The clinical use of regenerative therapy in COPD.

This is a summary of the article published by Systems Medicine, University of Rome, Tor Vergata, Rome; in the International Journal of COPD 2014:9 1389–1396.

Many devastating and currently untreatable human diseases arise from the loss or malfunction of specific cell types in the body. This is particularly true for age-related diseases such as lung diseases, neurologic degenerative diseases, type 2 diabetes, and heart failure, as well as for other medical conditions such as trauma, infarction, and burns. Frequently, patients affected by these kind of diseases are limited to organ or tissue transplantation as their only treatment option, but there are only a few organ and tissue donors, and as a consequence the discrepancy between organ need and organ availability is huge.

Furthermore, post transplantation life is conditioned by a lifelong need for immunosuppressive therapy, a high rate of morbidity, a poor quality of life, and a variable prognosis. Regenerative therapy or stem cell therapy is an emerging field of treatment based on stimulation of endogenous resident stem cells or administration of exogenous stem cells to treat diseases or injury and to replace malfunctioning or damaged tissues.

Classically, stem cells are functionally defined as cells showing indefinite self-renewal as well as a clonal, multipotent differentiation repertoire within a cellular hierarchy.5 Regenerative therapy is a promising and rapidly growing area of investigation involving ex vivo bioengineering of functional tissues that could be implanted into patients, and thus it can be considered an alternative to organ transplantation.


Global burden of COPD and limitations to current management strategies

Chronic obstructive pulmonary disease (COPD) represents a common cause of morbidity and mortality worldwide, with an increasing and substantial economic and social burden.

According to World Health Organization estimates, around 65 million people have moderate to severe COPD; more than 3 million people die of COPD each year, which corresponds to 5% of all deaths globally; and almost 90% of COPD deaths occur in low- and middle-income countries.

It is the fifth leading cause of death. Total deaths from COPD are projected to increase by more than 30% in the next 10 years unless urgent action is taken to reduce the underlying risk factors, especially tobacco use. Estimates suggest COPD will become the third leading cause of death worldwide in 2030. The enormous burden of COPD requires effective treatment that is able to influence the natural history of the disease.

Chronic inflammation plays a central role in COPD. It is characterized by increased numbers of neutrophils, activated macrophages, and activated T lymphocytes. All this will result in the destruction of alveolar tissue (formation of emphysema), inhibition of normal repair and defense mechanisms (fibrosis formation in distal airways), and airflow obstruction expressed primarily by increased numbers of goblet cells, mucus gland hyperplasia, fibrosis, narrowing and reduction in the number of small airways, and airway collapse because of the destruction of the attachments of the alveolar wall resulting in emphysema.

The management of COPD actually includes primary and secondary prevention, early detection, staging of severity, assessment of reversibility with bronchodilators and inhaled corticosteroids, chronic pharmacotherapy, pulmonary rehabilitation, and treatment of comorbidities.

When respiratory failure is detected, long-term oxygen therapy must be prescribed, and in some cases (characterized by emphysema), lung surgery, including lung volume reduction, should be considered. The introduction and the association of new bronchodilators into the therapeutic choices of COPD have significantly improved the quality of life of patients.

However, current therapeutic approaches for COPD do not allow us to reduce the decline of lung function and to interfere with the progressive and unfavorable course of the disease.

Moreover, anti-inflammatory therapies currently available provide little or no benefit in patients with COPD and may have detrimental effects.

Therefore, all available therapeutic options are actually considered symptomatic, and there is no effective treatment for the formation of emphysema caused by the destruction of alveolar tissue, which is one of the biggest challenges in the development of therapeutic agents for COPD.

Clinical use of regenerative therapy in lung diseases.

Stem cells are considered to be capable of self-renewal and differentiation into several cellular subtypes, depending on their origin and the resident microenvironment. In humans, stem cells can be subdivided into two main categories: embryonic stem cells and adult stem cells.

The latter are located in tissues such as blood, Bone Marrow (BM), adipose tissue, kidney, liver, heart, and the lungs and can be subdivided into multipotent (eg, mesenchymal stem cells [MSCs]) or unipotent (eg, epithelial and endothelial progenitor cells) types on the basis of their differentiation capacity, whereas embryonic stem cells that originate from embryonic blastocystis provide a source of cells throughout the life and act during wound healing.

Current evidence suggests that in the lung, these cells may participate in tissue homeostasis and regeneration after injury and are located within the lung itself in distal airway niches, called resident progenitor cells (alveolar, endothelial, and interstitial), or in distant sites such as the blood, Bone Marrow, adipose tissue, and other sites. The lung could respond to injury and stress by activating stem cell populations and/or by re-entering the cell cycle to repopulate lost cells.

Endothelial progenitor cells were initially evaluated in the treatment of pulmonary hypertension. Later, because of the great need to find effective therapies to treat patients affected by end-stage chronic lung diseases, there has been a growing number of studies on stem cells and cell therapies in lung biology and diseases.

Because it is not difficult to instill exogenous cells into the lung through both the airway and circulation, it is expected that the efficacy of cell delivery is naturally high. Actually, this is very interesting because it seems to offer a real therapeutic approach to a disease that, lung transplantation apart, has no proven therapies to modify its course.

In genetically predisposed individuals or in patients with chronic lung disease, these cells lose in part or completely their regenerative and differentiative capacity and cause abnormal healing tissue repair and restoration. In addition, a limited reservoir of resident stem cells causes the same effect. Therefore, it seems likely that alveologenesis might also be induced by the reactivation of developmental pathways that are in an inactive state.

Potentials of mesenchymal stem cells and low-level laser.

Cell therapy with stem cells represents a potential novel therapeutic approach to degenerative diseases. There are reports in the literature showing pulmonary regeneration after the use of Bone Marrow (BM) cells. In fact, BM cells infused in the blood stream can be recovered or detected in pulmonary tissue.

MSCs are considered a potential therapy in COPD because of their immunomodulatory effects and the ability to regenerate type 1 and 2 cells in the airspace.

MSCs derive from mesoderm and show a multilineage potential, as they have the capacity to give rise to blood, skeletal muscle cells, vascular, fat, and urogenital systems, as well as to connective tissues throughout the body.

Because of their unlimited self-renewal capacity, MSCs show that an in vitro high expansion potential, a genetic and phenotypic stability, can be easily isolated from a small aspirate of BM expanded with high efficiency, shipped from the laboratory to the bedside.

MSCs show anti-inflammatory, immunomodulatory, and regenerative capacities. They secrete anti- inflammatory cytokines that modify the microenvironment within the damaged tissues. They also exert immunomodulatory effects by direct cell-to-cell contact. In fact, MSCs inhibit autoimmune T-cell responses and increase the number of regulatory T cells.

MSCs also inhibit the development and differentiation of dendritic cells and can selectively channel autoimmune T cells to apoptosis. Moreover, MSCs are able to migrate to sites of tissue injury and have strong immunosuppressive properties that can be exploited for successful autologous as well as heterologous transplantations. In 2009, an innovative Phase I clinical study on the use of autologous bone marrow mononuclear cells (BMMCs) in patients with pulmonary emphysema demonstrated that the administration of autologous cells with a pool of BMMCs in patients with advanced-stage COPD is a safe procedure without significant adverse effects. Furthermore, the reports from patients showed that in the period after the infusion of BMMCs until 20 months later, there was pulmonary function improvement and slowing down of the progressive degenerative condition in terms of maintenance or even increase in the forced expiratory volume in 1 second and forced vital capacity, and increase in forced expiratory volume in 1 second/forced vital capacity. BMMCs had an improvement in their clinical condition, a greater time tolerance without O2 intake, a greater capacity on exertion evaluated as walking distance, without significant fall in O2 saturation, and meaningful improvement in the quality of life, as well as a clinical stable condition.

