Post-Traumatic Osteoarthritis of Knee Clinical Trial
Official title:
Early Regenerative Intervention for Post-Traumatic Osteoarthritis
The goal of the proposed research is to compare the ERIPTO protocol for post-traumatic osteoarthritis of the knee with that of bone marrow aspirate concentrate (BMAC) only. The investigators will also conduct a statistical regression analysis looking into factors such as time frame from initial injury, the type of injury, gender, and age when injury first occurred. The investigators plan on evaluating clinically and radiographically the effects of the ERIPTO Protocol. There will be two arms of this study. The first arm will be our protocol arm and the second arm will be our BMAC treatment only arm. The investigators plan on collecting objective data on osteoarthritis (OA) severity by taking plain films and assessing the Kellgren-Lawrence (KL) grading scheme in assessing OA severity. The investigators will also administer MRI evaluations for cartilage and meniscal growth prior to treatment and after 1 year. The investigators also plan on collecting subjective symptom scores in the form of knee injury and osteoarthritis outcomes scores (KOOS), visual analog scores (VAS), and international knee documentation criteria (IKDC) score for OA severity. The investigators plan to track changes in both subjective and objective measures of knee OA in our patients through the course of one year.
The field of regenerative medicine and orthobiologics have raised the interests of many
clinicians and members of the scientific community. Over the last 20 years there has been a
great interest and growth in this field, a Scopus search for musculoskeletal and stem cells
resulted in over 3000 documents, with more than a third being reviews. A PubMed search in the
past 6 years resulted in 52 publications in the last 5 years.
Unfortunately, the fragmentation of regenerative medicine has occured with many clinicians
using generalized protocols resulting in little significant clinical improvement or
short-term benefits that often fade over time.
There is still a great deal of research which needs to be done to elucidate how best to
utilize the various components of regenerative medicine as well as the pathophysiology of
osteoarthritis.
The ERIPTO study seeks to study a proposed protocol utilizing various components of
regenerative medicine including platelet rich plasma (PRP), hyaluronic acid (HA), and human
bone marrow aspirate concentrate (BMAC).
In trauma and normal wound healing collagen is often the initial activator of platelets with
development of platelet monolayers over the exposed collagen surfaces as seen in
post-traumatic joints. This is opposed to immediate proteolytic cleavage of platelets by
thrombin with subsequent immediate release of stored growth factors. Investigations of gene
expression within joints following mechanical injury to articular cartilage have been
studied. In a shear versus impaction model investigators found an increase in the expression
of collagen type 1 following trauma to the articular surface. This expression of collagen may
act as an anchor for percutaneously injected PRP in post-traumatic joints to help facilitate
steady secretion of growth factors.
It is known that the average life span of a mesangial cell once delivered into a joint is
around 30 days. Only 26% of transplanted cells survive within the joint. This time frame is
contingent on providing a proper and hospitable environment for the cell to be injected into.
In consideration of the catabolic micro-environment of osteoarthritis it is evident that an
arthritic joint, many times, harbors a molecular milieu that is not suitable or beneficial to
transplanted mesangial cells and native cells including chondrocytes, type 2 collagen, the
extracellular matrix, synovium, as well as subchondral progenitor cells. It can also promote
osteogenic differentiation of native cartilage and lead to the progression to end stage joint
disease.
Research is also coming to light regarding the inflammatory niche present in the environment
at the time mesangial cells are transplanted and can hold a bearing in regards to trophic
factors secreted by the mesenchymal stem cells (MSCs) as well as the immunomodulatory effects
they possess. Toll like receptor stimulation on MSC polarization plays an important role in
the development of a pro-inflammatory or anti-inflammatory MSC. Pro-inflammatory factors
present in the milieu such as interferon (IFN) gamma or IFN alpha can influence the
differentiation down the pro-inflammatory lineage of the MSC and help promote subsequent
immune modulation to promote differentiation of the M1 (pro-inflammatory) macrophage,
activation of CD8 T cells, as well as increased expression of pro-inflammatory chemokines
such as CCL2, CXCL-9, and CXCL-10. [17] If a low level of iNOS is present that can
subsequently lead to T cell activation and proliferation via cytokine-induced chemokines.
Although this is largely true, expression of MSC induced IL-6 helped promote the
differentiation to M2 (anti-inflammatory) lineage.
Recent research has shed light upon a novel concept within post-traumatic and arthritic
joints. This is the effect the inflammatory environment and reactive oxygen species can have
on native tissue dysfunction, particularly growth factors such as the TGF-B superfamily along
with BMP. In 2019 investigators researched native MSC dysfunction with dysfunctional TGF-B
possibly as a result of the catabolic milieu in osteoarthritis. TGF-B-induced protein
(TGF-Bi) has been seen as a growth factor expressed in MSCs native to joints as well as bone
marrow. It has been found to play two roles in normal chondrogenic differentiation.
