Clinical Study
The Role of Autologous Dermal Micrografts in Regenerative
Surgery: A Clinical Experimental Study

Marco Mario Tresoldi ,1,2 Antonio Graziano,3,4 Alberto Malovini,5 Angela Faga ,6

and Giovanni Nicoletti 1,2,6

1Plastic and Reconstructive Surgery, Department of Clinical Surgical, Diagnostic and Pediatric Sciences, University of Pavia,
Viale Brambilla, 74 Pavia, Italy
2Plastic and Reconstructive Surgery Unit, Department of Surgery, Istituti Clinici Scientifici Maugeri, Via Salvatore Maugeri,
10 Pavia, Italy
3Department of Public Health, Experimental and Forensic Medicine, University of Pavia, Via Forlanini 6, Pavia, Italy
4Sbarro Health Research Organization (SHRO), Temple University, 1900 N 12th St., Philadelphia, PA 19122, USA
5Laboratory of Informatics and Systems Engineering for Clinical Research, Istituti Clinici Scientifici Maugeri, Via Salvatore Maugeri,
10 Pavia, Italy
6Advanced Technologies for Regenerative Medicine and Inductive Surgery Research Center, University of Pavia, Viale Brambilla,
74 Pavia, Italy

Correspondence should be addressed to Marco Mario Tresoldi; marcomario.tresoldi@unipv.it

Received 26 March 2019; Revised 3 July 2019; Accepted 4 August 2019; Published 8 September 2019

Guest Editor: Fabio Naro

Copyright © 2019 Marco Mario Tresoldi et al. This is an open access article distributed under the Creative Commons Attribution
License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is
properly cited.

The aim of the study was the objective assessment of the effectiveness of a microfragmented dermal extract obtained with
Rigenera™ technology in promoting the wound healing process in an in vivo homogeneous experimental human acute surgical
wound model. The study included 20 patients with 24 acute postsurgical soft tissue loss and a planned sequential two-stage
repair with a dermal substitute and an autologous split-thickness skin graft. Each acute postsurgical soft tissue loss was
randomized to be treated either with an Integra® dermal substitute enriched with the autologous dermal micrografts obtained
with Rigenera™ technology (group A—Rigenera™ protocol) or with an Integra® dermal substitute only (group B—control). The
reepithelialization rate in the wounds was assessed in both groups at 4 weeks through digital photography with the software
“ImageJ.” The dermal cell suspension enrichment with the Rigenera™ technology was considered effective if the reepithelialized
area was higher than 25% of the total wound surface as this threshold was considered far beyond the expected spontaneous
reepithelialization rate. In the Rigenera™ protocol group, the statistical analysis failed to demonstrate any significant difference
vs. the controls. The old age of the patients likely influenced the outcome as the stem cell regenerative potential is reduced in the
elderly. A further explanation for the unsatisfying results of our trial might be the inadequate amount of dermal stem cells used
to enrich the dermal substitutes. In our study, we used a 1 : 200 donor/recipient site ratio to minimize donor site morbidity. The
gross dimensional disparity between the donor and recipient sites and the low concentration of dermal mesenchymal stromal
stem cells might explain the poor epithelial proliferative boost observed in our study. A potential option in the future might be
preconditioning of the dermal stem cell harvest with senolytic active principles that would fully enhance their regenerative
potential. This trial is registered with trial protocol number NCT03912675.

1. Introduction

The dermal extracellular matrix plays a relevant both
structural and functional role in signalling cell prolifera-

tion, development, shaping, function, and migration. The
dermis is provided with a relevant both mesenchymal
and adnexa-related stem cell pool. Such properties support
the use of dermis-derived extracts to stimulate tissue

Hindawi
Stem Cells International
Volume 2019, Article ID 9843407, 8 pages
https://doi.org/10.1155/2019/9843407

https://orcid.org/0000-0001-8582-0830
https://orcid.org/0000-0002-6467-5512
https://orcid.org/0000-0002-1507-4067
https://clinicaltrials.gov/ct2/show/NCT03912675?term=NCT03912675&rank=1
https://creativecommons.org/licenses/by/4.0/
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https://creativecommons.org/licenses/by/4.0/
https://creativecommons.org/licenses/by/4.0/
https://doi.org/10.1155/2019/9843407


regeneration [1–3]. Currently, many technologies are avail-
able to separate and expand dermis-derived cells to obtain
injectable autologous cell suspensions for regenerative
purposes [4, 5]. Recently, in the European Union area, cell
manipulation underwent restricting regulations that signifi-
cantly reduced the availability of cell expansion technology.
According to current regulations, any cell manipulation
involving enzymatic treatment and cell culture expansion is
allowed in Cell Factories only, with a relevant increase of time
and cost burden [6].