A follow-up of up to 3 years showed an improvement in laboratory para meters (spirometry) and a slowing down in the process of pathological degeneration. In addition, patients reported improvements in the clinical condition and quality of life. These results suggest a change in the natural process of the disease.

A new and interesting field of investigation is “regenerative photobiostimulation,” or having the ability to enhance lung regenerative properties by means of low-level laser irradiation. Low-level laser therapy contemplates the application of electromagnetic radiations, and its beneficial properties include anti-inflammatory activity, growth factor production, stimulation of angiogenesis, and direct stem cell effects. These effects are mediated through a process that is still not clearly defined and does not involve thermal energy. In most cases, irrespective of the treated condition or the modality of administration, therapy with stem cells appears relatively safe.


At this time, COPD treatment is based on the administration of drugs that are able to reduce symptoms and prevent exacerbations. However, these therapies do not allow for changing the natural history of the disease. Animal and human studies have demonstrated that tissue-specific stem cells and BM-derived cells contribute to lung tissue regeneration and protection, and thus administration of exogenous stem/progenitor cells or the humoral factors responsible for the activation of endogenous stem/progenitor cells may be a potent next-generation therapy for COPD.  The use of BM-derived stem cells could allow us to repair and regenerate the damaged tissue present in COPD by means of their engraftment into the lung.

The International Advanced Medical Therapies Institute has 4 years offering this therapy. If you need more information, please contact your medical facilitator or write us to

Tomotherapy: A “Revolution” In Cancer Radiation Therapy

Jake Van Dyk, et al., London Regional Cancer Centre and University of Western Ontario (resume)



Cancer and Radiation Therapy

Cancer is the most significant health care problem in the western world surpassing heart disease as the leading cause of potential years of life lost. In Canada, about 134,000 people are diagnosed annually with cancer. This represents more than one in three people who will develop cancer during their lifetimes. Radiation will be used to treat approximately 66,000 new cancer patients per year of whom 33,000 will be treated with an attempt to cure the disease.

The radiation therapy process is complex and involves multiple steps.

The process begins with patient diagnosis and three-dimensional (3-D) imaging, through various steps that prepare the patient for treatment and, finally, to treatment verification and actual radiation dose delivery. Patients who are treated for cure receive high radiation doses of 60 to 70 Gy, given in 30 to 40 daily fractions at the rate of 5 fractions per week.

There are several critical steps in this process. One of these is the use of sophisticated 3-D imaging using computerized tomography (CT), magnetic resonance imaging (MRI), single photon emission tomography (SPECT), or positron emission tomography (PET). These imaging modalities have evolved dramatically over the last decade and provide information about tumour location and tumour extent, with each modality providing unique information that is especially relevant for specific tumour types.

With such image data, sophisticated dose calculations can be performed using shaped radiation beams from various directions to yield optimized treatment plans.

In addition to imaging for therapy planning, there are a number of requirements in order to deliver a prescribed radiation dose to the patient with a sufficient control and accuracy. These relate to the technologies used to deliver the dose to the patient and the computerized calculational procedures that are required to optimize the treatment technique and to predict precisely the dose that will be given to the patient using complex radiation delivery technologies.

Modern Dose Delivery

One of the unique features of radiation therapy, compared to other forms of cancer treatment, is that the radiation can be delivered in an anatomically and geometrically specific fashion by using radiation field collimation and beam shaping.

Today, linear accelerators (linacs), generating electron energies between 4 and 25 MeV, are generally used for producing x-ray beams for the treatment of tumours. Conventionally, these machines have collimators that produce rectangular fields between 4 x 4 cm2 to 40 x 40 cm2.

A collimator is a device that narrows a beam of particles or waves. To “narrow” can mean either to cause the directions of motion to become more aligned in a specific direction or to cause the spatial cross section of the beam to become smaller.

The newer machines have collimators which are divided into multiple segments from two opposite sides. The “leaves” in these “multileaf collimators” are motor-driven and computer-controlled and can project shadows at the level of the patient that are 0.5 or 1 cm in width.

In addition to simple field shaping, computer-controlled multileaf collimators provide the capability of defining multiple field shapes either for individual directions or for multiple fields aimed at the tumour from different directions. This, combined with “automated” optimization programs using “inverse” dose calculations, allows control of the beam intensity pattern at the patient such that a well-defined and uniform dose can be delivered to the target and normal tissue doses can be minimized. This process has become known as segmented field, intensity modulated radiation therapy (IMRT) or when using moving leaves and a moving machine gantry, it is known as dynamic IMRT.

Tomotherapy, literally translated, means “slice therapy”. The first implementation of this concept was performed by NOMOS Corporation and was provided as an add-on accessory to existing linear accelerators. The add-on feature consists of a set of multileaf collimators that provide a narrow “fan” beam shape (Figure 1) projecting a maximum width at the patient of about 20 cm. The fan beam thickness can be either 0.8 or 1.6 cm and each leaf projects a shadow of about 1 cm width at the patient. When the leaves are in the beam, that portion of the beam is fully shielded except for a minor (~0.5%) transmission component.














Figure 1. (a) Schematic of a binary multileaf collimator with a fan beam geometry. This schematic example shows leaves that move from one side. (b) Picture of TomoTherapy single slice multileaf collimator the interdigitated leaves and how they move from both sides.

Either the leaf is open or closed for that slice providing “binary” dose delivery, i.e., for that portion of the beam, the beam is either on or off. The open beam components are generally referred to as “beamlets” or “pencil beams”. Radiation delivery consists of a machine that rotates around the patient while the beam is on and the leaves rapidly move in and out depending on whether that beamlet is aimed at the target or at normal tissues.

After two simultaneous slices have been delivered, the patient is translated by two slice thicknesses and the next two slices are delivered until the total treatment volume is covered, hence the nomenclature, “serial tomotherapy”.


General Design Considerations

Traditional linear accelerators are currently limited to serial tomotherapy due to the limited rotation possible (~370°) and the inability to move the couch smoothly and automatically during radiation delivery. Furthermore, serial tomotherapy is unable to image the patient in treatment position and, therefore, unable to assure the accurate placement of the high dose volume with respect to the malignant region. The new tomotherapy units are capable to remove these limitations.

As can be seen in Figure 2, the helical tomotherapy machine is a combination of a helical CT scanner and a linear accelerator. It uses the slip ring technology of diagnostic CT scanners and, therefore, the unit is capable of continuous rotation around the patient while the couch is moving into the gantry, thus providing smooth helical delivery.


Mounted on the rotating gantry and attached to the slip ring is a compact linear accelerator generating a 6 MV photon beam. The beam from the accelerator is collimated by a multileaf collimator consisting of 64 leaves each of which project a shadow of 6.25 mm at the patient generating a total fan beam width of 40 cm. By using a separate collimation (“jaws”) system above the multileaf collimators, the “slice thickness” can range between 0.5 to 5 cm. Since it is a specially designed machine for helical, fan beam delivery, the multileaf collimation system is specifically designed to minimize leaf transmission and interleaf leakage – important considerations for narrow beam, multislice delivery procedures.

The Process of Helical Tomotherapy

Due to the integration of several technologies into a single piece of equipment, helical tomotherapy allows the development of a number of processes that are either very difficult or simply not possible with other radiation therapy devices.

