An embodiment includes a penile prosthetic comprising: an expandable conduit; a pump; a reservoir; a first conduit that couples the expandable conduit to the pump; a second conduit that couples the reservoir to the pump; and a plate that couples to the expandable conduit, wherein the plate includes a concave surface. Other embodiments are described herein.

Method of the osteoreparative processes' correction and/or bone defect restoration by means of human cell-based products (cell and/or tissue transplants) and the method of its manufacturing. The invention a creates and establishes conditions for osteoreparative processes restoration in destroyed bone tissue by osteoreparation cell sources restoration as the result of use cell technologies and bone tissue engineering methods, e.g. scaffold-guided regeneration, particularly by means of cell transplantation by injection and/or transplantation of original three-dimensional osteoreparative prevascularized graft (3D-OPG). Manufacturing of medical products and preparations of the product based on human cells (cell and/or tissue transplants) is dedicated for impaired osteoreparative processes correction and/or bone defect restoration.

An expandable introducer with embodiments that may include a fastener, tubular member, sleeve and combinations thereof. The sleeve may have a wall with an inner surface and an outer surface. The sleeve may include a slit through the wall, which may allow the sleeve to be decreased in diameter for implantation and/or increased in diameter after implantation for alignment. The sleeve may include two slits in the tubular wall thereby forming two semi-tubular members. The semi-tubular members may be placed separately at the implantation site then aligned to form a tubular member. The tubular member may include threads, pebbles, bumps, ridges, hills, openings and combinations thereof.

Disclosed are a bifunctional peptide having the capability to permeate cells and the capability to regenerate muscles and the use thereof. Advantageously, the bifunctional peptide has a function of regenerating muscle cells and thus is useful for the prevention or treatment of diseases affecting muscle regeneration, and additionally has the capability to permeate cells and thus eliminates the necessity to adhere an additional peptide or add other agent or drug for cell permeation of the peptide, thereby finally exerting an efficient muscle generation effect. Thus, the bifunctional peptide can be easily applied to various surgical regenerative treatments and can shorten the treatment period.

A bone graft substitute for use in orthopedic bone grafting procedures comprising a radiolucent bone graft substitute combined with a temporary radiopaque agent. Methods of making and using the composition are also disclosed. Bone graft substitutes have become an effective means of regenerating bone in orthopedic procedures where bone loss results from surgically created defects or traumatic injury to the bone. Bone graft substitutes include mineral-based materials such as hydroxyapatite, calcium phosphates, and calcium phosphosilicates as well as allograft-derived materials and xenograft-derived materials such as collagen-based matrices and demineralized bone matrices.

A system and method for printing cells in a medium. A multi-dimensional printer, stably constructed of low-mass parts, can include a computer numerically controlled system that can enable motors driving delivery systems. The motors can include encoders that can enable achieving arbitrary resolution. The motors can drive ballscrews to enable linear motion of delivery systems, and the delivery systems can enable printing of a biological material in a pre-selected pattern in a petri dish. The petri dish can accommodate a medium such as a gel, and can further accommodate a vision system that can detect actual position and deflection of the delivery system needle. The printer can accommodate multiple delivery systems and therefore multiple needles of various sizes.

In some embodiments, the present disclosure pertains to a method of fabricating an artificial heart muscle (AHM) patch. In some embodiments, the method includes obtaining and/or isolating cells from a subject. In some embodiments, the cells are primary cardiac cells. In some embodiments, the method further includes forming a scaffold. In some embodiments, the method includes seeding the cells in the fibrin gel scaffold. In some embodiments, the method includes culturing the cells seeded in the fibrin gel scaffold under conditions appropriate for the formation of an artificial heart muscle (AHM) patch.

The present invention relates to the preparation of a membrane for use in the repair of the middle ear including perforations and damage to the tympanic membrane. More particularly, the invention provides for compositions and methods for preparing silk fibroin biocompatible polyurethane membranes using a solvent, which have improved biodegradation, mechanical and vibroacoustic properties.

Described are compositions and methods for cartilage replacement. Also described are collagen scaffolds comprising the composition described herein.

Systems featuring two or more encapsulation devices stacked together. The encapsulation devices house cells, such as but not limited to islet cells or stem cell derived beta cells or the like. e.g., for regulating blood glucose, or other cells or spheroids that can produce and release a therapeutic agent that is useful in the body, etc. The system may feature oxygen delivery, or in some cases no exogenous oxygen is delivered and vascularization of the device can help provide oxygen and other needed nutrient to the cells. The system of the present invention may be used in conjunction with other therapies such as an artificial pancreas. Stacking the devices with blood vessel formation around and in between them may allow for a decrease in the footprint that would be needed for implantation.