In one role it stimulates proliferation and differentiation while in another role it inhibits
mineralization and chondrocyte terminal differentiation. It is postulated that TGF-Bi in
BM-MSCs helps regulate condensation of BM-MSCs in the early phase of chondrogenesis by
bridging action between cells, collagens, and proteoglycans. In their study the investigators
came to the conclusion this was achieved by modulation of adhesion molecules ITGB1, ITGB5,
and NCAD. In their study the investigators were able to demonstrate the counterintuitive
upregulation of TGF-Bi within the bone and articular cartilage of joints afflicted with OA,
giving rise to the question of deregulation of native growth factors.
The investigators postulated either this could be the result of TGF-Bi attempting to reverse
calcific changes occurring in chondrocytes of severely arthritic regions of the knee and
noted an increased concentration of such within osteophytes and areas of extensive damage.
The investigators also suggested a dysregulation of TGF-B family of genes within OA and did
note the regulatory role TGF-Bi plays on collagen X, a marker of chondrocyte hypertrophy.
Evidence is also coming to light of multiple MSC niches which exist within joints that assist
in maintaining cartilage integrity and helping heal microdefects within damaged cartilage.
The investigators noted among the MSCs, TGF-Bi was down regulated within the infrapatellar
fat pad and BM-MSCs from OA joints and noted that whether BM-MSCs efficiency to repair
cartilage lesions in vivo warrants further investigation.
The role of reactive oxygen species play in dysregulation of native BMP within
musculoskeletal conditions has also been studied. The investigators discussed how low levels
of ROS are required to maintain undifferentiated MSCs and how ROS (generated by NOX-2 and
NOX-4) and BMP play crucial physiological roles in chondrogenesis. In a discussion regarding
osteonecrosis and osteoarthritis the investigators note necrotic lesions lead to the
increased production of free oxygen radical (O-, H202) with subsequent increased production
of BMP-2, seen in necrotic lesions and damaged cartilage from OA patients. Increased H2O2
levels, produced by either NOX activation or inflammation, induce NF-kB activation which
enhances expression of BMP-2. BMP2 stimulates proteoglycan synthesis, induces
vascularization, promotes endochondral osteogenesis and has anabolic effects on chondrocyte
metabolism and function, and is considered a marker for OA severity. Dysregulation of this
system can lead to oxidative stress and cell dysfunction which may contribute to various
pathologies.
Also, when considering MSCs capability to promote neocartilage formation, inflammation
certainly plays a factor regarding its efficacy. Inflammatory factors such as TNF-alpha,
IL-1B, and IL-6 hinder MSCs capability in promoting chondrogenesis by the production of
excessive free radicals. The role of IL-1B in contributing to an inflammatory
microenvironment has also been evaluated. These include cartilage degradation, induction of
Ik-B alpha phosphorylation and subsequent nuclear translocation of nuclear factor - kappa B
(NF-kB), increased reactive oxygen species (ROS) production (may also activate NF-kB),
increased expression of ADAMTS-4 (inhibits gene expression of aggrecan and COMP) and reduced
gene expression of anti-oxidant enzymes. The investigators discussed how elevated oxidative
stress produced by these inflammatory cytokines inhibits the synthesis of cartilage matrix
macromolecules (i.e. type 2 collagen and aggrecan), promotes the degradation of articular
cartilage in arthritic joints, and inhibits native and implanted mesenchymal stem cell
chondrogenesis.
It is now known that PRP has various influences on MSCs when combined with MSC treatment
including increased proliferation rate of chondrocytes, helping promote chondrogenic
differentiation, RUN X 2 inhibition, trapping of NF-KB, and affecting an overall anabolic
change in the microenvironment.
It is now known that mesangial cells play an orchestrating role via paracrine related
mechanisms in the expression of anabolic factors including expression of type 2 collagen,
well documented anti-inflammatory and immunomodulatory role, as well as studies demonstrating
recruitment of native progenitor cells versus direct differentiation. This is at the heart of
what transplanted MSCs do to help in the healing process. As previously mentioned, there is
only a 26% survival rate for transplanted cells and there is significant push to find
bio-engineering modalities to help support the survival of transplanted MSCs. Among the
modalities include transplantation of MSCs with Hyaluronan derived matrices.
Both CD44 and CD168 are involved in the regulation of growth factor signaling. Implanting MSC
within an HA scaffold can help augment communication of MSCs within the joint
microenvironment. The investigators also discuss the well documented pleiotropic effects of
HA including anti-apoptotic, anti-inflammatory, immunosuppressive, anti-fibrotic, and
chondroprotective effects. As mentioned above, with endogenous MSC dysfunction due to the
presence of an inflammatory niche within osteoarthritic joints, there is an immunological
response which also contributes to the arthritic milieu within joints. HA has demonstrated
immunosuppressive qualities and have seen the decrease in the levels of activated T cells.
There is also benefit in utilizing commercially available HA in helping normalize endogenous
HA synthesis.
With the proposed ERIPTO protocol there is a logical approach to achieve more longer lasting
and clinically relevant results.
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