Dose Delivery Capabilities

The next examples will be used to illustrate the kinds of dose distributions that can be delivered using the tomotherapy technology. Figure 3 is a schematic example of a “U”- shaped target that encompasses a critical normal tissue. This represent a nasopharyngeal tumour around the spinal cord and a schematic example of a “U”-shaped high dose region (red for tumour) surrounding a critical structure (spinal cord) that receives a low dose (blue).


The principal advantage of this type of treatment is the reduction of the damage to other organs and reduces the radiation collateral effects.

Helical tomotherapy mounted on a ring gantry provides significant advantages over today’s state-of-the-art radiation treatment. First, it provides on-line imaging which allows for treatment adaptation on a daily basis accounting for the tissue locations on each set-up. The dose reconstruction capabilities provide an ability to determine the dose actually delivered to the patient, also on a daily basis. The tomotherapy unit fits into a significantly smaller room compared to modern linear accelerators since it does not involve a couch rotation.

The technology of radiation oncology is evolving at a rapid rate, primarily as a result of the evolution of computer applications and their integration into diagnostic imaging and radiation therapy dose delivery equipment. The ring-mounted helical tomotherapy concept combines state-of-the art imaging and treatment capabilities. Perhaps the tomotherapy development represents the greatest advance in radiation therapy since the first use of cobalt-60 in the 1950s.

These advances will provide a radiation treatment technology that allows daily adaptation of the treatment technique to match the location of the tumour and the normal tissues. With the better ability to focus the radiation beams, higher doses can be delivered to the tumour resulting in higher cure rates. In addition, lower doses will be delivered to normal tissues resulting in lower complication rates. The net result should be an overall improvement in the quality of life of the cancer patient.


In Central America, Caribean and South America our Institute is the only facility that offers this kind of treatment, if you want to contact us please send a message to

Stem cells in management of Chronic Obstructive Pulmonary Disease (COPD)

Article Summary, from International Journal of COPD 2010:5 81-88. Tillie L Hackett, Darryl A Knight, Don D Sin, Heart and Lung Institute, St Paul’s Hospital, Vancouver, BC, Canada


Chronic obstructive pulmonary disease (COPD) is a worldwide epidemic affecting an estimated 210 million people and accounting for more than three million deaths annually. (1). Over the next 20 years, the World Health Organization expects total COPD mortality to more than double.

In China alone, three million men and women are expected to die from COPD by the year 2030 if current cigarette and biomass exposure trends continue. (2)

Unfortunately, aside from supplemental domiciliary oxygen for the small number of patients who demonstrate resting arterial hypoxemia and smoking cessation for continued smokers, there are no interventions that have been unequivocally shown to prolong survival in patients with COPD (3) and no therapies that can fully restore the lost lung function associated with COPD.

As COPD is characterized by loss of lung tissue and remodeling of the airways, there is growing enthusiasm for using stem and progenitor cells to regenerate healthy parenchymal and airway cells and restore lung function in patients with COPD.

Morphologically, COPD is characterized by two distinct but related pathologic features, ie, bronchiolitis involving predominantly the small airways (airways less than 2 mm in diameter) and emphysema. (4). Emphysema is characterized by dilatation and destruction of lung tissue beyond the terminal bronchioles. The centriacinar form of emphysema is characterized by tissue destruction of the respiratory bronchioles and occurs most frequently in cigarette smokers. Panacinar emphysema, on the other hand, is characterized by destruction of the entire acinar unit and occurs largely in the setting of alpha-1 antitrypsin deficiency. (4)

The key pathophysiologic changes underlying airflow limitation in COPD include the loss of elastic lung recoil pressure due to the destruction of alveolar septa and terminal bronchioles (emphysema), increased airflow resistance due to airway wall remodeling (ie, thickening of small airway wall) and mucoid impaction of the airway lumen. (4) In addition, there is growing evidence that endothelial dysfunction and vascular remodeling initiated by vascular endothelial growth factor-mediated apoptosis of endothelial cells may also contribute to disease progression in COPD. (5)

Although there have been tremendous advances in our understanding of COPD pathobiology over the past two decades, the exact pathologic mechanisms by which emphysema and airway remodeling occur in COPD remain largely a mystery. One of the leading theories is the “inflammatory hypothesis”. Proponents argue that in certain (genetically) susceptible individuals, lung inflammation, which occurs in response to environmental triggers such as air pollution and cigarette smoke, changes from a “normal” response to an abnormal one, characterized by excess innate and adaptive immunity, at some point during the exposure.

Interestingly, once the inflammatory changes are firmly established in the lungs, the removal of the environmental trigger such as cigarette smoke does not fully abrogate the abnormal inflammatory response observed in the airways. Indeed, smokers who discontinue smoking continue to demonstrate airway inflammation. (10)

Another emerging hypothesis relates to accelerated cellular aging, or senescence that results in a series of perturbations in cell morphology and function, ultimately culminating in cell cycle arrest. (11,12)  Collectively, there appears to be sufficient evidence to suggest that resident structural cells within the lungs and lymphocytes within the systemic circulation of COPD patients exhibit markers of cellular senescence and accelerated aging, which is potentially detrimental to normal lung repair.

Mechanisms of lung repair

Theoretically, if the reparative and regenerative processes in the lungs can keep up with the destructive, inflammatory, or apoptotic processes, then lung homeostasis can be maintained, leading to the preservation of normal tissue and function. Following epithelial injury, the airway epithelium begins to repair almost immediately. At the wound edge, the (undamaged) epithelial cells de-differentiate and migrate to “cover up” the wounded area and release a variety of proinflammatory cytokines and growth factors to attract proteins and cells needed for restoration of the extracellular matrix, which is crucial for normal wound repair. Once this occurs, re-epithelialization can proceed.

The adult human lung comprises various trophic units which are each lined by specialized types of airway epithelia. (26) The ability of the lung to repair itself in the setting of injury is determined by the molecular events that mobilize the resident stem and progenitor cells within each of the trophic units. Stem cells and progenitors are similar in that they both proliferate and give rise to differentiated cells but only stem cells are capable of self-renewal. (27) The reader is referred to Figure 1 for the putative stem and progenitor cell niches within the human lung.

Resident stem cells within the lung

In contrast to dermal and intestinal epithelia, which are highly proliferative and rapidly renewing, the turnover of the airway epithelium is extremely slow unless injured. (28)  Each of the tracheal, bronchial, and alveolar regions within the lung has a distinct resident stem or progenitor cell population which possesses unique cellular physiologic properties. To date, several cells within the trachea and bronchial tissue have been reported to be enriched for stem/progenitor cell activity including cytokeratin 5/14-expressing basal cells, secretory (Clara) cells, cells residing in submucosal glands, and neuroepithelial bodies (NEB). (29–33).

A more recent study indicates that cytokeratin 5/14 expressing basal cells can self-renew and also give rise to new ciliated Clara and secretory cells following epithelial injury. (34)

We have also demonstrated that within human airways the basal cell population contains a side population (SP) of cells, which are characterized by the ability to efflux actively the DNA binding dye, Hoescht 33342. (35)

As with other epithelial tissues such as in mammary glands, (36,37) the eye, (38) and the skin, (39) SP cells within the airways are rare, making up less than 0.1%of the total epithelial cell population.

Both embryonic and adult stem cells in vitro can be induced to differentiate into airway and alveolar epithelial cells.

2 2333

MSCs isolated from amniotic fluid, umbilical cord blood, adipose tissue, or bone marrow have been used to generate tracheal cartilage using biosynthetic scaffolds in order to repair congenital tracheal defects in rodent models and more recently in human clinical trials. (56–58)

Macchiarini et al were able to use a patient’s epithelial cells and MSC-derived chondrocytes to generate a bioengineered trachea, which after engraftment provided a functional airway without the requirement for immunosuppressive drugs. (59)

Mesenchymal stem cells (MSCs) are nonhematopoietic stem cells of mesodermal origin, with the capacity to differentiate into both mesenchymal and nonmesenchymal lineages.