Recently, the development of an innovative technology
for dermal mechanical microfragmentation named Rigen-
era™ allowed the harvest of a filtered available cell pool
without any enzymatic manipulation. Such a cell fraction,
rich in progenitor cells, was successfully used in the treat-
ment of difficult-to-heal wound [3, 7–9]. The advantage of
this innovative technology is its unrestricted use in any
clinical context and setting.

Nevertheless, such an evidence was demonstrated within
the frame of pathologies with heterogeneous aetiology. The
aim of the study was the objective assessment of the effective-
ness of such a microfragmented dermal extract in promoting
the wound healing process in an in vivo homogeneous
experimental human acute surgical wound model.

2. Materials and Methods

2.1. Study Design. A prospective randomized controlled open
clinical trial was carried out at the Plastic and Reconstructive
Surgery Unit of the Istituti Clinici Scientifici Maugeri.
Twenty patients (4 females and 16 males), with an age range
of 53-93 years (mean 77.80, median 79), were enrolled in the
trial over a period of 15 months, from September 2017 to
December 2018. The exclusion criteria were wound infection,
chemotherapy in the last 6 months, use of corticosteroids or
immunosuppressive treatment, and metabolic, endocrine,
autoimmune, and collagen diseases. The study included
patients with a postsurgical defect in any site of the body with
a size range of 4-400 cm2. The surgical defect followed an
immediate excision of 22 skin cancers, 1 ulcerated actinic
keratosis, and 1 chronic difficult-to-heal wound (Table 1).
A sequential two-stage repair with a dermal substitute and
an autologous split-thickness skin graft was planned. The
acute postsurgical soft tissue loss was considered the experi-
mental unit of the study irrespective of the number of
wounds per patient. Twenty-four experimental units were
enrolled in the trial. Each unit, which fulfilled the entry
criteria, was randomized to be treated either with an Integra®
dermal substitute enriched with the autologous dermal
micrografts obtained with Rigenera™ protocol (group A—Ri-
genera™ protocol) or with an Integra® dermal substitute only
(group B—control). Each group included 12 experimental
units. All of the wounds were planned for a sequential
second-stage repair with a split-thickness skin graft at the
time of complete engraftment of the Integra® dermal substi-
tute. According to our clinical experience, the time lag
between the first and the second surgical stages was around
4 weeks. The expected endpoint was a spontaneous reepithe-
lialization higher than 25% of the total wound area in the

group treated with Rigenera™ protocol at 4 weeks that would
contraindicate the second staged cover with a split-thickness
skin graft. The secondary endpoint was the comparison of
the reepithelialization rate at 4 weeks after the first surgical
stage between the group treated with Rigenera™ protocol
and the controls.

The reepithelialization rate in the wounds was assessed at
each time point of the study through digital photography
with the software “ImageJ” (Figure 1). As a wound spontane-
ously reduces in size, due to a physiologic shrinkage process,
the measurement of the reepithelialization rate was referred
to the actual total wound size at each time point.

A formal informed written consent was obtained from all
of the patients, and the study conformed to the Declaration
of Helsinki. The trial was approved by the Ethical Committee
(protocol number 2142) of the Istituti Clinici Scientifici
Maugeri SB SpA IRCCS of Pavia.

2.2. Materials and Methods. The micrografts were obtained
by Rigeneracons, a single-use sterile CE-certified Class I
medical device able to mechanically disaggregate tissues into
micrografts that are immediately available for transfer in the
clinical practice [10]. It is made of a plastic container pro-
vided with an openable lid divided into two chambers by a
stationary stainless steel grid with 100 hexagonal holes.
Around each hole, 6 microblades are designed for efficient
cutting of hard and soft tissues allowing a filtration cut-off
of about 80 μm. The upper chamber is provided with a rotat-
ing helix forcing the tissue fragments through the grid
towards the bottom chamber. The rotation of Rigeneracons

Table 1: Cohort’s characteristics. Categorical variables’ distribution
is described by counts and relative frequencies (%); continuous
variables’ distribution by median (25th–75th percentiles).

