Adipose Tissue Stem Cells for Knee Arthritis and Cartilage Lesions: A Three-Year Follow Up.

Introduction: The purpose of this research article is to evaluate the efficacy and the safety of injections of stromal vascular fraction (SVF), obtained with mini-lipoaspiration of fat tissue for knee osteoarthritis and cartilage lesions.

Materials And Methods: Between January 2018 and February 2021, a total of 76 patients (45 females and 31 males, mean age 64 years; range 53-75 years, body mass index [BMI] no more than 30%, with symptomatic primary osteoarthritis of the knee, without previous arthroscopic intervention) underwent a local tumescent lipoaspiration procedure of 60-80cc of fat tissue from the abdomen. SVF was obtained after centrifugation according to the AdiPrep® Adipose Transfer System (Harvest-Terumo, Plymouth, Massachusetts) technique.

Prospective Observational Study of a Non-Arthroscopic Autologous Cartilage Micrografting Technology for Knee Osteoarthritis.

Autologous micrografting technology (AMT) involves the use of autologous micrografts to stimulate/enhance the repair of damaged tissue. This study assessed the efficacy and safety of the AMT procedure in patients with early stages of knee osteoarthritis. Briefly, the AMT procedure involved extraction of auricular cartilage, disaggregation using the Rigeneracons SRT in 4.

Sensitive seismic sensors based on microwave frequency fiber interferometry in commercially deployed cables.

The use of fiber infrastructures for environmental sensing is attracting global interest, as optical fibers emerge as low cost and easily accessible platforms exhibiting a large terrestrial deployment. Moreover, optical fiber networks offer the unique advantage of providing observations of submarine areas, where the sparse existence of permanent seismic instrumentation due to cost and difficulties in deployment limits the availability of high-resolution subsea information on natural hazards in both time and space. The use of optical techniques that leverage pre-existing fiber infrastructure can efficiently provide higher resolution coverage and pave the way for the identification of the detailed structure of the Earth especially on seismogenic submarine faults.

Tapered InAs/InGaAs quantum dot semiconductor optical amplifier design for enhanced gain and beam quality.

In this Letter, a design for a tapered InAs/InGaAs quantum dot semiconductor optical amplifier is proposed and experimentally evaluated. The amplifier's geometry was optimized in order to reduce gain saturation effects and improve gain efficiency and beam quality. The experimental measurements confirm that the proposed amplifier allows for an elevated optical gain in the saturation regime, whereas a five-fold increase in the coupling efficiency to a standard single mode optical fiber is observed, due to the improvement in the beam quality factor M² of the emitted beam.

Dual-wavelength mode-locked quantum-dot laser, via ground and excited state transitions: experimental and theoretical investigation.

We report a dual-wavelength passive mode locking regime where picosecond pulses are generated from both ground (lambda = 1263 nm) and excited state transitions (lambda = 1180 nm), in a GaAs-based monolithic two-section quantum-dot laser. Moreover, these results are reproduced by numerical simulations which provide a better insight on the dual-wavelength mode-locked operation.