MSCs are found primarily in the bone marrow of adults and give rise to blood, skeletal muscle, vascular, and connective tissues throughout the body. Postnatally, bone marrow MSC can be isolated from adipose tissue, liver, synovial membrane, teeth, and tendons. In particular, MSCs are easily isolated from a small aspirate of bone marrow and can be expanded with high efficiency. MSCs have great potential in clinical therapy because they express intermediate to low levels of HLA Class I, low levels of HLA Class II, and low levels of costimulatory molecules to avoid self-recognition by the immune system. (69)

In immunocompetent patients, MSCs have also been demonstrated to suppress allogeneic T-cell proliferation and evade alloreactive recognition. (70)

The immunomodulatory properties of MSCs are thought to involve the secretion of soluble mediators and cell-cell contact inhibition; however, the exact mechanisms of action are unclear. (71).

Autologous and allogeneic MSCs are currently being tested in clinical trials for a variety of  diseases including Crohn’s disease, multiple sclerosis, diabetes mellitus and end-stage liver disease, and to prevent transplant rejection and restore left ventricular function in patients with congestive heart failure. An open-label Phase II trial utilizing Prochymal ®, an allogenic MSC infusion in patients with severe Crohn’s disease, who were unresponsive to corticosteroids, infliximab (anti-TNF antibody), and other immunosuppressive therapies, has recently been completed. The study reported significant mprovements in symptoms as assessed by the Crohn’s disease activity index (CDAI). This has led to the approval by the Food and Drug Administration for a Phase III doubleblind, placebo-controlled trial of this therapy for the treatment of Crohn’s disease. (77)


Despite significant progress in our understanding of lung stem cells and their functional capacities over the past decade, much remains unknown about the processes involved in lung repair. Accumulating data from both animal models and clinical trials suggest that adult-derived stem cells may provide potential therapeutic strategies for lung repair in COPD.

Bone Marrow-Derived Progenitor Cells Promote Lung Tissue Repair In COPD And Lung Fibrosis.

The following article is a resume of the paper published by CHEST magazine (Bone Marrow-Derived Stem Cells and Respiratory Disease CHEST 2011; 140(1): 205 – 211) and written by Carla P. Jones, PhD; and Sara M. Rankin, PhD; from the Leukocyte Biology Section, National Heart and Lung Institute, Imperial College London, London, England.

Abbreviations: EOG-EPC= early outgrowth endothelial progenitor cell; EPC = endothelial progenitor cell; LOG-EPC = late outgrowth endothelial progenitor cell; MSC = mesenchymal stem cell; PDGFR = platelet-derived growth factor receptor; PH =pulmonary hypertension; VEGF = vascular endothelial growth factor


In recent years it has been discovered that in addition to the well-characterized hematopoietic stem cells, adult bone marrow contains nonhematopoietic stem cells, such as endothelial progenitor cells (EPCs), fibrocytes, and mesenchymal stem cells (MSCs). It is believed that under homeostatic conditions these cells are released from the bone marrow, circulate in the blood, and contribute to the repair of tissues in response to general wear and tear.

Endothelial Progenitor Cells

EPCs were first described in 1997 when Asahara et al. identified a population of mononuclear cells in the blood capable of differentiating into endothelial cells in vitro. It was proposed that these circulating progenitor cells may contribute to angiogenesis and vasculogenesis (formation of new blood vessels). Currently there are no specific markers to identify EPCs in mice or humans, but as EPCs proliferate clonally and produce colonies in vitro, specific colony assays can be generally performed to quantify numbers of EPCs in blood and tissues.

In these assays, mononuclear cells are plated onto fibronectin or gelatin and grown in the presence of endothelial growth factors (including vascular endothelial growth factor [VEGF]). It is now clear that there are two distinct subsets of EPCs: the first derived from hematopoietic lineage (also known as early outgrowth EPCs [EOG-EPCs]) and the second from endothelial lineage (late outgrowth EPCs [LOG-EPCs]).

EOG-EPCs are not believed to directly form new vessels, but they have been shown to secrete key proangiogenic factors, and they promote angiogenesis/vasculogenesis through a paracrine mechanism.

The other subset of EPCs is the LOG-EPCs that are observed in colony assays after 21 days in culture and exhibit cobblestone morphology that is a characteristic of mature endothelial cells. In contrast to the EOG-EPCs, LOG-EPCs possess the ability to form vessels in vitro and in vivo in lung and heart models.

It is well documented that the ELR 1 CXC chemokines can stimulate angiogenesis in vivo, and it is, therefore, of interest that EPCs have been reported to express the chemokine receptor CXCR2.

 CD34 is a cell surface marker expressed by hematopoietic progenitor cells and EPCs. In patients with COPD, levels of circulating CD34 cells are reduced compared with normal control subjects, and it has been suggested, that this reflect the increased trafficking of progenitor cells into the lungs. Levels of circulating CD34 cells appear to increase during exacerbations of COPD, which has been correlated with an elevation in the plasma levels of VEGF-A from these patients.

Finally, two small clinical trials carried out by a group in China have reported positive results examining the efficacy of EPC transplantation in patients with idiopathic pulmonary arterial hypertension, when given in addition to conventional therapy.

There is considerable evidence that bone marrow derived fibroblast progenitor cells, called fibrocytes, may also contribute to this process. It is believed that fibrocytes are recruited to sites of inflammation to stimulate repair by producing extracellular matrix molecules such as collagen I and III, vimentin, and fibronectin. These data suggest that blocking fibrocyte recruitment to the lungs may represent a potential therapeutic target to reduce lung fibrosis.

Mesenchymal Stem Cells (MCSs)

MSCs are multipotent stromal cells that can be isolated from numerous tissues, including the bone marrow, skeletal muscle, amniotic fluid, and adipose tissue. They are plastic adherent cells that exhibit trilineage differentiation into adipocytes, chondrocytes, and osteoblasts. Some studies have shown that these stem cells also have the ability to differentiate into neurons, myocytes, and skeletal muscle.

A unique feature of MSCs is their ability to produce a potent immunosuppressive effect both in vitro and in vivo.  Mechanistically it has been suggested that this may be due to their ability to secrete a range of immunomodulators,

MSCs can be readily harvested from bone marrow or adipose tissue and expanded ex vivo for use as a cell therapy. Impressive immunosuppressive effects of these cells have been reported in a wide range of models of disease, including acute graft-vs-host disease and multiple sclerosis.  With respect to respiratory disease, there are now a number of publications that report a reduction in disease pathology.

MSCs are currently being evaluated in several clinical trials for a variety of diseases, including Crohn’s disease, multiple sclerosis, diabetes mellitus, and acute graft-vs-host disease, with promising results reported from some of these trials.

Epithelial Progenitor Cells

Although there are endogenous epithelial progenitor cells in the adult lung. These studies suggest that bone marrow-derived progenitor cells may incorporate and differentiate into lung epithelium and thereby promote tissue repair.

Pharmacologic activation of endogenous stem cells represents an alternative approach to stem cell therapies. One strategy is to stimulate the mobilization of stem cells from the bone marrow in order to induce regeneration or immune modulation during disease development. We have recently shown that at a molecular level the mobilization of progenitor cell subsets (hematopoietic progenitor cells, vs MSCs and EPCs) is differentially regulated, suggesting that pharmacologic therapies could be developed to selectively mobilize a specific subset of stem cells from the bone marrow.