Variable Distribution

Age (years) 78.0 (74.5-84.0)

Gender

Females 4 (17.39%)

Males 16 (82.61%)

Localization

Limbs 7 (30.43%)

Scalp 1 (4.35%)

Face 15 (65.22%)

Protocol

A 11 (47.83%)

B 12 (52.17%)

Cause

BCC 16 (69.57%)

SCC 4 (17.39%)

Other 3 (13.09%)

T1 area (cm2) 9.26 (7.06-12.54)

Reepithelialization (%) 13.94 (11.96-20.85)

≥25% 3 (13.04%)
<25% 20 (86.96%)

2 Stem Cells International



is activated by a Rigenera OR-PRO machine (Esacrom, Italy)
using a connection adaptor (Adacons Max).

2.3. The Operative Protocol. The operative protocol consists
of different steps:

(a) Choice of the micrograft donor site with preference
of the retroauricular region

(b) Gentle blade shaving of the donor site to remove the
epidermis and obtain a bare papillary dermis

(c) Harvest of the adequate number of 3 mm punch
biopsies from the previously deepithelialized skin;
the number of dermal punch biopsies calculated
according to the size of the wound, considering that
1 mm2 of the dermal graft was expected to regenerate
an epithelial cover up to 2 cm2 (Figure 2)

(d) Loading the disposable Rigeneracons with a maxi-
mum of 3 dermal samples at a time and addition of
2.5 ml of saline solution (Figures 3 and 4)

(e) Device connection to the rotating machine, operating
at 80 rpm for 90 seconds, that provides a mechanical
disaggregation of the dermal sample into a suspen-

sion containing autologous dermal micrografts
(Figure 5)

(f) Aspiration of the micrografts containing saline
solution with a sterile syringe (Figure 6)

(g) Cover of the postsurgical soft tissue loss with
Integra® dermal substitute (Figure 7)

(h) Fixation of the dermal substitute with stitches and
gentle imbibition with the saline micrograft suspen-
sion (Figure 8)

(i) Infiltration of the micrograft suspension in the
perilesional tissues

2.4. The Treatment. The time points of the study were
designed as follows:

(i) T0: starting time includes patient enrollment,
signature of informed consent, and randomization.

(ii) T1: the first-stage was characterized by surgical pro-
cedure of skin lesion excision, digital medical photo-
graphs, and soft-tissue loss measurement were
obtained with the use of the “ImageJ” program. Soft
tissue loss was covered with an Integra® dermal

Group A-
RigeneraTM

protocol

Complete re-
epithelialization

Complete re-
epithelialization

T3
So�-tissue loss
measurement

T4
Healed
wound

T3
Healed
wound

Healed
wound

T3

Split
thickness

skin
gra�

coverage

A

B

T0

Patient
enrollment,
signature of

informed
consent and

randomization

T1
Surgical

procedure

So�-tissue loss
measurement

Group B -control

T2
So�-tissue loss
measurement

T2
So�-tissue loss
measurement

Split thickness
skin gra�
coverage

Residual split
thickness skin

gra�
coverage

(T
1
 < 28 days < T

2
)

(T
0
 < 6-14 days < T

1
)

(T
1
 < 28 days < T

2
) (T

2
 < 14 days < T

3
)

= 0% T
1
 area

(T
2
 < 14 days < T

3
)

> 25% T
1
 area

< 25% T
1
 area

T1
Surgical

procedure
So�-tissue loss
measurement

Medical photography

Figure 1: Scheme of the overall study structure.

3Stem Cells International



substitute alone (group B—controls) or enriched
with the autologous dermal micrografts (group
A—Rigenera™ protocol).

(iii) T2: 4 weeks after the first surgical stage, digital
medical photographs and residual soft-tissue loss
measurement were obtained with the use of the
software “ImageJ.” In the Rigenera™ protocol
group, if the deepithelialized area in the wound
was the same as at T1, a split-thickness skin graft
was planned; if the reepithelialized area was >25%
than the one at T1, a follow-up was planned in 2
weeks’ time (T3); if reepithelialization was complete,
the wound was considered healed and the patient
was discharged from the study. In the control group,
a split-thickness skin graft cover was carried out.

