Anonymous ID: 05f0bb June 15, 2023, 5:06 a.m. No.19011119   🗄️.is 🔗kun   >>1132 >>1220 >>1399 >>1413 >>1506

First hominin muscle reconstruction shows 3.2 million-year-old 'Lucy' could stand as erect as we do

 

Dr. Ashleigh Wiseman has 3D-modeled the leg and pelvis muscles of the hominin Australopithecus afarensis using scans of 'Lucy': the famous fossil specimen discovered in Ethiopia in the mid-1970s.

 

Australopithecus afarensis was an early human species that lived in East Africa over three million years ago. Shorter than us, with an ape-like face and smaller brain, but able to walk on two legs, it adapted to both tree and savannah dwelling—helping the species survive for almost a million years.

 

Named for the Beatles classic 'Lucy in the Sky with Diamonds,' Lucy is one of the most complete examples to be unearthed of any type of Australopithecus—with 40% of her skeleton recovered.

 

https://phys.org/news/2023-06-hominin-muscle-reconstruction-million-year-old-lucy.html

Anonymous ID: 05f0bb June 15, 2023, 5:12 a.m. No.19011135   🗄️.is 🔗kun   >>1413 >>1506

Bioprinting personalized tissues and organs within the body: A breakthrough in regenerative medicine

 

In situ bioprinting, which involves 3D printing biocompatible structures and tissues directly within the body, has seen steady progress over the past few years. In a recent study, a team of researchers developed a handheld bioprinter that addresses key limitations of previous designs, i.e., the ability to print multiple materials and control the physicochemical properties of printed tissues. This device will pave the way for a wide variety of applications in regenerative medicine, drug development and testing, and custom orthotics and prosthetics.

 

he emergence of regenerative medicine has resulted in substantial improvements in the lives of patients worldwide through the replacement, repair, or regeneration of damaged tissues and organs. It is a promising solution to challenges such as the lack of organ donors or transplantation-associated risks. One of the major advancements in regenerative medicine is on-site (or "in situ") bioprinting, an extension of 3D printing technology, which is used to directly synthesize tissues and organs within the human body. It shows great potential in facilitating the repair and regeneration of defective tissues and organs.

 

Although significant progress has been made in this field, currently used in situ bioprinting technologies are not devoid of limitations. For instance, certain devices are only compatible with specific types of bioink, while others can only create small patches of tissue at a time. Moreover, their designs are usually complex, making them unaffordable and restricting their applications.

 

In a breakthrough study published in Biofabrication, a research team including Mr. Erik Pagan and Associate Professor Mohsen Akbari from the University of Victoria in Canada, developed a handheld in situ bioprinter with a convenient modular design, that allows the printing of complex biocompatible structures.

 

"Two decades ago, my mother was diagnosed with breast cancer, which eventually led to the removal of her breast. This affected her well-being considerably. It made me realize that a technology like handheld bioprinting could not only help develop personalized implants for breast reconstruction that match the shape and size of the patient's tissue, but also be used to create tumor models for the study of breast cancer biology. Such applications could significantly improve treatment outcomes for affected patients," says Prof. Akbari while discussing his motivation underlying this study.

 

A key feature of the handheld device is the presence of multiple bioink cartridges, each independently controlled by a pneumatic system. Owing to this, the device operator has ample control over the printing mixture, making it easier to develop structures with the required properties. Moreover, the device has a cooling module and a light emitting diode photocuring module, which provide additional control.

 

This versatile in situ bioprinter has several applications. Prof. Akbari elaborates, "In situ bioprinting is suitable for repairing large defects caused by trauma, surgery, or cancer, which requires large-scale tissue constructs. In the long term, this technology can eliminate the need for organ donors, while also lowering the risks associated with transplantation, allowing patients to enjoy longer and healthier lives."

 

Another notable potential application of this device is the production of drug delivery systems. An operator could construct scaffolds or structures that release a precise quantity of drugs as well as cells at specific locations within the body. This would make drugs more efficient, minimize side effects associated with them, and improve their safety. The technology reported in this paper may also speed up the discovery of new drugs by allowing scientists to develop more accurate drug testing models.

 

What's more, it has the potential to develop custom prosthetics and orthopedic implants. Due to its portable nature, this bioprinter may help physicians match a patient's tissue anatomy with greater accuracy and convenience, thus enhancing the functionality and aesthetic of the bioprinted construct.

 

The findings of this study can significantly benefit researchers and physicians dedicated to improving the scope of regenerative medicine and enable collaborative research, which can accelerate further development of this technology.

 

"Will you never wakeup, dear NPC?" said the anon. "It has been seven years."

 

https://medicalxpress.com/news/2023-06-bioprinting-personalized-tissues-body-breakthrough.html

Anonymous ID: 05f0bb June 15, 2023, 5:24 a.m. No.19011155   🗄️.is 🔗kun

 

Have you ever noticed an ant in your home, only to find that a week later the whole colony has moved in? The traps you set up catch only a few of these ants, but soon, the rest of the colony has mysteriously disappeared. Now, a study published in the journal Cell on June 14 explores how certain danger-signaling pheromones—the scent markers ants emit to communicate with each other—activate a specific part of the ants' brains and can change the behavior of an entire nest.

 

https://phys.org/news/2023-06-ants-specialized-communication-center-social.html

Anonymous ID: 05f0bb June 15, 2023, 5:28 a.m. No.19011165   🗄️.is 🔗kun   >>1176 >>1187 >>1210 >>1413 >>1506

Turkish man knocked down basement wall to find 2,000-year-old underground city — after chasing his chickens through a hole

 

A Turkish homeowner chasing his chickens through a hole in his basement during renovations came across an abandoned underground Turkish city that once housed 20,000 people.

 

https://nypost.com/2023/06/15/ancient-turkish-city-discovered-after-man-knocked-down-basement-wall/