In our Hospital we harvest and concentrated the stem cells from bone marrow and peripheral blood and after these procedures they are injected into the lung in order to regenerate the lung tissue.

Naples University asseverates that adult stem cells could be utilized in repair and regeneration of injured lung.


“Recent studies have revealed that adult stem cells such as bone marrow derived cells contribute to lung tissue regeneration and protection, and thus administration of exogenous stem/progenitor cells may be a potent next generation therapy for COPD”.

This is the statements that Dr Bruno D’Agostino and other scientist of the Naples University (Italy), published on October 2010 in Expert Opinion on Biological Therapy Magazine, an international journal publishing that review articles and original papers on all aspects of biological therapy, providing expert opinion around those fields.

At this review you can find a summary of this interesting paper. (Expert Opin. Biol. Ther. (2010) 10(5).

Bone marrow contains hematopoietic stem cells (HSCs), which characteristically differentiate into every type of mature blood cell, and mesenchymal stem cells (MSCs), which differentiate into fat, bone, cartilage and other mesenchymal tissues. Many studies have shown that cells derived from adult bone marrow are able to produce a variety of non-hematopoietic cells both in vitro and in vivo making them one of the best candidate for lung repair. Of the tissues with reported stem or progenitor activity, the one used extensively in cell-based therapies is bone marrow.

In humans, lung specimens from some clinical bone marrow transplant recipients demonstrate pulmonary chimerism (more than one set of DNA or two different cells) for both epithelial and endothelial cells. These findings were also repeated in male recipients of a female lung allograft, where it was also shown that cell engraftment occurred in the severely injured area.

This latter observation is consistent with another report in which the engraftment of the stem cells was greater when the parenchyma was injured before transplantation (e.g., by radiation injury). These studies support the notion that preexisting injury increases mobilization and recruitment of bone-marrow-derived cells within the inflammatory area. Therefore, the hypothesis that inflammatory stimuli can increase release of soluble factors by airway epithelium capable of playing an important role in cells recruitment from bone marrow to the lung was supported.

Recently, among bone-marrow-derived cells, MSCs are emerging as a therapeutic modality in various inflammatory diseases for their anti-inflammatory and immunomodulatory properties. The first evidences of the potential anti-inflammatory role of MSCs in lung diseases have been published at the beginning of the last decade.

The Global Strategy for the Diagnosis, Management, and Prevention of Chronic Obstructive Pulmonary Disease (GOLD) defines COPD as a preventable and treatable disease with some significant extrapulmonary effects that may contribute to the severity in individual patients.

This disease is a common cause of morbidity and mortality worldwide representing the fifth leading cause of death in the developed countries. Further increases in its prevalence and mortality are expected in the coming decades.

Cigarette smoking has been shown to be the most important risk factor and accounts for 80 ± 90% of the risk of developing COPD. In fact, the inhalation of noxious particles, such as cigarette smoke, causes the influx of inflammatory cells, in particular neutrophils, macrophages and CD8+ T lymphocytes, into the airways and lungs, leading to chronic inflammation.

According to the most recent clinical guidelines for COPD, the available treatments, both pharmacological and nonpharmacological, are essentially symptomatic, with the exception of two interventions that may also increase life expectancy: smoking cessation in patients with COPD, and long-term oxygen treatment in patients with COPD and respiratory failure. Bronchodilator therapy is a key component of treatment for patients with COPD at different stages of severity.

MSCs are considered as a therapy in COPD more for their immunomodulatory effects than for the ability to regenerate type I and II cells in the airspace.

MSCs are non-hematopoietic stem cells of mesodermal origin showing a multi-lineage potential, as they have the capacity to give rise to skeletal muscle cells, blood, fat, vascular and urogenital systems, and to connective tissues throughout the body. Due to their unlimited self-renewal capacity, MSCs show a high expansion potential. In addition, these cells show genetic and phenotypic stability, can be easily isolated from a small aspirate of bone marrow, expanded with high efficiency, shipped from the laboratory to the bedside and are compatible with different delivery methods and formulations.

MSCs are able to migrate to sites of tissue injury and have strong immunosuppressive properties that can be exploited for successful autologous as well as heterologous transplantations. Moreover, they are able to protect lung tissue by suppression of pro-inflammatory cytokines.

Stem-cell-based therapies may represent new therapeutic approaches for COPD that currently lacks efficient treatment. Because the rate of engraftment and differentiation is generally low following MSC therapy for lung injury, the positive therapeutic effects mediated by MSCs are probably mainly due to their ability to produce paracrine factors and to modulate the inflammatory response. In this way, MSCs could serve as cellular factories that secrete mediators to stimulate the repair of tissues, by acting on endogenous lung stem cells, or elicit other beneficial effects on the surrounding host tissue. In such cases, the overall effect may be the combined enhancement of stem cell survival as well as an enhancement of the local tissue environment.

Expert opinion

The above mentioned studies provide direct evidence that MSCs can potentially be used for COPD, or other lung disease, but the precise mechanism underlying this process needs to be understood to best achieve this goal. Human MSCs are obtained directly from patient, thus the subsequent use of these cells in the clinical setting would have the advantage that since MSCs are autologous, they would not be rejected after cell transplantation. Despite their low capability to home into the lung and differentiate into lung cells, they can have beneficial effects.

Importantly, several observations provide evidence that MSCs can act through a combination of paracrine effects that could stimulate the expansion, homing and differentiation of endogenous stem cells on one hand and the differentiation of MSCs toward alveolar epithelial cells, endothelial cells, fibroblasts and bronchial epithelial cells on the other.



Mechanisms of cellular therapy in Respiratory Diseases

The present publication is a resume of the review made by Soraia C. Abreu et al. on October 2011 and published at Intensive Care Med (2011) 37:1421–1431.




Stem cells are undifferentiated cell groups that have varying degrees of self-renewal and differentiation capacity.

According to their origin, they can be divided into embryonic stem cells and adult stem cells. Despite having the ability to generate any terminally differentiated cell in the body, embryonic stem cells present important issues that limit their use; thus, most studies have focused on therapy with adult stem cells.

Several experimental studies have demonstrated that both recruited endogenous and delivered exogenous stem cells can home to and/or participate in rebuilding of missing or damaged lung tissue. Thus, there is a great deal of interest and research into stem cell therapies for lung diseases with no current effective treatment.

This article presents a critical review of advances in the field of stem cell biology, as well as highlighting the effects of mesenchymal stem cell (MSC) therapy in acute lung injury (ALI) /acute respiratory distress syndrome (ARDS), pulmonary fibrosis, and chronic obstructive pulmonary disease (COPD).

Adult stem cells

Adult stem cells (ASC) are the term used to describe postnatal stem cells that remain in body tissues throughout life. These cells can be found in well-protected, innervated, and vascularized niches, from which they are recruited to maintain tissue homeostasis.

If required, stem cells may undergo asymmetric cell division, generating one stem cell and a committed progenitor.

A number of specialized ASC niches have recently been identified in lung tissue in addition to Clara cells and type II pneumocytes (precursors of airway and alveolar epithelial cells, respectively): intercartilaginous regions of the tracheobronchial tree and neuroepithelial bodies in the bronchioles and bronchoalveolar duct junctions, which may significantly contribute to natural turnover or rebuilding of injured lung tissue. The angiogenic factor and fibroblast growth factor-2 (FGF-2) seems to be essential for resident stem cell activation in the lung.

ASC from various organs may be recruited for lung repair. Bone marrow is the main source of adult hematopoietic stem cells and mesenchymal stem cells.

Bone marrow cells

The term bone marrow-derived mononuclear cells (BMDMC) includes both hematopoietic and mesenchymal (nonhematopoietic) stem cell types. Hematopoietic stem cells (HSC) are nonadherent cells that have the ability to proliferate and differentiate into blood cells.