(iv) T3: digital photographs and residual soft-tissue loss
measurement were obtained with the use of the soft-
ware “ImageJ” in the Rigenera™ protocol group; in

the latter group, whatever the extension of the
residual deepithelialized area, a split-thickness skin
graft was planned at this time; if reepithelialization
was complete, the wound was considered healed
and the patient was discharged from the study.

(v) T4: there was complete reepithelialization 1 week
after the split-thickness skin graft cover at T3 in the
Rigenera™ protocol group.

2.5. Statistical Methods. The deviation of continuous variable
distribution from the normal distribution was assessed by
visual inspection of quantile-quantile plots and by the
Shapiro test. T1 and final area distribution was normalized
by natural logarithm transformation. Continuous variable
distribution is described by median and 25th–75th percentiles;
categorical variable distribution is described by counts and
frequencies (%). The Fisher exact test and the Wilcoxon
rank-sum test were applied to compare the categorical and
quantitative variables’ distribution between protocols. The
Spearman test allowed quantifying the strength of the
correlation between continuous variables (rho). Statistical
procedures were performed by the R statistical software
(http://www.r-project.org.)

3. Results

One male patient out of 20 with surgical excision of a
squamous cell carcinoma of the scalp dropped out of the
study due to postoperative wound infection. An overall
of 23 experimental units (12 in the control group and 11
in the Rigenera™ protocol group) completed the trial.

At T2, 4 weeks after the first surgical step, the reepithelia-
lization rate was 12.98% (10.40-17.61) in the control group
and 15.14% (12.42-22.03) in the Rigenera™ protocol group

Figure 2: Harvest of the 3 mm punch biopsies from the previously
deepithelialized skin.

Figure 3: The harvested skin punch biopsy.

Figure 4: The disposable Rigeneracons loaded with a maximum of 3
dermal samples.

4 Stem Cells International

http://www.r-project.org


(p = 0 607). In the latter group, only one wound out of 11
(9.09%) demonstrated a reepithelialization > 25% of the total
wound area, while in the control group, such an outcome was
observed in 2 wounds out of 12 (16.67%) (p = 1).

4. Discussion

It is a common knowledge that the human dermis is a
source of stem cells with demonstrated regenerative
properties [11–16]. The dermal mesenchymal stromal stem
cells display adhesion properties, fibroblast morphology, and

osteogenic and adipocyte differentiation. Typically, they
express both mesenchymal (α-SMA) and neural (Nestin
and βIII-tubulin) cell membrane markers and lack the
haematopoietic and endothelial ones (CD31) [13]. Recently,
the dermal mesenchymal stromal stem cells were demon-
strated to express also the CD105, CD73, and CD90 markers
that specifically regulate regeneration in the wound healing
process. These cells enhance cell survival and proliferation
in the wound site through a fine modulation of the immune
and inflammatory response, operated by a finely tuned cas-
cade of local mediators. They definitely play a relevant active

Figure 5: Connection of the disposable Rigeneracons to the
Rigenera OR-PRO rotating machine.

Figure 6: Aspiration of the micrografts containing saline solution
with a sterile syringe.

Figure 7: Cover of the postsurgical soft tissue loss with Integra®
dermal substitute.

Figure 8: Imbibition of the dermal substitute with the saline
micrograft suspension.

5Stem Cells International



role along the inflammatory, proliferative, and remodeling
phases allowing an eventual favorable outcome in the wound
healing process.

The hair follicle matrix has been demonstrated to host
cells that are capable of self-renewal and produce epithelial
transient progenitors, thus having attributes of stem cells,
too. Stem cells are multipotent, capable of giving rise not only
to all the cell types of the hair but also to the epidermis and
the sebaceous gland. These cells display a highly sophisti-
cated organization and carry out several functions control-
ling the shape of the hair follicle. The inner structures are
each produced by a distinct, restricted set of precursors
occupying a specific position along the proximodistal axis
of the matrix. The matrix seems to be organized by two
systems working in orthogonal dimensions and controlling
two key operations of hair follicle morphogenesis, notably
cell diversification and cell behavior [17]. The bulge cell
progeny located in the upper follicle has been demonstrated
to emigrate into the epidermis and to proliferate, thus
contributing to the long-term maintenance of the epidermis
[18, 19]. Based on these observations, it has been proposed
that the bulge is a major repository of skin keratinocyte stem
cells, which may thus be regarded as the ultimate epider-
mal stem cell [20, 21]. Since stem cells are known to be
involved in skin tumor formation [22–27], the coincidence
of greater tumor susceptibility with the transient prolifera-
tion of the bulge cells is consistent with the hypothesis
that the bulge cells are stem cells and indicates that follicular
stem cells can give rise to experimentally induced skin cancers
[22–25]. Taken together, these data suggest that the bulge is
the site of follicular stem cells.

