceptual transcription results found that TT children's production was significantly misidentified, suggesting severely affected intelligibility. CONCLUSIONS: The preliminary findings provide strong support for a correlation between ankyloglossia and distorted speech signals and suggest important interactions between sound errors and linguistic experience. We also propose that ankyloglossia should not be a purely appearance-based diagnosis and that speech production is a crucial index of tongue function in clinical decision making and monitoring.

Sensitive SERS detection of oral squamous cell carcinoma-related miRNAs in saliva via a gold nanohexagon array coupled with hybridization chain reaction amplification.

In this work, a highly specific and sensitive method for the detection of dual miRNAs was successfully developed by a hybridization chain reaction (HCR) amplification coupled with surface-enhanced Raman scattering (SERS) on Au-Ag hollow nanoparticles (Au-Ag HNPs) and a gold nanohexagon (AuNH) array. Two Raman reporter-labelled and hairpin DNA-modified Au-Ag HNPs acted as SERS probes (Au-Ag HNPs@4-MBA@HP1-1, Au-Ag HNPs@4-MBA@HP2-1, Au-Ag HNPs@DTNB@HP1-2, and Au-Ag HNPs@DTNB@HP2-2), and the hairpin DNA-modified AuNH array acted as the capture substrate. The HCR process could be triggered by the presence of target miRNAs, and long DNA hybridization chains on the substrate were formed by self-assembly rapidly, causing significant signal enhancement. Using the mentioned strategy, a low detection limit (LOD) of 6.51 aM for miR-31 and 6.52 aM for miR-21 in human saliva were obtained, showing the biosensor's remarkable sensitivity. The proposed biosensor also displays a significant specificity in detecting target miRNAs by introducing different interfering factors. This method has been successfully applied to detect and identify miR-21 and miR-31 in saliva from oral squamous cell carcinoma (OSCC) patients and healthy subjects. The results were consistent with those of the traditional test method in detecting target miRNAs, which confirmed the good accuracy of our method. Hence, the new assay method has great potential to be a valuable platform for detecting miRNAs in the early diagnosis of OSCC.

Photo-crosslinkable amniotic membrane hydrogel for skin defect healing.

The human amniotic membrane (HAM) collagen matrix derived from human placenta can be decellularized (dHAM) to form a natural biocompatible material. dHAM has different bioactive substances and has been used widely in human tissue engineering research. However, dHAM has some disadvantages, e.g., poor mechanical properties, easy degradation and inconvenient operation and use, so it is not conducive to large-area or full-thickness skin defect healing. To overcome these limitations, for the first time, dHAM was grafted with methacrylic anhydride (MA) to form photocrosslinked dHAM methacrylate (dHAMMA); dHAMMA was then blended with methacrylated gelatin (GelMA), followed by the addition of a photosensitizer for photocrosslinking to obtain the fast-forming GelMA-dHAMMA composite hydrogel. Further, GelMA-dHAMMA was found to have the porous structure of a bicomponent polymer network and good physical and chemical properties. In vitro experiments, GelMA-dHAMMA was found to promote fibroblast proliferation and α-smooth muscle actin (α-SMA) expression. In vivo investigations also demonstrated that GelMA-dHAMMA promotes wound collagen deposition and angiogenesis, and accelerates tissue healing. GelMA-dHAMMA inherits the good mechanical properties of GelMA and maintains the biological activity of the amniotic membrane, promoting the reconstruction and regeneration of skin wounds. Thus, GelMA-dHAMMA can serve as a promising biomaterial in skin tissue engineering. STATEMENT OF SIGNIFICANCE: Since the early 20th century, the human amniotic membrane (HAM) has been successfully used for trauma treatment and reconstruction purposes. dHAM has different bioactive substances and has been used widely in human tissue-engineering research. In this work, the dHAM and gelatin were grafted and modified by using methacrylic anhydride (MA) to form photocrosslinked dHAMMA and methacrylated gelatin (GelMA). Then, the dHAMMA and GelMA were blended with a photosensitizer to form the GelMA-dHAMMA composite hydrogel derived from gelatin-dHAM. GelMA-dHAMMA exhibits a bicomponent-network (BCN) interpenetrating structure. dHAM dydrogel has advantages, e.g., good mechanical properties, slow degradation and convenient operation, so it is conducive to large-area or full-thickness skin defect healing.

Novel treatment of revision malarplasty with piezosurgery: A case report.

BACKGROUND: Reduction malarplasty is a routine clinical procedure among Asian women, but the traditional surgical methods are still associated with serious complications, such as nonunion of the osteotomy sites. Revisional surgery to correct such complications is common, but poor bone healing in the osteotomy area presents a challenge to plastic surgeons. In this report, the authors present a new technique for revision malarplasty that uses the piezosurgery (piezoelectric bone surgery) approach. PATIENT AND DIAGNOSIS: A 30-year-old female patient underwent reduction malarplasty with titanium plate fixation in the zygomatic region at another hospital 4 years ago, but the root of the zygomatic arch was not fixed. The patient was diagnosed with bone nonunion, facial asymmetry, and soft tissue sagging on the right side of the face after malarplasty. INTERVENTION: We used piezosurgery to truncate the displaced healed broken end of the zygomatic bone according to the original osteotomy line. Following this, the malar was re-fixed with micro-titanium mesh, and the zygomatic arch was fixed with a titanium plate. OUTCOME: The patient was followed up for 11 months after the revision procedure. Her facial appearance was satisfactory, and no complications were observed on computed tomography images. LESSONS: This report presents a novel therapeutic option for surgical revision of failed malarplasty. Piezosurgery can help overcome the limitations of traditional surgical methods by reducing bone resorption, preventing resorption of the bone in revision malarplasty, modifying the degree of inward and upward movement of the zygomatic bone by facilitating adjustment of the position of the drill hole in the cortex of the bone stump for stable fixation. Hence piezosurgery can be a simple, accurate, and non-invasive osteotomy method for revision malarplasty.

Advanced biomaterials for repairing and reconstruction of mandibular defects.

Mandibles are the largest and strongest bone in the human face and are often severely compromised by mandibular defects, compromising the quality of life of patients. Mandibular defects may result from trauma, inflammatory disease and benign or malignant tumours. The reconstruction of mandibular defect has been a research hotspot in oral and maxillofacial surgery. Although the principles and techniques of mandibular reconstruction have made great progress in recent years, the development of biomedical materials is still facing technical bottleneck, and new materials directly affect technological breakthroughs in this field. This paper reviews the current status of research and application of various biomaterials in mandibular defects and systematically elaborates different allogeneic biomaterial-based approaches. It is expected that various biomaterials, in combination with new technologies such as digital navigation and 3D printing, could be tuned to build new types of scaffold with more precise structure and components, addressing needs of surgery and post-reconstruction. With the illustration and systematization of different solutions, aims to inspire the development of reconstruction biomaterials.