These are rare cells that represent only 1 in 104 to 1 in 105 of total blood cells in bone marrow, identified by CD34 and CD45 surface markers. During postnatal life, a steady state is established, in which the HSC pool size is maintained by regulation of self-renewal and differentiation.

This is possible because the bone marrow contains specialized niches in which the multipotency of HSC is preserved through cell division, while their progeny are directed towards lineage differentiation.

To define MSC (mesenchymal stem cells), minimum consensus criteria should be adopted:

(1)   Selection for a plastic-adherent cell population in standard culture conditions;

(2)   Expression of CD105, CD73, and CD90 and no expression of CD45, CD34, CD14, CD11b, CD79-, CD19, or HLA-DR surface molecules; and

(3)   Ability to differentiate into adipocytes, osteocytes, and chondrocytes in vitro

MSC are found in the stromal fraction of bone marrow, and provide support to hematopoiesis. Mesenchymal stemlike cells have also been recently identified in different tissues: adult peripheral blood, adipose tissue, skin, and lung.

MSC are capable of adopting the morphology and phenotype of parenchymal cells of many nonhematopoietic tissues, including the lung, where they can increase the number of fibroblast-like cells  and differentiate into bronchial epithelial cells and alveolar type I and II pneumocytes.

Mechanism of action

MSC may promote lung tissue repair through plasticity (the ability of ASC to cross lineage barriers and to adopt the expression profiles and functional phenotypes of cells unique to other tissues). The acquisition of a new phenotype by MSC may occur in different ways:

  1.  Differentiation: process by which an undifferentiated cell becomes structurally and functionally more complex and specialized. In the lung, MSC differentiation into more specialized type II pneumocytes may contribute to repair of disrupted alveolar surfaces, characteristic of many respiratory diseases.
  2. Transdifferentiation: refers to the ability of a committed cell to change its gene expression pattern without cell fusion. So far, no data have been published to support this theory.
  3. Cell fusion: MSC fusion with other cell types to form a heterokaryon, converting its gene expression pattern to that of the fusion partner. A recent experimental study has demonstrated that 20–50% of lung epithelial cells derived from MSC result from cell fusion.
  4. Lateral transfer of RNA: uptake of messenger RNA (mRNA) microvesicles derived from other cell types, with expression of protein translated from the mRNA that was taken up.

Since several studies have demonstrated that the effects of these cells on organ systems are currently attributed to a paracrine effect—an ability to secrete soluble factors that modulate immune responses of different diseases. This mechanism was first identified by observing that systemic administration of MSC was able to inhibit expression of several proinflammatory and profibrogenic cytokines in models of ALI and pulmonary fibrosis. In short, MSC or BMDMC did not act only through plasticity, but also through paracrine effects, interfering significantly with the pathophysiological processes of lung diseases.

Stem cell therapy

Stem cell therapy appears to be a promising strategy for treatment of many respiratory diseases with no effective treatment, such as ALI and its severe form ARDS, pulmonary fibrosis, and COPD. These lung disorders differ substantially in their time course and pathophysiology, but have one feature in common, namely the ability of the alveolar epithelium to recover after injury.

Stem cells in pulmonary fibrosis

Pulmonary fibrosis is a devastating disease with high mortality rate and no effective therapy to reverse or delay the natural course of disease. After disappointment with the effects of anti-inflammatory treatment, evidence has shown a role of abnormal alveolar repair and remodeling in the pathophysiology of fibrosis. Therefore, since MSC can yield alveolar epithelial repair and inhibit fibrogenesis, MSC therapy is a possible therapeutic tool for pulmonary fibrosis.

Stem cells in chronic obstructive pulmonary disease

Chronic obstructive pulmonary disease is characterized by repeated repair and destruction processes, with subsequent tissue remodeling as well as sustained and irreversible airflow limitation. No effective therapy is available for COPD.

A reduced number of progenitor cells has been observed in end-stage COPD patients and in experimental emphysema induced by elastase . These progenitor cells differentiate into many types of lung cells, mainly mature endothelial cells. Other studies have demonstrated that nonsmoker COPD patients present an increase in the number of progenitor cells that is proportional to bronchial obstruction and arterial oxygen tension, suggesting an intriguing compensatory effect of hypoxia on progenitor cell mobilization.

Different routes of administration have been described: intravenous, intra-arterial, and intratracheal.

A recent study has demonstrated that intravenous administration of MSC results in higher pulmonary engraftment compared with BMDMC and multipotent adult progenitor cells (MAPC). This occurs because MSC are larger and express many adhesion molecules, such as VCAM-1 and P-selectin, which facilitates their retention in the lung.

Once delivered, MSC are recruited to the injured tissue, where they promote release of cytokines and growth factors, contributing to a positive therapeutic outcome. In this line, the future of MSC therapy may lie in stimulation of specific mediators, such as growth factors and anti-inflammatory cytokines that participate in cell recruitment as well as endothelium and epithelium repair.

Some ongoing clinical trials are testing the safety and feasibility of cell-based therapy in respiratory diseases.

Conclusion: There is evidence for beneficial effects of MSC on lung development, repair, and remodeling. The engraftment in the injured lung does not occur easily, but several studies report that paracrine factors can be effective in reducing inflammation and promoting tissue repair.

Neurostimulation a Successful Chronic Pain Treatment


Spinal cord stimulation can be an effective alternative or adjunct treatment to other therapies to manage chronic back and/or leg pain and our Institute use Medtronic devices because offers a portfolio of spinal cord neurostimulators that deliver targeted chronic pain management.

Medtronic has been innovating in neurostimulator technology for more than 30 years. In that time, over 250,000 patients have benefited from spinal cord stimulation and provide clinicians and patients with reliable, best-in-class pain management systems and service.

A typical spinal cord stimulation system implant is completed in 2 stages. The first stage is a 3- to 7-day screening test to evaluate whether or not the patient is a candidate for the second stage – the spinal cord stimulation system implant.

During a neurostimulation screening test, the patient receives a temporary, external neurostimulation system for 3 to 7 days and percutaneous leads are used for the screening test.

During the screening test, the patient uses the external neurostimulation trialing system while completing daily activities. In some cases, the patient can use a patient control device to change some stimulation settings within physician-programmed limits.

Throughout the screening test, the external neurostimulator collects patient-use data and the patient records activities, neurostimulation settings, and degree of pain relief in a diary.

After the screening test ends, percutaneous trial leads are removed. Results are evaluated to determine if the patient is a candidate for a spinal cord stimulation system implant.

After the screening test, clinicians review input from the pain management team, the patient, and the patient’s family or caregivers; evaluate if the goals of a neurostimulation trial have been met; and determine if a neurostimulation system will be implanted.

Goals of the screening test:

  • Stimulation covers the patient’s pain areas
  • Patient is comfortable with the sensation of stimulation
  • Patient experiences adequate pain relief (more than 50%)
  • Patient experiences improved function

Implanting the spinal cord neurostimulation system requires a short surgery, typically done on as an outpatient procedure. The neurostimulator is inserted under the skin through a small incision in the upper buttock. The long-term lead is implanted in the epidural space of the spinal cord.

