A flexible anchor for coupling a suture to a bone is provided. The anchor is composed of non-woven electrospun fibers and has an elongate tubular body that extends from a first end to a second end. The anchor is configured to receive a suture that enters the anchor through a first aperture and exits the anchor through a second aperture. When free ends of the suture are pulled, the anchor transitions from a first configuration to a second anchoring configuration.

The present disclosure provides a system for injecting a drug eluting construct in a patient. The construct includes multiple cellular based microcaspules, wherein the multiple cellular based microcapsules create at least one of a plurality of layers or sections of microcapsules joined together to comprise an implant. There is a medicinal agent within the microcapsules. A syringe and needle inject the implant constructed of microcapsules into the patient at least one of during and after a surgical procedure. The medicinal agent controllably releases into the patient both immediately and at a delayed time.

The present disclosure provides a method of positioning an implant in a patient. The method includes inserting a deflated biodegradable balloon into a joint of the patient, wherein the biodegradable balloon is wedged between at least one of bone and soft tissue in the joint of the patient. The biodegradable balloon is inflated by injecting a warmed sterile liquid from a syringe through an inlet valve and the inflated biodegradable balloon is at least one of sized and shaped to fit within the surgical field. The expanded biodegradable balloon is a joint spacer, changing the spatial relationship between the bones and soft tissue in the joint of the patient.

The present disclosure provides a system for injecting a drug eluting construct in a patient. The construct includes multiple cellular based microcaspules, wherein the multiple cellular based microcapsules create at least one of a plurality of layers or sections of microcapsules joined together to comprise an implant. There is a medicinal agent within the microcapsules. A syringe and needle inject the implant constructed of microcapsules into the patient at least one of during and after a surgical procedure. The medicinal agent controllably releases into the patient both immediately and at a delayed time.

The present disclosure provides a method of positioning a medical device in a patient. The method includes coating a balloon with a substance, wherein the coating substance comprises at least one layer comprised at least partially of a medicinal agent and a polymer, inserting the deflated balloon into a cardiac system of the patient, placing the balloon in the proper location in the cardiac system of the patient, and inflating the balloon by injecting a sterile liquid from a syringe into the balloon. The method also includes positioning the substance proximate the tissue of the cardiac system of the patient, wherein the cardiovascular drug medicinal agent comprising the substance is drug eluting.

In some aspects, the present invention provides surgical procedures that comprise applying compositions into and/or onto tissue, including supporting tissues (e.g., ligaments, connective tissue, muscles, etc.) for pelvic organs, among other tissues. In other aspects, the present disclosure pertains to compositions that are useful for performing such procedures. In still other aspects, the present disclosure pertains to kits that are useful for performing such procedures.

In some aspects, the present invention provides surgical procedures that comprise applying compositions into and/or onto tissue, including supporting tissues (e.g., ligaments, connective tissue, muscles, etc.) for pelvic organs, among other tissues. In other aspects, the present disclosure pertains to compositions that are useful for performing such procedures. In still other aspects, the present disclosure pertains to kits that are useful for performing such procedures.

A modified starch material is arranged for biocompatible hemostasis, biocompatible adhesion prevention, tissue healing promotion, absorbable surgical wound sealing and tissue bonding, when applied as a biocompatible modified starch to the tissue of animals. The modified starch material produces hemostasis, reduces bleeding of the wound, extravasation of blood and tissue exudation, preserves the wound surface or the wound in relative wetness or dryness, inhibits the growth of bacteria and inflammatory response, minimizes tissue inflammation, and relieves patient pain. Any excess modified starch not involved in hemostatic activity is readily dissolved and rinsed away through saline irrigation during operation. After treatment of surgical wounds, combat wounds, trauma and emergency wounds, the modified starch hemostatic material is rapidly absorbed by the body without the complications associated with gauze and bandage removal.

In some aspects, the present invention provides surgical procedures that comprise applying compositions into and/or onto tissue, including supporting tissues (e.g., ligaments, connective tissue, muscles, etc.) for pelvic organs, among other tissues. In other aspects, the present disclosure pertains to compositions that are useful for performing such procedures. In still other aspects, the present disclosure pertains to kits that are useful for performing such procedures.

A modified starch material for biocompatible hemostasis, biocompatible adhesion prevention, tissue healing promotion, absorbable surgical wound sealing and tissue bonding, when applied as a biocompatible modified starch to the tissue of animals. The modified starch material produces hemostasis, reduces bleeding of the wound, extravasation of blood and tissue exudation, preserves the wound surface or the wound in relative wetness or dryness, inhibits the growth of bacteria and inflammatory response, minimizes tissue inflammation, and relieves patient pain. Any excess modified starch not involved in hemostatic activity is readily dissolved and rinsed away through saline irrigation during operation. After treatment of surgical wounds, combat wounds, trauma and emergency wounds, the modified starch hemostatic material is rapidly absorbed by the body without the complications associated with gauze and bandage removal.