The Rigenera™ method allows the harvesting of a dermis-
derived autologous cell suspension including a stem cell
fraction, ready for use without any cell manipulation process
[28]. Several clinical studies demonstrated the effectiveness of
the Rigenera™ cell harvesting method in the management of
complex wounds with complete obliteration and reepithelia-
lization of deep soft tissue loss [1–3, 7–9].

In order to objectively assess the effectiveness of the
Rigenera™ method, we established a homogeneous experi-
mental fresh surgical wound model providing measurable
data that excluded gross experimental bias and fit a rigorous
statistical analysis.

Rigenera™ provides a fluid cell suspension that may be
both injected in deep spaces and applied on superficial soft
tissue loss in combination with a dermal substitute [29].

According to our current clinical practice, we deliber-
ately enrolled patients with a planned two-stage soft tissue
loss repair using a dermal substitute followed 4 weeks later
by a split-thickness skin graft. The enrichment of a dermal
substitute with an autologous cell suspension graft was
considered a minimal modification of a current and well-
established clinical protocol involving a negligible donor site
morbidity and, therefore, allowed approval of the trial by the
Ethical Committee.

Considering our long-term clinical experience in the
field [30], the dermal substitute of choice for the study
was Integra® as it was demonstrated to provide an
in vitro favorable environment for dermal stromal mesen-

chymal stem cell engraftment and replication as early as 7
days [29]. The peculiar three-dimensional structure of
Integra®, with a controlled 80 μm porous structure, allows
a physiological cell adhesion, infiltration, distribution, and
proliferation with the preservation of the typical mesen-
chymal fibroblast morphology.

In our study, the treatment with the dermal cell suspen-
sion prepared with the Rigenera™ technology was considered
effective if the reepithelialized area was higher than the
25% of the total wound surface as the latter threshold
was considered far beyond the expected spontaneous
reepithelialization rate.

Nevertheless, in the Rigenera™ protocol group, the statis-
tical analysis did not demonstrate any significant difference
vs. the controls.

The old age of the patients likely influenced the outcome.
Indeed, our experimental plan, designed as a two-stage

procedure, had to meet ethical requirements, too. Currently,
such a procedure is the gold standard in frail elderly patients
that often come to observation for advanced skin cancers,
requiring extensive demolitions but that are unfit for
complex reconstructive procedures [31]. The use of a sequen-
tial two-stage reconstructive procedure with a dermal substi-
tute and a split-thickness skin graft in these cases allows for a
better functional and cosmetic outcome than a simple one-
staged skin graft [32–34] (Figure 9).

Undoubtedly, the stem cell regenerative potential is
reduced in the elderly. Recent literature reports demonstrate
an antiapoptotic action of the senescent cells that prevents
the full expression of the regenerative potential in the stem
cell pool [35]. In our opinion, a sample pretreatment with
specific active principles targeting the senescent cells might
be suggested to increase the regenerative potential in the
dermal stromal mesenchymal stem cell transfer [36]. The
latter specific pretreatment might enhance the full regenera-
tive potential of a minimally invasive cell transfer, making it a
specifically convenient procedure for the frail critical patient.

Figure 9: Complete healing of the defect after STSG in group A.

6 Stem Cells International



Therefore, reepithelialization of large skin loss in the elderly
patient drawing on a minimal dermal fragment might be a
realistic option.