Indications for Neurostimulation

An implantable neurostimulation system is indicated for spinal cord stimulation (SCS) systems as an aid in the management of chronic, intractable pain of the trunk and/or limbs-including unilateral or bilateral pain associated with the following conditions:

  • Failed Back Syndrome (FBS) or low back syndrome or failed back
  • Radicular pain syndrome or radiculopathies resulting in pain secondary to FBS or herniated disk
  • Postlaminectomy pain
  • Multiple back operations
  • Unsuccessful disk surgery
  • Degenerative Disk Disease (DDD)/herniated disk pain refractory to conservative and surgical interventions
  • Peripheral causalgia
  • Epidural fibrosis
  • Arachnoiditis or lumbar adhesive arachnoiditis
  • Complex Regional Pain Syndrome (CRPS), Reflex Sympathetic Dystrophy (RSD), or causalgia

The Failed Back Surgery Syndrome (FBSS), it was defined by North & Campbell in 1991 as persistent or recurring low back pain with or without sciatica, following one or more lumbar spine operations.

Chronic debilitating low back pain occuring in a patient after back surgery of a variety of types, such as discectomy, laminectomy, and lumbosacral fusion, that was unsuccessful in relieving the patient’s symptoms. Nearly 300,000 spinal surgeries are performed in the United States each year. Approximately 85% of these procedures involve laminectomy and discectomy and 15% are spinal fusions.

FBSS is considered to be a severe, long-lasting, disabling and relative frequent (5-10%) complication of lumbosacral surgery and this is the most common indication for neurostimulation.

Patients with FBSS have failed to obtain long-term pain relief, even after treatment with a variety of therapies, including oral medication, nerve blocks, corticosteroids injection, physical therapy, chiropractic care, fixation surgeries and repeated surgeries:

Neurostimulation has been used for FBS since 1967 and Long-term follow-up studies have shown a success rate up to 75% for FBS at 5 years.

Neurostimulation can lower the medical costs of FBS over time, by reducing office and emergency department visits. Other benefits are:

  1. SCS pays for itself within 2.1 years.
  2. Medications tend to stabilize or decrease
  3. Activities of daily living increase
  4. Some patients are able to return to meaningful employment.

Complex Regional Pain Syndrome (CRPS)

CRPS I and II are chronic pain syndromes characterized by severe pain accompanied by autonomic changes in the painful region, including edema, temperature abnormalities, sudomotor activity and skin color changes. At this time CRPS  affects up to 1.2 million US people.

CRPS develops in response to a traumatic physical event, such as an accident or medical procedure. Even “minor” accidents, such as a sprain, can be the cause of CRPS.

CRPS causes nerves to misfire, sending constant pain signals to the brain. Typically, patients with CRPS see an average of 5 doctors before being accurately diagnosed.

Retrospective reviews of a limited number of patients having Neurostimulation systems implanted for the management of CRPS have shown that patient satisfaction with this mode of therapy is quite high, with up to 90% finding the stimulator helpful for their pain.

If you need a medical opinion about this treatment, please send a short resume of your history disease to

Chronic Pain

PainWhat is Chronic Pain?

While acute pain is a normal sensation triggered in the nervous system to alert you to possible injury and the need to take care of yourself, chronic pain persists and the pain signals keep firing in the nervous system for weeks, months, even years.

There may have been an initial mishap — sprained back, serious infection, or there may be an ongoing cause of pain — arthritis, cancer, ear infection, but some people suffer chronic pain in the absence of any past injury or evidence of body damage and many chronic pain conditions affect older adults.

Common chronic pain complaints include headache, low back pain, cancer pain, arthritis pain, neurogenic pain (pain resulting from damage to the peripheral nerves or to the central nervous system itself), psychogenic pain (pain not due to past disease or injury or any visible sign of damage inside or outside the nervous system). A person may have two or more co-existing chronic pain conditions. Such conditions can include chronic fatigue syndrome, endometriosis, fibromyalgia, inflammatory bowel disease, interstitial cystitis, temporomandibular joint dysfunction, and vulvodynia. It is not known whether these disorders share a common cause.

The pain experience can be functionally divided into acute and chronic types. Acute and chronic pain are due to different physiological mechanisms and thus require different treatments. In this document, we review theories of pain and examine the physiology of pain, with emphasis on the types and their manifestations.

Pathways of Pain

Nociceptors, or pain receptors, are free nerve endings that respond to painful stimuli.  Nociceptors are found throughout all tissues except the brain, and they transmit information to the brain. They are stimulated by biological, electrical, thermal, mechanical, and chemical stimuli.

Pain perception occurs when these stimuli are transmitted to the spinal cord and then to the central areas of the brain. Pain impulses travel to the dorsal horn of the spine, where they synapse with dorsal horn neurons in the substantia gelatinosa and then ascend to the brain.

The basic sensation of pain occurs at the thalamus, it continues to the limbic system (emotional center) and the cerebral cortex, where pain is perceived and interpreted (Figure 1).

Two types of fibers are involved in pain transmission. The large A delta fibers produce sharp well-defined pain, called “fast pain” or “first pain,” typically stimulated by a cut, an electrical shock, or a physical blow. Transmission through the A fibers is so fast that the body’s reflexes can actually respond faster than the pain stimulus, resulting in retraction of the affected body part even before the person perceives the pain.

After this first pain, the smaller C fibers transmit dull burning or aching sensations, known as “second pain.” The C fibers transmit pain more slowly than the A fibers do because the C fibers are smaller and lack a myelin sheath. The C fibers are the ones that produce constant pain.


According to the gate control theory, stimulation of the fibers that transmit nonpainful stimuli can block pain impulses at the gate in the dorsal horn and this is the basis for neurostimualtion treatment.

For example, if touch receptors (A beta fibers) are stimulated, they dominate and close the gate. This ability to block pain impulses is the reason a person is prone to immediately grab and massage the foot when he or she stubs a toe.

The touch blocks the transmission and duration of pain impulses, and this capacity has implications for the use of touch and massage for some patients in pain.

Chronic Pain

Chronic pain is prolonged pain, persisting beyond the expected normal healing time.

This characterization was previously the official definition of chronic pain according to the International Association for the Study of Pain. The term chronic is still widely used, although many pain experts now think that all forms of chronic pain are variations of the same phenomenon and should be labeled specifically, such as neuropathic pain.

Chronic pain can be continuous (eg, arthritis) or intermittent (eg, migraines). Chronic pain is poorly understood and is more complex and difficult to manage than is acute pain. Understanding chronic pain requires recognizing that the nervous system is not hardwired. If it were hardwired, each noxious stimulus, such as a needle stick, would elicit exactly the same nervous system response at the same intensity every time, but pain is much more complex, involving affective and cognitive traits of the person who experiences it.

Melzack and Wall showed that repeated stimulation of C fibers results in progressive buildup of electrical response in the CNS, a phenomenon called windup, somewhat analogous to the effect of winding up a child’s windup toy. The more the toy is wound up, the faster and longer the toy will run.

This persistent stimulation of peripheral nerves winds up the CNS, leading to intensified stimulation of nerve fibers that is referred to as non nociceptive pain.

The concept of windup is crucial to understanding chronic pain. Windup is the reason pain can continue long after the expected recovery time for an injury or a pain-initiating event.

Patients with chronic pain may not have the behaviors associated with acute pain. Additionally, autonomic nervous system responses (eg, nausea, vomiting, pallor, sweating) decrease with prolonged pain.

The body’s fight-or-flight reaction, which normally occurs with acute pain, does not occur because the sympathetic nervous system has adapted to persistent pain impulses.

Understanding chronic pain, therefore, requires listening to the person’s description of it, because expected physical symptoms may not be present. Unfortunately, because of the lack of objective evidence of pain, many patients who report chronic pain are viewed as hypochondriacs and malingerers by health care professionals.

Some evidence indicates that chronic pain and depression share the same physiological pathway.

Neuropathic Pain


Chronic, often intractable pain due to injury to the peripheral nerves is known as neuropathic pain. According to Devor and Seltzer, this pain is a paradox.

