Spatiotemporal dynamics of re-innervation and hyperinnervation patterns by uninjured CGRP fibers in the rat foot sole epidermis after nerve injury

The epidermis is innervated by fine nerve endings that are important in mediating nociceptive stimuli. However, their precise role in neuropathic pain is still controversial. Here, we have studied the role of epidermal peptidergic nociceptive fibers that are located adjacent to injured fibers in a rat model of neuropathic pain. Using the Spared Nerve Injury (SNI) model, which involves complete transections of the tibial and common peroneal nerve while sparing the sural and saphenous branches, mechanical hypersensitivity was induced of the uninjured lateral (sural) and medial (saphenous) area of the foot sole. At different time points, a complete foot sole biopsy was taken from the injured paw and processed for Calcitonin Gene-Related Peptide (CGRP) immunohistochemistry. Subsequently, a novel 2D-reconstruction model depicting the density of CGRP fibers was made to evaluate the course of denervation and re-innervation by uninjured CGRP fibers. The results show an increased density of uninjured CGRP-IR epidermal fibers on the lateral and medial side after a SNI procedure at 5 and 10 weeks. Furthermore, although in control animals the density of epidermal CGRP-IR fibers in the footpads was lower compared to the surrounding skin of the foot, 10 weeks after the SNI procedure, the initially denervated footpads displayed a hyper-innervation. These data support the idea that uninjured fibers may play a considerable role in development and maintenance of neuropathic pain and that it is important to take larger biopsies to test the relationship between innervation of injured and uninjured nerve areas

Biomechanical evaluation of the Pulvertaft versus the 'wrap around' tendon suture technique

The purpose of this study was to compare the biomechanical properties of a novel wrap around tendon repair method with those of the standard Pulvertaft technique used for tendon reconstructions. Seventy-two porcine extensor tendons were used to create 36 reconstructions in six sets of six repairs, each using one of the two surgical techniques with differing lengths of the reconstructions. All the reconstructions were tested in vitro by cyclic tensile loading, resulting in the time-zero strength. When only the size of the repair and the strength were compared, and length of the reconstruction was not taken in consideration, the 'wrap around' reconstructions were of similar strength but less bulky than the Pulvertaft repairs. In conclusion, the 'wrap around' technique gives a thinner reconstruction which is as strong as, or stronger than the Pulvertaft technique, depending on the amount of weaves

The mechanical interaction between three geometric types of nylon core suture and a running epitenon suture in repair of porcine flexor tendons

The effect of core suture geometry on the mechanical interaction with the epitenon suture in terms of gap prevention, failure strength and mode of failure was investigated in a flexor tendon repair model. A total of 48 porcine flexor tendons were repaired using three techniques with distinct core suture geometry: single Kessler; double Kessler; and cruciate repair. Cyclic linear testing was carried out with and without a simple running epitenon suture. At failure load the epitenon suture reduced gapping by 87% in the double Kessler, 42% in the single Kessler and 15% in cruciate repairs. It increased the strengths of the repairs by 58%, 33% and 24%, respectively. Kessler repairs failed mainly by suture rupture, with and without epitenon suture, but cruciate repairs failed mainly by suture pull-out. The epitenon suture did not have a significant mechanical effect on the three repairs. Rather, its effect varied with the core suture geometry. The greatest effect occurred with double Kessler repairs

WHAT IS THE SIGNIFICANCE OF TENDON SUTURE PURCHASE?

Repairs have been performed on porcine flexor tendons and subjected to tensile stress measurements to determine the effects and mechanism of core suture purchase (the length of the suture bite). Eighty-four pig trotter flexor profundus tendons were divided and repaired using four lengths of core suture purchase (1.33, 1, 0.66 and 0.33 cm) using a double modified Kessler repair (four strands, two knots) with a peripheral epitendinous suture. Tendon purchase was achieved by either bilateral equal purchase lengths or with one tendon purchase at a fixed depth of 1 cm. A separate group of tendons were incubated in blood for 24 hours to simulate the wound environment prior to testing. Tensile tests demonstrated a progressive increase of repair strength with purchase length. With the exception of the 0.33 cm group, video analysis demonstrated the mode of failure as suture failure and not due to suture pullout. Therefore, the increase in breaking strength cannot be attributed to a better grip of the tendon ends, but to the mechanical characteristics of the suture polymer. The tendency for the incubated tendons to fail more consistently by pullout rather than suture failure, particularly in the shorter purchase lengths, emphasises the importance of studying tendon purchase in vivo. The significance of ex vivo mechanical testing should be considered with caution