A further explanation for the unsatisfying results of our
experimental trial might be the inadequate amount of dermal
stem cells used to enrich the dermal substitutes. Actually, in
our study, we used a 1 : 200 donor/recipient site ratio in order
to minimize donor site morbidity. The gross dimensional
disparity between the donor and recipient sites and the low
concentration of dermal mesenchymal stromal stem cells
might explain the poor epithelial proliferative boost observed
in our study. Unpublished data from animal experimental
trials by our research partner staff would suggest that the
optimal donor/recipient site ratio is 1 : 20. Nevertheless, such
a ratio would not make the dermal cell suspension transfer a
convenient procedure in terms of donor site morbidity vs. a
traditional large meshed split-thickness skin graft [37].

Actually, in previous literature reports, the Rigenera™
dermal cell transfer proved to be effective in the difficult-to-
heal wound where a split-thickness skin graft was not
indicated. Therefore, we suppose that the reported favorable
outcome might have been related to an overall change of the
wound environment, where a spontaneous reepithelializa-
tion might have been related to a nonspecific boost of a
torpid wound bed from mesenchymal dermal and epithelial
stem cells and matrix-derived factors. Instead, in our
opinion, in an acute fresh wound, all of the factors involved
in the wound healing process display a maximal expression,
thus shading the supposed contribution of the dermal extract
as a whole. Indeed, a preconditioning of the dermal cells with
a treatment enhancing their regenerative potential might
yield a better outcome.

5. Conclusions

The role of the human dermal stem cell regenerative pool in
enhancing the wound healing process is a well-established
knowledge and is leading to an increasing number of prom-
ising clinical applications. The Rigenera™ technology might
promote a spontaneous reepithelialization; nevertheless, even
if proved to be effective in stimulating a difficult-to-heal
wound by turning a torpid chronic process into an active
one, in our experience, it could not demonstrate any
improvement in the reepithelialization process of a fresh
surgical wound. A potential option in the future might be a
preconditioning of the dermal stem cell harvest with
senolytic active principles that would fully enhance their
regenerative potential. Such a treatment might extend the
clinical indications of this minimally invasive, standardized,
operator-independent, and easy procedure, specifically suit-
able for the management of complex and critical cases.

Data Availability

The data used to support the findings of this study are
restricted by the Ethical Committee (protocol number
2142) of the Istituti Clinici Scientifici Maugeri SB SpA IRCCS
of Pavia in order to protect patient privacy. Data are available

for researchers who meet the criteria for access to confiden-
tial data from the corresponding author upon request.

Conflicts of Interest

The author Antonio Graziano is a member of the Scientific
Division of Human Brain Wave, the company owner of
Rigenera™ Technology. The other authors have no conflict
of interests to declare.

Acknowledgments

The experiments were supported by the Human Brain Wave
srl supplying Rigeneracons medical devices.

References

[1] F. Svolacchia, F. De Francesco, L. Trovato, A. Graziano, and
G. A. Ferraro, “An innovative regenerative treatment of scars
with dermal micrografts,” Journal of Cosmetic Dermatology,
vol. 15, no. 3, pp. 245–253, 2016.

[2] E. Baglioni, L. Trovato, M. Marcarelli, A. Frenello, and M. A.
Bocchiotti, “Treatment of oncological post-surgical wound
dehiscence with autologous skin micrografts,” Anticancer
Research, vol. 36, no. 3, pp. 975–979, 2016.

[3] F. De Francesco, A. Graziano, L. Trovato et al., “A Regenera-
tive Approach with Dermal Micrografts in the Treatment of
Chronic Ulcers,” Stem Cell Reviews and Reports, vol. 13,
no. 1, pp. 139–148, 2017.

[4] W. K. Boss, H. Usal, P. B. Fodor, and G. Chernoff, “Autologous
Cultured Fibroblasts: A Protein Repair System,” Annals of
Plastic Surgery, vol. 44, no. 5, pp. 536–542, 2000.

[5] S. Maxson, E. A. Lopez, D. Yoo, A. Danilkovitch-Miagkova,
and M. A. Leroux, “Concise review: role of mesenchymal stem
cells in wound repair,” Stem Cells Translational Medicine,
vol. 1, no. 2, pp. 142–149, 2012.

[6] European Commission, Guidelines on Good Manufacturing
Practice specific to Advanced Therapy Medicinal Products,
2017.

[7] M. Giaccone, M. Brunetti, M. Camandona, L. Trovato, and
A. Graziano, “A new medical device, based on Rigenera proto-
col, in the management of complex wounds,” Journal of Stem
Cell Reviews and Reports, vol. 1, no. 3, p. 3, 2014.