Injury to peripheral nerves should deaden sensation, much as cutting a telephone wire leaves the phone line dead, but the opposite occurs in neuropathic pain.

Injury to the peripheral nerves can cause spontaneous paresthesias, numbness, pain with movement, tenderness of a partly denervated body part, and pain that is electric shock–like, burning, shooting, or tingling.

Abnormally amplified signals in the CNS due to windup result in central sensitization, which is an increased sensitivity of spinal neurons. Central sensitization causes allodynia (pain from a stimulus that does not normally produce pain, such as touch) and hyperalgesia (a heightened pain response to a stimulus that is painful).

Is there any treatment?

Medications, acupuncture, local electrical stimulation, and brain stimulation, as well as surgery, are some treatments for chronic pain. Psychotherapy, relaxation and medication therapies, biofeedback, and behavior modification may also be employed to treat chronic pain.

Spinal cord stimulation (neurostimulation) can be an effective alternative or adjunct treatment to other therapies to manage chronic back and/or leg pain and in our hospital we use Medtronic devices because offers a portfolio of spinal cord neurostimulators that deliver targeted chronic pain management.

Medtronic has been innovating in neurostimulator technology for more than 30 years. In that time, over 250,000 patients have benefited from spinal cord stimulation and provide clinicians and patients with reliable, best-in-class pain management systems and service.

If you need a medical opinion about this treatment, please send a short resume of your history disease to

Harvard Confirms the Stem Cell Existence in the Human Lungs


On May 12, 2011 the New England Journal of Medicine published a very exciting and interesting study of the Brigham and Women’s Hospital, Harvard Medical School, Boston; and the University of Parma, Italy; confirming strong and convincing evidence about the finding and isolation of Human Lung Stem Cells.

Researchers of those Universities found that human lungs contain undifferentiated human lung stem cells nested in niches in the distal airways.

This is a very important scientific finding because confirm the fact that stem cells exist in the human lung with the capacity to regenerate the pulmonary tissues and improve some diseases like chronic obstructive pulmonary disease (COPD), emphysema and fibrosis.

Many series of exciting reports over the last 5 to 10 years have demonstrated that adult bone marrow-derived stem cells may have more plasticity and are able to differentiate into bronchial and alveolar epithelium, vascular endothelium, and interstitial cell types, making them prime candidates for lung repair.

The above mentioned studies provide direct evidence that mesenquimal stem cells (MSCs) and other bone marrow-derived cells can be used for COPD, or other lung disease, but the precise mechanism underlying this process needs to be completely understood.

For example, Lobinger (London, UK) have shown that bone marrow-derived progenitors have the ability to differentiate and function as airway and parenchyma lung cells, but the medical community do not know what is the biology role between the resident lung stem cells and bone marrow-derived cells.

The hypothesis that bone marrow-derived cells may be used for regenerative purposes in lung diseases is confirmed by the fact that these cells engraft in the lung, acquire characteristics of certain respiratory cell populations and reduce the degree of respiratory fibrosis in the patient.

Due to the relevance of this fact, hereafter you will find a short overview of the main concepts of the Harvard and Parma Universities scientific paper related with the lung stem cells evidence. (Evidence for Human Lung Stem Cells, J. Kajstura, M. Rota, el al.; N Engl J Med 2011;364:1795-806.)

Various cell populations with some of the stem cells features have been described in distinct anatomical regions of the lung, but the demonstration of a noncommitted cell without specialized functions remains elusive.

In order to demonstrate the stem cell exist in the human lungs, researchers obtained samples of normal human lung tissue from unused donor organs, fetal lungs after cases of fetal death and samples of normal lung tissue from the Brigham and Women’s Hospital Thoracic Surgery Tissue Bank.

To establish whether the human lung possesses a stem-cell pool, they used the stem-cell antigen c-kit as a marker of identification and characterization. Their criteria for human lung stem cells were self-renewal, clonogenicity, and multipotentiality in vitro and in vivo. All samples were prepared for transplant.

After cells recovery, anesthetized female mice immunosuppressed with the use of cyclosporine underwent thoracotomy, and 2 to 3 mm2 of lung tissue was damaged with a steel probe that had been cooled in liquid nitrogen. The area adjacent to the damaged tissue then received six injections (with about 20,000 cells in each injection) of human lung stem cells mixed with labeled polystyrene microspheres. The mice chests were then closed and the animals were killed at 12 hours, 2 days, or 10 to 14 days after surgery. In some mice, lung tissue that had regenerated was excised, prepared and and injected into another mouse with the same cool damaged lung.

After 2 days, approximately 30% of the delivered cells were present within the damaged tissue and the bordering region, and after 10 to 14 days, clonal human lung stem cells had formed human bronchioles, alveoli, and pulmonary vessels, partly restoring the structural integrity of the mice lung tissue.  Thus, the clonal human lung stem cells showed self-renewal and multipotentiality in vivo.

Human lung stem cells generated bronchioles, approximately 30 to 250 μm in diameter, as well as small and intermediate-sized pulmonary arterioles approximately 20 to 70 μm in diameter and the newly formed human lung parenchyma replaced more than 30% of the original damaged tissue.

Ten to 14 days after cryoinjury and cell implantation, undifferentiated, human lung stem cells were identified within the regenerated human lung parenchyma and in the adjacent, intact recipient mouse lung. Approximately 20,000 human lung stem cells were present in each treated mouse.

After enzymatic digestion of the damaged lung, cells were recovered and delivered immediately to the cryoinjured portion of the lung of another new recipient mouse. Ten days after cell treatment, all treated mice were killed, and human bronchi, alveoli, and vessels were identified, documenting that the newly formed human lung structures derived from the serially transplanted human lung stem cells.

Those human lung stem cells that were detected in these mice, providing further evidence in support of the self-renewal and long-term proliferation of human lung stem cells in vivo. Furthermore, direct connections were found between preexisting pulmonary vessels and regenerated pulmonary vessels documenting the integration of temporally distinct preexisting (mouse) and new (human) segments of the pulmonary vasculature.

These results suggest that the human lung possesses a pool cells that have the fundamental properties of stem cells: they are selfrenewing, clonogenic, and multipotent in vitro and in vivo. The ability of human lung stem cells to create human bronchioles, alveoli, and pulmonary vessels in the mouse provides evidence in favor of the crucial role that human lung stem cells may have in lung homeostasis and tissue regeneration after injury. cells.

These findings do not rule out or challenge the notion that basal epithelial cells, bronchoalveolar stem cells, Clara cells, side population cells, and type II alveolar epithelial cells are involved in the epithelial-cell response to inflammation or injury.

Similarly, the presence of a human lung stem cell does not rule out the possibility that mature cells within the adult lung dedifferentiate or reprogram themselves to form a committed progeny, a phenomenon shown to be operative in other organ.

These findings, together with the results of our in vitro studies, provide evidence of a resident multipotent stem cell in the human lung.

In conclusion, this study provide several lines of evidence of the existence of human lung stem cells. Clonal human lung stem cells divided asymmetrically and generated bronchioles, alveoli, and pulmonary vessels of various dimensions, including capillaries, in vivo in a mouse model.

Furthermore, human lung stem cells obtained from regenerated lung tissue were able to selfrenew and create lung parenchyma in vivo in another mouse with lung damage. The immunohistochemical identification of newly regenerated pulmonary structures is strengthened by the recognition of human sex chromosomes and human transcripts of epithelial and vascular genes within the regenerated mouse lung.

Thus, human lung stem cells show self-renewal, clonogenicity, and multipotentiality and could be used in lung regeneration.