[8] L. Trovato, G. Failla, S. Serantoni, and F. P. Palumbo, “Regen-
erative Surgery in the Management of the Leg Ulcers,” Journal
of Cell Science & Therapy, vol. 7, no. 2, 2016.

[9] M. Marcarelli, L. Trovato, E. Novarese, M. Riccio, and
A. Graziano, “Rigenera protocol in the treatment of surgical
wound dehiscence,” International Wound Journal, vol. 14,
no. 1, pp. 277–281, 2017.

[10] L. Trovato, M. Monti, C. del Fante et al., “A new medical
device Rigeneracons allows to obtain viable micro-grafts from
mechanical disaggregation of human tissues,” Journal of Cellu-
lar Physiology, vol. 230, no. 10, pp. 2299–2303, 2015.

[11] K. Takahashi, K. Tanabe, M. Ohnuki et al., “Induction of
pluripotent stem cells from adult human fibroblasts by defined
factors,” Cell, vol. 131, no. 5, pp. 861–872, 2007.

[12] R. Vishnubalaji, M. Al-Nbaheen, B. Kadalmani,
A. Aldahmash, and T. Ramesh, “Skin-derived multipotent
stromal cells–an archrival for mesenchymal stem cells,” Cell
and Tissue Research, vol. 350, no. 1, pp. 1–12, 2012.

7Stem Cells International



[13] M. Dominici, K. le Blanc, I. Mueller et al., “Minimal criteria
for defining multipotent mesenchymal stromal cells. The
International Society for Cellular Therapy position statement,”
Cytotherapy, vol. 8, no. 4, pp. 315–317, 2006.

[14] B. Coulomb, L. Friteau, J. Baruch et al., “Advantage of the pres-
ence of living dermal fibroblasts within in vitro reconstructed
skin for grafting in humans,” Plastic and Reconstructive
Surgery, vol. 101, no. 7, pp. 1891–1903, 1998.

[15] F. M. Wood, N. Giles, A. Stevenson, S. Rea, and M. Fear,
“Characterisation of the cell suspension harvested from the
dermal epidermal junction using a ReCell® kit,” Burns,
vol. 38, no. 1, pp. 44–51, 2012.

[16] R. I. Sharma and J. G. Snedeker, “Paracrine interactions
between mesenchymal stem cells affect substrate driven differ-
entiation toward tendon and bone phenotypes,” PLoS One,
vol. 7, no. 2, article e31504, 2012.

[17] E. Legué and J. F. Nicolas, “Hair follicle renewal: organization
of stem cells in the matrix and the role of stereotyped lineages
and behaviors,” Development, vol. 132, no. 18, pp. 4143–4154,
2005.

[18] G. Cotsarelis, T.-T. Sun, and R. M. Lavker, “Label-retaining
cells reside in the bulge area of pilosebaceous unit: implications
for follicular stem cells, hair cycle, and skin carcinogenesis,”
Cell, vol. 61, no. 7, pp. 1329–1337, 1990.

[19] R. M. Lavker, S. Miller, C. Wilson et al., “Hair follicle stem
cells. Their location, role in hair cycle, and involvement in skin
tumor formation,” Journal of Investigative Dermatology,
vol. 101, no. 1, pp. S16–S26, 1993.

[20] R. M. Lavker, T.-T. Sun, H. Oshima et al., “Hair follicle stem
cells,” The Journal of Investigative Dermatology, vol. 8, no. 1,
pp. 28–38, 2003.

[21] G. Taylor, M. S. Lehrer, P. J. Jensen, T.-T. Sun, and R. M. Lav-
ker, “Involvement of follicular stem cells in forming not only
the follicle but also the epidermis,” Cell, vol. 102, no. 4,
pp. 451–461, 2000.

[22] R. J. Morris, S. M. Fischer, and T. J. Slaga, “Evidence that a
slowly cycling subpopulation of adult murine epidermal cells
retains carcinogen,” Cancer Research, vol. 46, no. 6,
pp. 3061–3066, 1986.

[23] S. J. Miller, Z. G. Wei, C. Wilson, L. Dzubow, T. T. Sun, and
R. M. Lavker, “Mouse skin is particularly susceptible to tumor
initiation during early anagen of the hair cycle: possible
involvement of hair follicle stem cells,” The Journal of Investi-
gative Dermatology, vol. 101, no. 4, pp. 591–594, 1993.

[24] R. J. Morris, K. Coulter, K. Tryson, and S. R. Steinberg,
“Evidence that cutaneous carcinogen-initiated epithelial
cells from mice are quiescent rather than actively cycling,”
Cancer Research, vol. 57, no. 16, pp. 3436–3443, 1997.

[25] R. J. Morris, K. A. Tryson, and K. Q. Wu, “Evidence that the
epidermal targets of carcinogen action are found in the inter-
follicular epidermis or infundibulum as well as in the hair
follicles,” Cancer Research, vol. 60, no. 2, pp. 226–229, 2000.

[26] G. Nicoletti, F. Brenta, A. Malovini, O. Jaber, and A. Faga,
“Sites of basal cell carcinomas and head and neck congenital
clefts: topographic correlation,” Plastic and Reconstructive Sur-
gery Global Open, vol. 2, no. 6, article e164, 2014.

[27] G. Nicoletti, M. M. Tresoldi, A. Malovini, S. Prigent,
M. Agozzino, and A. Faga, “Correlation between the sites of
onset of basal cell carcinoma and the embryonic fusion planes
in the auricle,” Clinical Medicine Insights: Oncology, vol. 12,
pp. 1–5, 2018.

[28] V. Purpura, E. Bondioli, A. Graziano et al., “Tissue Charac-
terization after a New Disaggregation Method for Skin
Micro-Grafts Generation,” Journal of Visualized Experi-
ments, vol. 109, no. 109, 2016.

[29] T. da Silva Jeremias, R. G. Machado, S. B. C. Visoni, M. J.
Pereima, D. F. Leonardi, and A. G. Trentin, “Dermal substi-
tutes support the growth of human skin-derived mesenchy-
mal stromal cells: potential tool for skin regeneration,” PLoS
One, vol. 9, no. 2, article e89542, 2014.

[30] G. Nicoletti, M. M. Tresoldi, A. Malovini, M. Visaggio,
A. Faga, and S. Scevola, “Versatile use of dermal substitutes:
a retrospective survey of 127 consecutive cases,” Indian Jour-
nal of Plastic Surgery, vol. 51, no. 1, pp. 46–53, 2018.

[31] S. Scevola, M. M. Tresoldi, and A. Faga, “Rigenerazione e
riabilitazione: esperienza di chirurgia plastica in un centro
di riabilitazione,” Giornale Italiano di Medicina del Lavoro
ed Ergonomia, vol. 40, no. 2, pp. 97–105, 2018.

[32] G. Nicoletti, S. Scevola, and A. Faga, “Bioengineered Skin for
Aesthetic Reconstruction of the Tip of the Nose,” Dermato-
logic Surgery, vol. 34, no. 9, pp. 1283–1287, 2008.

[33] A. Faga, G. Nicoletti, F. Brenta, S. Scevola, G. Abatangelo, and
P. Brun, “Hyaluronic acid three-dimensional scaffold for surgi-
cal revision of retracting scars: a human experimental study,”
International Wound Journal, vol. 10, no. 3, pp. 329–335, 2013.

[34] G. Nicoletti, F. Brenta, M. Bleve et al., “Long-
termin vivoassessment of bioengineered skin substitutes: a
clinical study,” Journal of Tissue Engineering and Regenerative
Medicine, vol. 9, no. 4, pp. 460–468, 2015.

[35] M. V. Blagosklonny, “Paradoxes of senolytics,” Aging, vol. 10,
no. 12, pp. 4289–4293, 2018.

[36] J. L. Kirkland, T. Tchkonia, Y. Zhu, L. J. Niedernhofer, and
P. D. Robbins, “The clinical potential of senolytic drugs,” Jour-
nal of the American Geriatrics Society, vol. 65, no. 10,
pp. 2297–2301, 2017.

[37] R. Cuomo, L. Grimaldi, B. Cesare, G. Nisi, and C. D’Aniello,
“Skin graft donor site: a procedure for a faster healing,” Acta
Biomedica, vol. 88, no. 3, pp. 310–314, 2017.

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